88E1518-A0-NNB2C000

Marvell® Alaska® 88E1510/88E1518/88E1512/88E1514 Integrated 10/100/1000 Mbps Energy Efficient Ethernet Transceiver Datasheet - Public Doc. No. MV-S107146-U0 Rev. E June 3, 2021 Document Classification: Public Cover Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public THIS DOCUMENT AND THE INFORMATION FURNISHED IN THIS DOCUMENT ARE PROVIDED "AS IS" WITHOUT ANY WARRANTY. MARVELL AND ITS AFFILIATES EXPRESSLY DISCLAIM AND MAKE NO WARRANTIES OR GUARANTEES, WHETHER EXPRESS, ORAL, IMPLIED, STATUTORY, ARISING BY OPERATION OF LAW, OR AS A RESULT OF USAGE OF TRADE, COURSE OF DEALING, OR COURSE OF PERFORMANCE, INCLUDING THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. This document, including any software or firmware referenced in this document, is owned by Marvell or Marvell's licensors, and is protected by intellectual property laws. No license, express or implied, to any Marvell intellectual property rights is granted by this document. The information furnished in this document is provided for reference purposes only for use with Marvell products. It is the user's own responsibility to design or build products with this information. Marvell products are not authorized for use as critical components in medical devices, military systems, life or critical support devices, or related systems. Marvell is not liable, in whole or in part, and the user will indemnify and hold Marvell harmless for any claim, damage, or other liability related to any such use of Marvell products. Marvell assumes no responsibility for the consequences of use of such information or for any infringement of patents or other rights of third parties that may result from its use. You may not use or facilitate the use of this document in connection with any infringement or other legal analysis concerning the Marvell products disclosed herein. Marvell and the Marvell logo are registered trademarks of Marvell or its affiliates. Please visit www.marvell.com for a complete list of Marvell trademarks and guidelines for use of such trademarks. Other names and brands may be claimed as the property of others. Copyright © 2021. Marvell and/or its affiliates. All rights reserved. Document Classification: Public June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Page 2 Copyright © 2021 Marvell Alaska 88E1510/88E1518/88E1512/88E1514 Integrated 10/100/1000 Mbps Energy Efficient Ethernet Transceiver Datasheet - Public PRODUCT OVERVIEW The Alaska® 88E1510/88E1518/88E1512/88E1514 device is a physical layer device containing a single 10/100/1000 Gigabit Ethernet transceiver. The transceiver implements the Ethernet physical layer portion of the 1000BASE-T, 100BASE-TX, and 10BASE-T standards. It is manufactured using standard digital CMOS process and contains all the active circuitry required to implement the physical layer functions to transmit and receive data on standard CAT 5 unshielded twisted pair. The device supports the RGMII (Reduced pin count GMII) and SGMII for direct connection to a MAC/Switch port. The SGMII can also be used on media/line side to connect to SFP modules that support 1000BASE-X, 100BASE-FX and SGMII. It also supports Copper/Fiber Auto-media applications with RGMII as the MAC interface. SGMII operates at 1.25 Gbps over a single differential pair thus reducing power and number of I/Os used on the MAC interface. The device integrates MDI termination resistors into the PHY. This resistor integration simplifies board layout and reduces board cost by reducing the number of external components. The new Marvell® calibrated resistor scheme will achieve and exceed the accuracy requirements of the IEEE 802.3 return loss specifications. The device has an integrated switching voltage regulator to generate all required voltages. The device can run off a single 3.3V supply. The device supports 1.8V, 2.5V, and 3.3V LVCMOS I/O Standards. The 88E1510/88E1518/88E1512/88E1514 device supports Synchronous Ethernet (SyncE) and Precise Timing Protocol (PTP) Time Stamping, which is based on IEEE1588 version 2 and IEEE802.1AS. The 88E1510/88E1518/88E1512/88E1514 device supports IEEE 802.3az-2010 Energy Efficient Ethernet (EEE) and is IEEE 802.3az-2010 compliant. The device incorporates the Marvell Advanced Virtual Cable Tester® (VCT™) feature, which uses Time Domain Reflectometry (TDR) technology for the remote identification of potential cable malfunctions, thus reducing equipment returns and service calls. Using VCT, the Alaska device detects and reports potential cabling issues such as pair swaps, pair polarity and excessive pair skew. The device will also detect cable opens, shorts or any impedance mismatch in the cable and reporting accurately within one meter the distance to the fault. The device uses advanced mixed-signal processing to perform equalization, echo and crosstalk cancellation, data recovery, and error correction at a Gigabits per second data rate. The device achieves robust performance in noisy environments with very low power dissipation. Features            10/100/1000BASE-T IEEE 802.3 compliant Multiple Operating Modes • RGMII to Copper • SGMII to Copper (88E1512/88E1514 device only) • RGMII to Fiber/SGMII (88E1512 device only) • RGMII to Copper/Fiber/SGMII with Auto-Media Detect (88E1512 device only) • Copper to Fiber (1000BASE-X) (88E1512/88E1514) Four RGMII timing modes including integrated delays - This eliminates the need for adding trace delays on the PCB Supports 1000BASE-X and 100BASE-FX on the Fiber interface along with SGMII (88E1512 device only) Supports LVCMOS I/O Standards on the RGMII Supports Energy Efficient Ethernet (EEE) - IEEE 802.3az-2010 compliant • EEE Buffering • Incorporates EEE buffering for seamless support of legacy MACs Ultra Low Power Integrated MDI termination resistors that eliminate passive components Integrated Switching Voltage Regulators Supports Green Ethernet • Active Power Save Mode • Energy Detect and Energy Detect+ low power modes IEEE1588 version 2 Time Stamping Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 3 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public            Synchronous Ethernet (SyncE) Clock Recovery Three loopback modes for diagnostics “Downshift” mode for two-pair cable installations Fully integrated digital adaptive equalizers, echo cancellers, and crosstalk cancellers Advanced digital baseline wander correction Automatic MDI/MDIX crossover at all speeds of operation Automatic polarity correction IEEE 802.3 compliant Auto-Negotiation Software programmable LED modes including LED testing MDC/XMDIO Management Interface CRC checker, packet counter Table 1: Packet generation Wake on LAN (WOL) event detection Advanced Virtual Cable Tester® (VCT™) Auto-Calibration for MAC Interface outputs Temperature Sensor Supports single 3.3V supply when using internal switching regulator I/O pads can be supplied with 1.8V, 2.5V, or 3.3V Commercial grade, Industrial grade (88E1510 and 88E1512 only) 48-Pin QFN 7 mm x 7 mm Green package with EPAD (88E1510 and 88E1518) and 56-Pin QFN 8 mm x 8 mm Green package with EPAD (88E1512/88E1514 device)          88E1510/88E1518/88E1512/88E1514 Device Features F ea t u r e s 88E1510 RGMII to Copper 88E1518 Yes Yes 88E1512 88E1514 Yes No SGMII to Copper No No Yes Yes RGMII to Fiber/SGMII No No Yes No RGMII to Copper/Fiber/SGMII with Auto-Media Detect No No Yes No Copper to Fiber I/O Voltage (VDDO) No No Yes Yes 3.3V/2.5V 1.8V only 3.3V/2.5V/1.8V 3.3V/2.5V/1.8V IEEE 802.3az-2010 Energy Efficient Ethernet (EEE) Yes Yes Yes Yes EEE Buffering Yes Yes Yes Yes Synchronous Ethernet (SyncE) Yes Yes Yes Yes Precise Timing Protocol (PTP) Yes Yes Yes Yes Auto-Media Detect No No Yes No Wake on LAN (WOL) Yes Yes Yes Yes Package Industrial/Commercial Temperature 48-pin QFN Commercial Industrial Commercial Doc. No. MV-S107146-U0 Rev. E Page 4 56-pin QFN Commercial Industrial Commercial Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Product Overview Features Alaska® 88E1512/ 88E1514 Device Magnetics Alaska® 88E1510/ 88E1518/ 88E1512 Device Integrated Passive Termination 10/100/1000 Mbps Ethernet MAC MAC Interface - RGMII Integrated Passive Termination Figure 1: RGMII to Copper Device Application Media Type - 10BASE-T - 100BASE-TX - 1000BASE-T RJ-45 10/100/1000 Mbps Ethernet MAC MAC Interface – SGMII/SERDES Magnetics Figure 2: SGMII to Copper Application RJ-45 Media Type - 10BASE-T - 100BASE-TX - 1000BASE-T 10/100/1000 Mbps Ethernet MAC MAC Interface – RGMII Alaska® 88E1512 Device Integrated Passive Termination Figure 3: RGMII to Fiber/SGMII Application SERDES/ SGMII Fiber Optics Media Type - 1000BASE-X - 100BASE-FX - SFP MAC Interface – RGMII Alaska® 88E1512 Device SERDES/SGMII Copyright © 2021 Marvell June 3, 2021 Magnetics 10/100/1000 Mbps Ethernet MAC Integrated Passive Termination Figure 4: RGMII to Copper/Fiber/SGMII Auto-Media Application Fiber Optics RJ-45 Media Type - 1000BASE-X - 100BASE-FX - SFP or Media Type - 1000BASE-T - 100BASE-TX - 10BASE-T Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 5 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table of Contents 1 Signal Description ..................................................................................................................... 17 1.1 Pin Description .............................................................................................................................................. 1.1.1 88E1510/88E1518 48-Pin QFN Package Pinout ............................................................................ 1.1.2 88E1512 56-Pin QFN Package Pinout ........................................................................................... 1.1.3 88E1514 56-Pin QFN Package Pinout ........................................................................................... 17 18 23 28 1.2 Pin Assignment List ....................................................................................................................................... 1.2.1 88E1510 48-Pin QFN Pin Assignment List - Alphabetical by Signal Name .................................... 1.2.2 88E1518 48-Pin QFN Pin Assignment List - Alphabetical by Signal Name .................................... 1.2.3 88E1512 56-Pin QFN Pin Assignment List - Alphabetical by Signal Name .................................... 1.2.4 88E1514 56-Pin QFN Pin Assignment List - Alphabetical by Signal Name .................................... 33 33 34 35 36 2 PHY Functional Specifications ................................................................................................. 37 2.1 Modes of Operation and Major Interfaces ..................................................................................................... 37 2.2 Copper Media Interface ................................................................................................................................. 39 2.2.1 Transmit Side Network Interface .................................................................................................... 39 2.2.1.1 Multi-mode TX Digital to Analog Converter ............................................................. 39 2.2.1.2 Slew Rate Control and Waveshaping ...................................................................... 40 2.2.2 Encoder .......................................................................................................................................... 40 2.2.2.1 1000BASE-T ............................................................................................................ 40 2.2.2.2 100BASE-TX ........................................................................................................... 40 2.2.2.3 10BASE-T ................................................................................................................ 40 2.2.3 Receive Side Network Interface ..................................................................................................... 40 2.2.3.1 Analog to Digital Converter ...................................................................................... 40 2.2.3.2 Active Hybrid ............................................................................................................ 40 2.2.3.3 Echo Canceller ........................................................................................................ 40 2.2.3.4 NEXT Canceller ....................................................................................................... 40 2.2.3.5 Baseline Wander Canceller ..................................................................................... 41 2.2.3.6 Digital Adaptive Equalizer ........................................................................................ 41 2.2.3.7 Digital Phase Lock Loop .......................................................................................... 41 2.2.3.8 Link Monitor ............................................................................................................. 41 2.2.3.9 Signal Detection ....................................................................................................... 41 2.2.4 Decoder .......................................................................................................................................... 41 2.2.4.1 1000BASE-T ............................................................................................................ 41 2.2.4.2 100BASE-TX ........................................................................................................... 42 2.2.4.3 10BASE-T ................................................................................................................ 42 2.3 1.25 GHz SERDES Interface ........................................................................................................................ 42 2.3.1 Electrical Interface .......................................................................................................................... 42 2.4 MAC Interfaces ............................................................................................................................................. 43 2.4.1 SGMII .............................................................................................................................................. 43 2.4.1.1 SGMII Speed and Link ............................................................................................. 43 2.4.1.2 SGMII TRR Blocking ................................................................................................ 43 2.4.1.3 False SERDES Link Up Prevention ......................................................................... 43 2.4.2 RGMII ............................................................................................................................................. 44 2.4.3 10/100 Mbps Functionality .............................................................................................................. 45 2.4.4 TX_ER and RX_ER Coding ............................................................................................................ 45 2.5 Loopback ....................................................................................................................................................... 2.5.1 System Interface Loopback ............................................................................................................ 2.5.2 Line Loopback ................................................................................................................................ 2.5.3 External Loopback .......................................................................................................................... Doc. No. MV-S107146-U0 Rev. E Page 6 45 45 47 48 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Table of Contents 2.6 Resets ........................................................................................................................................................... 49 2.7 Power Management ...................................................................................................................................... 2.7.1 Low Power Modes .......................................................................................................................... 2.7.1.1 IEEE Power Down Mode ......................................................................................... 2.7.1.2 Copper Energy Detect Modes ................................................................................. 2.7.2 RGMII/SGMII MAC Interface Power Down ..................................................................................... 49 49 50 50 51 2.8 Auto-Negotiation ........................................................................................................................................... 2.8.1 10/100/1000BASE-T Auto-Negotiation ........................................................................................... 2.8.2 1000BASE-X Auto-Negotiation ....................................................................................................... 2.8.3 SGMII Auto-Negotiation .................................................................................................................. 2.8.3.1 Serial Interface Auto-Negotiation Bypass Mode ...................................................... 51 52 53 53 53 2.9 CRC Error Counter and Frame Counter ....................................................................................................... 54 2.9.1 Enabling the CRC Error Counter and Packet Counter ................................................................... 54 2.10 Packet Generator .......................................................................................................................................... 54 2.11 1.25G PRBS Generator and Checker ........................................................................................................... 55 2.12 MDI/MDIX Crossover .................................................................................................................................... 56 2.13 Polarity Correction ......................................................................................................................................... 56 2.14 FLP Exchange Complete with No Link .......................................................................................................... 57 2.15 Duplex Mismatch Indicator ............................................................................................................................ 57 2.16 LED ............................................................................................................................................................... 58 2.16.1 LED Polarity .................................................................................................................................... 59 2.16.2 Pulse Stretching and Blinking ......................................................................................................... 59 2.16.3 Bi-Color LED Mixing ....................................................................................................................... 60 2.16.4 Modes of Operation ........................................................................................................................ 62 2.16.4.1 Compound LED Modes ........................................................................................... 63 2.16.4.2 Speed Blink .............................................................................................................. 63 2.16.4.3 Manual Override ...................................................................................................... 63 2.16.4.4 MODE 1, MODE 2, MODE 3, MODE 4 .................................................................... 64 2.17 Interrupt ......................................................................................................................................................... 64 2.18 Configuring the 88E1510/88E1518/88E1512/88E1514 Device .................................................................... 65 2.18.1 Hardware Configuration .................................................................................................................. 65 2.18.2 Software Configuration - Management Interface ............................................................................ 66 2.18.2.1 Preamble Suppression ............................................................................................ 67 2.19 Jumbo Packet Support .................................................................................................................................. 67 2.20 Temperature Sensor ..................................................................................................................................... 67 2.21 Regulators and Power Supplies .................................................................................................................... 2.21.1 AVDD18 .......................................................................................................................................... 2.21.2 AVDDC18 ....................................................................................................................................... 2.21.3 AVDD33 .......................................................................................................................................... 2.21.4 DVDD .............................................................................................................................................. 2.21.5 REG_IN .......................................................................................................................................... 2.21.6 AVDD18_OUT ................................................................................................................................ 2.21.7 DVDD_OUT .................................................................................................................................... 2.21.8 VDDO ............................................................................................................................................. 2.21.9 Power Supply Sequencing .............................................................................................................. 3 88E1510/88E1518/88E1512/88E1514 Register Description .................................................... 70 3.1 PHY MDIO Register Description ................................................................................................................... 70 Copyright © 2021 Marvell June 3, 2021 68 68 68 68 69 69 69 69 69 69 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 7 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4 Electrical Specifications ......................................................................................................... 118 4.1 Absolute Maximum Ratings ........................................................................................................................ 118 4.2 Recommended Operating Conditions ......................................................................................................... 119 4.3 Package Thermal Information ..................................................................................................................... 120 4.3.1 Thermal Conditions for 88E1510/88E1518 48-pin, QFN Package ............................................... 120 4.3.2 Thermal Conditions for 88E1512/88E1514 56-pin, QFN Package ............................................... 121 4.4 88E1510/88E1518 Current Consumption ................................................................................................... 122 4.4.1 Current Consumption when using External Regulators ................................................................ 122 4.4.2 Current Consumption when using Internal Regulators ................................................................. 123 4.5 88E1512 Current Consumption ................................................................................................................... 124 4.5.1 Current Consumption when using External Regulators ................................................................ 124 4.5.2 Current Consumption when using Internal Regulators ................................................................. 126 4.6 88E1514 Current Consumption ................................................................................................................... 127 4.6.1 Current Consumption when using External Regulators ................................................................ 127 4.6.2 Current Consumption when using Internal Regulators ................................................................. 128 4.7 DC Operating Conditions ............................................................................................................................ 129 4.7.1 Digital Pins .................................................................................................................................... 129 4.7.2 LED Pins ....................................................................................................................................... 130 4.7.3 IEEE DC Transceiver Parameters ................................................................................................ 131 4.7.4 SGMII Interface ............................................................................................................................. 132 4.7.4.1 Transmitter DC Characteristics .............................................................................. 132 4.7.4.2 Common Mode Voltage (Voffset) Calculations ...................................................... 133 4.7.4.3 Receiver DC Characteristics .................................................................................. 136 4.8 AC Electrical Specifications ........................................................................................................................ 4.8.1 Reset Timing ................................................................................................................................. 4.8.2 XTAL_IN/XTAL_OUT Timing ........................................................................................................ 4.8.3 LED to CONFIG Timing ................................................................................................................ 4.9 SGMII Timing .............................................................................................................................................. 140 4.9.1 SGMII Output AC Characteristics ................................................................................................. 140 4.9.2 SGMII Input AC Characteristics .................................................................................................... 140 4.10 RGMII Timing .............................................................................................................................................. 141 4.10.1 RGMII AC Characteristics ............................................................................................................. 141 4.10.2 RGMII Delay Timing for Different RGMII Modes ........................................................................... 142 4.10.2.1 PHY Input - TX_CLK Delay when Register 21_2.4 = 0 ......................................... 142 4.10.2.2 PHY Input - TX_CLK Delay when Register 21_2.4 = 1 ......................................... 142 4.10.2.3 PHY Output - RX_CLK Delay ................................................................................ 143 4.10.2.4 PHY Output - RX_CLK Delay ................................................................................ 143 4.11 MDC/MDIO Timing ...................................................................................................................................... 144 4.12 IEEE AC Transceiver Parameters ............................................................................................................... 145 4.13 Latency Timing ............................................................................................................................................ 146 4.13.1 RGMII to 1000BASE-T Transmit Latency Timing ......................................................................... 146 4.13.2 RGMII to 100BASE-TX Transmit Latency Timing ......................................................................... 146 4.13.3 RGMII to 10BASE-T Transmit Latency Timing ............................................................................. 146 4.13.4 1000BASE-T to RGMII Receive Latency Timing .......................................................................... 147 4.13.5 100BASE-TX to RGMII Receive Latency Timing .......................................................................... 147 4.13.6 10BASE-T to RGMII Receive Latency Timing .............................................................................. 147 4.13.7 10/100/1000BASE-T to SGMII Latency Timing ............................................................................ 148 4.13.8 SGMII to 10/100/1000BASE-T Latency Timing ............................................................................ 149 Doc. No. MV-S107146-U0 Rev. E Page 8 137 137 138 139 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Table of Contents 5 Package Mechanical Dimensions .......................................................................................... 150 5.1 48-Pin QFN Package .................................................................................................................................. 150 5.2 56-Pin QFN Package .................................................................................................................................. 152 6 Part Order Numbering/Package Marking .............................................................................. 154 6.1 Part Order Numbering ................................................................................................................................. 154 6.2 Package Marking ........................................................................................................................................ 155 6.2.1 Commercial ................................................................................................................................... 155 6.2.2 Industrial ....................................................................................................................................... 158 A Revision History ...................................................................................................................... 159 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 9 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public List of Tables Product Overview ....................................................................................................................................... 3 Table 1: 1 2 88E1510/88E1518/88E1512/88E1514 Device Features ....................................................................4 Signal Description ............................................................................................................................ 17 Table 2: Pin Type Definitions ..........................................................................................................................17 Table 3: Media Dependent Interface ..............................................................................................................19 Table 4: RGMII ...............................................................................................................................................20 Table 5: Management Interface and Interrupt ................................................................................................20 Table 6: LED Interface....................................................................................................................................20 Table 7: Clock/Configuration/Reset/I/O ..........................................................................................................21 Table 8: Control and Reference......................................................................................................................21 Table 9: Test...................................................................................................................................................21 Table 10: Power, Ground & Internal Regulators ...............................................................................................22 Table 11: Media Dependent Interface ..............................................................................................................24 Table 12: RGMII ...............................................................................................................................................25 Table 13: Management Interface and Interrupt ................................................................................................25 Table 14: LED Interface....................................................................................................................................25 Table 15: Clock/Configuration/Reset/I/O ..........................................................................................................26 Table 16: SGMII I/Os ........................................................................................................................................26 Table 17: Control and Reference......................................................................................................................26 Table 18: Test...................................................................................................................................................26 Table 19: Power, Ground, and Internal Regulators ..........................................................................................27 Table 20: Media Dependent Interface ..............................................................................................................29 Table 21: Management Interface and Interrupt ................................................................................................30 Table 22: LED Interface....................................................................................................................................30 Table 23: Clock/Configuration/Reset/I/O ..........................................................................................................30 Table 24: SGMII I/Os ........................................................................................................................................30 Table 25: Control and Reference......................................................................................................................31 Table 26: Test...................................................................................................................................................31 Table 27: Power, Ground, and Internal Regulators ..........................................................................................31 Table 28: No Connect.......................................................................................................................................32 Table 29: I/O State at Various Test or Reset Modes ........................................................................................32 Table 30: 88E1510 48-Pin QFN Pin Assignment List - Alphabetical by Signal Name......................................33 Table 31: 88E1518 48-Pin QFN Pin Assignment List - Alphabetical by Signal Name......................................34 Table 32: 88E1512 56-Pin QFN Pin Assignment List - Alphabetical by Signal Name......................................35 Table 33: 88E1514 56-Pin QFN Pin Assignment List - Alphabetical by Signal Name......................................36 PHY Functional Specifications........................................................................................................ 37 Table 34: MODE[2:0] Select .............................................................................................................................39 Table 35: SGMII (System Interface) Operational Speed ..................................................................................43 Doc. No. MV-S107146-U0 Rev. E Page 10 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 List of Tables 3 Table 36: Fiber Noise Filtering..........................................................................................................................43 Table 37: RGMII Signal Mapping......................................................................................................................44 Table 38: Reset Control Bits .............................................................................................................................49 Table 39: Power Down Control Bits ..................................................................................................................50 Table 40: Power Down Modes..........................................................................................................................51 Table 41: SGMII Auto-Negotiation modes ........................................................................................................54 Table 42: 1.25 GHz SERDES PRBS Registers ................................................................................................55 Table 43: Media Dependent Interface Pin Mapping .........................................................................................56 Table 44: Late Collision Registers ....................................................................................................................57 Table 45: LED Polarity .....................................................................................................................................59 Table 46: Pulse Stretching and Blinking ...........................................................................................................60 Table 47: Bi-Color LED Mixing .........................................................................................................................61 Table 48: Modes of Operation ..........................................................................................................................62 Table 49: Compound LED Status .....................................................................................................................63 Table 50: Speed Blinking Sequence.................................................................................................................63 Table 51: Speed Blink.......................................................................................................................................63 Table 52: MODE 3 Behavior .............................................................................................................................64 Table 53: MODE 4 Behavior .............................................................................................................................64 Table 54: Copper ..............................................................................................................................................65 Table 55: Fiber..................................................................................................................................................65 Table 56: Two-Bit Mapping...............................................................................................................................65 Table 57: Configuration Mapping......................................................................................................................65 Table 58: Configuration Definition ....................................................................................................................66 Table 59: Serial Management Interface Protocol .............................................................................................67 Table 60: Temperature Sensor.........................................................................................................................67 Table 61: Power Supply Options - Integrated Switching Regulator (REG_IN) .................................................68 Table 62: Power Supply Options - External Supplies .......................................................................................68 88E1510/88E1518/88E1512/88E1514 Register Description ........................................................... 70 Table 63: Register Types..................................................................................................................................70 Table 64: Register Map ....................................................................................................................................70 Table 65: Copper Control Register ...................................................................................................................72 Table 66: Copper Status Register ....................................................................................................................74 Table 67: PHY Identifier 1.................................................................................................................................75 Table 68: PHY Identifier 2.................................................................................................................................76 Table 69: Copper Auto-Negotiation Advertisement Register ............................................................................76 Table 70: Copper Link Partner Ability Register - Base Page ............................................................................79 Table 71: Copper Auto-Negotiation Expansion Register ..................................................................................80 Table 72: Copper Next Page Transmit Register ...............................................................................................80 Table 73: Copper Link Partner Next Page Register .........................................................................................81 Table 74: 1000BASE-T Control Register ..........................................................................................................81 Table 75: 1000BASE-T Status Register ...........................................................................................................82 Table 76: Extended Status Register .................................................................................................................83 Table 77: Copper Specific Control Register 1 ..................................................................................................83 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 11 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 78: Copper Specific Status Register 1 ....................................................................................................85 Table 79: Copper Specific Interrupt Enable Register .......................................................................................86 Table 80: Copper Interrupt Status Register ......................................................................................................87 Table 81: Copper Specific Control Register 2 ..................................................................................................88 Table 82: Copper Specific Receive Error Counter Register .............................................................................88 Table 83: Page Address ...................................................................................................................................89 Table 84: Global Interrupt Status......................................................................................................................89 Table 85: Fiber Control Register.......................................................................................................................89 Table 86: Fiber Status Register ........................................................................................................................91 Table 87: PHY Identifier....................................................................................................................................92 Table 88: PHY Identifier....................................................................................................................................92 Table 89: Fiber Auto-Negotiation Advertisement Register - 1000BASE-X Mode (Register 16_1.1:0 = 01).....................................................................................................................................................92 Table 90: Fiber Auto-Negotiation Advertisement Register - SGMII (System mode) (Register 16_1.1:0 = 10).....................................................................................................................................................94 Table 91: Fiber Auto-Negotiation Advertisement Register - SGMII (Media mode) (Register 16_1.1:0 = 11).....................................................................................................................................................94 Table 92: Fiber Link Partner Ability Register - 1000BASE-X Mode (Register 16_1.1:0 = 01) ..........................95 Table 93: Fiber Link Partner Ability Register - SGMII (System mode) (Register 16_1.1:0 = 10)......................96 Table 94: Fiber Link Partner Ability Register - SGMII (Media mode) (Register 16_1.1:0 = 11)........................96 Table 95: Fiber Auto-Negotiation Expansion Register......................................................................................97 Table 96: Fiber Next Page Transmit Register ..................................................................................................97 Table 97: Fiber Link Partner Next Page Register .............................................................................................98 Table 98: Extended Status Register .................................................................................................................98 Table 99: Fiber Specific Control Register 1 ......................................................................................................99 Table 100: Fiber Specific Status Register ........................................................................................................100 Table 101: Fiber Interrupt Enable Register.......................................................................................................101 Table 102: Fiber Interrupt Status Register........................................................................................................102 Table 103: PRBS Control .................................................................................................................................102 Table 104: PRBS Error Counter LSB ...............................................................................................................103 Table 105: PRBS Error Counter MSB ..............................................................................................................103 Table 106: Fiber Specific Control Register 2 ....................................................................................................103 Table 107: MAC Specific Control Register 1 ....................................................................................................104 Table 108: MAC Specific Interrupt Enable Register .........................................................................................105 Table 109: MAC Specific Status Register.........................................................................................................105 Table 110: MAC Specific Control Register 2 ....................................................................................................106 Table 111: RGMII Output Impedance Calibration Override ..............................................................................107 Table 112: LED[2:0] Function Control Register ................................................................................................108 Table 113: LED[2:0] Polarity Control Register ..................................................................................................109 Table 114: LED Timer Control Register............................................................................................................110 Table 115: 1000BASE-T Pair Skew Register ...................................................................................................111 Table 116: 1000BASE-T Pair Swap and Polarity .............................................................................................111 Table 117: Copper Port Packet Generation......................................................................................................111 Table 118: Copper Port CRC Counters ............................................................................................................112 Doc. No. MV-S107146-U0 Rev. E Page 12 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 List of Tables Table 119: Checker Control ..............................................................................................................................112 Table 120: Copper Port Packet Generation......................................................................................................113 Table 121: Late Collision Counters 1 & 2 .........................................................................................................113 Table 122: Late Collision Counters 3 & 4 .........................................................................................................113 Table 123: Late Collision Window Adjust/Link Disconnect ...............................................................................114 Table 124: Misc Test ........................................................................................................................................114 Table 125: Misc Test: Temperature Sensor Alternative Reading .....................................................................114 Table 126: Packet Generation ..........................................................................................................................115 Table 127: CRC Counters ................................................................................................................................116 Table 128: Checker Control ..............................................................................................................................116 Table 129: Packet Generation ..........................................................................................................................116 Table 130: General Control Register 1 .............................................................................................................117 4 Electrical Specifications ................................................................................................................118 Table 131: Absolute Maximum Ratings ............................................................................................................118 Table 132: Recommended Operating Conditions.............................................................................................119 Table 133: Thermal Conditions for 88E1510/88E151848-pin, QFN Package ..................................................120 Table 134: Thermal Conditions for 88E1512/88E1514 56-pin, QFN Package .................................................121 Table 135: Current Consumption AVDD18 + AVDDC18 ..................................................................................122 Table 136: Current Consumption AVDD33.......................................................................................................122 Table 137: Current Consumption DVDD ..........................................................................................................122 Table 138: Current Consumption VDDO ..........................................................................................................123 Table 139: Current Consumption REG_IN .......................................................................................................123 Table 140: Current Consumption AVDD18 + AVDDC18 ..................................................................................124 Table 141: Current Consumption AVDD33.......................................................................................................125 Table 142: Current Consumption DVDD ..........................................................................................................125 Table 143: Current Consumption VDDO ..........................................................................................................126 Table 144: Current Consumption REG_IN .......................................................................................................126 Table 145: Current Consumption AVDD18 + AVDDC18 ..................................................................................127 Table 146: Current Consumption AVDD33.......................................................................................................127 Table 147: Current Consumption DVDD ..........................................................................................................127 Table 148: Current Consumption VDDO ..........................................................................................................128 Table 149: Current Consumption REG_IN .......................................................................................................128 Table 150: Digital Pins ......................................................................................................................................129 Table 151: LED Pins .........................................................................................................................................130 Table 152: IEEE DC Transceiver Parameters ..................................................................................................131 Table 153: Transmitter DC Characteristics.......................................................................................................132 Table 154: Programming SGMII Output Amplitude ..........................................................................................132 Table 155: Receiver DC Characteristics...........................................................................................................136 Table 156: Reset Timing...................................................................................................................................137 Table 157: XTAL_IN/XTAL_OUT Timing ..........................................................................................................138 Table 158: LED to CONFIG Timing ..................................................................................................................139 Table 159: SGMII Output AC Characteristics ..................................................................................................140 Table 160: SGMII Input AC Characteristics.....................................................................................................140 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 13 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 161: RGMII AC Characteristics...............................................................................................................141 Table 162: PHY Input - TX_CLK Delay when Register 21_2.4 = 0 ..................................................................142 Table 163: PHY Input - TX_CLK Delay when Register 21_2.4 = 1 ..................................................................142 Table 164: PHY Output - RX_CLK Delay .........................................................................................................143 Table 165: PHY Output - RX_CLK Delay .........................................................................................................143 Table 166: MDC/MDIO Timing .........................................................................................................................144 Table 167: IEEE AC Transceiver Parameters ..................................................................................................145 Table 168: RGMII to 1000BASE-T Transmit Latency Timing ...........................................................................146 Table 169: RGMII to 100BASE-TX Transmit Latency Timing...........................................................................146 Table 170: RGMII to 10BASE-T Transmit Latency Timing ...............................................................................146 Table 171: 1000BASE-T to RGMII Receive Latency Timing ............................................................................147 Table 172: 100BASE-TX to RGMII Receive Latency Timing............................................................................147 Table 173: 10BASE-T to RGMII Receive Latency Timing ................................................................................147 Table 174: 10/100/1000BASE-T to SGMII Latency Timing ..............................................................................148 Table 175: SGMII to 10/100/1000BASE-T Latency Timing ..............................................................................149 5 Package Mechanical Dimensions .................................................................................................150 Table 176: 48-Pin QFN Mechanical Dimensions ..............................................................................................151 Table 177: 56-Pin QFN Mechanical Dimensions ..............................................................................................153 6 Part Order Numbering/Package Marking......................................................................................154 Table 178: 88E1510/88E1518/88E1512/88E1514 Part Order Options ............................................................154 A Revision History .............................................................................................................................159 Table 179: Revision History ..............................................................................................................................159 Doc. No. MV-S107146-U0 Rev. E Page 14 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 List of Figures List of Figures Product Overview ....................................................................................................................................... 3 1 2 Figure 1: RGMII to Copper Device Application ..................................................................................................5 Figure 2: SGMII to Copper Application ..............................................................................................................5 Figure 3: RGMII to Fiber/SGMII Application ......................................................................................................5 Figure 4: RGMII to Copper/Fiber/SGMII Auto-Media Application ......................................................................5 Signal Description ............................................................................................................................ 17 Figure 5: 88E1510/88E1518 Device 48-Pin QFN Package (Top View)...........................................................18 Figure 6: 88E1512 Device 56-Pin QFN Package (Top View) ..........................................................................23 Figure 7: 88E1514 Device 56-Pin QFN Package (Top View) ..........................................................................28 PHY Functional Specifications........................................................................................................ 37 Figure 8: Device Functional Block Diagram .....................................................................................................37 Figure 9: 88E1512/88E1514 SGMII/SERDES System to Copper Media Interface Example...........................38 Figure 10: 88E1510/88E1518 RGMII System to Copper Interface Example .....................................................38 Figure 11: 88E1512 RGMII System to SERDES Interface Example .................................................................38 Figure 12: CML I/Os...........................................................................................................................................42 Figure 13: RGMII Signal Diagram ......................................................................................................................44 Figure 14: MAC Interface Loopback Diagram - Copper Media Interface ...........................................................46 Figure 15: System Interface Loopback Diagram - Fiber Media Interface...........................................................46 Figure 16: Copper Line Loopback Data Path.....................................................................................................47 Figure 17: Fiber Line Loopback Data Path ........................................................................................................48 Figure 18: Loopback Stub (Top View with Tab up) ............................................................................................48 Figure 19: Test Setup for 10/100/1000 Mbps Modes using an External Loopback Stub ...................................49 Figure 20: LED Chain ........................................................................................................................................58 Figure 21: Various LED Hookup Configurations ................................................................................................59 Figure 22: Typical MDC/MDIO Read Operation ................................................................................................66 Figure 23: Typical MDC/MDIO Write Operation.................................................................................................66 3 88E1510/88E1518/88E1512/88E1514 Register Description ........................................................... 70 4 Electrical Specifications ................................................................................................................118 Figure 24: CML I/Os.........................................................................................................................................133 Figure 25: AC connections (CML or LVDS receiver) or DC connection LVDS receiver ..................................134 Figure 26: DC connection to a CML receiver ...................................................................................................135 Figure 27: Input Differential Hysteresis ............................................................................................................136 Figure 28: Reset Timing...................................................................................................................................137 Figure 29: XTAL_IN/XTAL_OUT Timing ..........................................................................................................138 Figure 30: ........................................................................................................................................................138 Figure 31: LED to CONFIG Timing ..................................................................................................................139 Figure 32: Serial Interface Rise and Fall Times ...............................................................................................140 Figure 33: RGMII Multiplexing and Timing.......................................................................................................141 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 15 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 5 6 A Figure 34: TX_CLK Delay Timing - Register 21_2.4 = 0..................................................................................142 Figure 35: TX_CLK Delay Timing - Register 21_2.4 = 1 (add delay)...............................................................142 Figure 36: RGMII RX_CLK Delay Timing - Register 21_2.5 = 0......................................................................143 Figure 37: RGMII RX_CLK Delay Timing - Register 21_2.5 = 1 (add delay)...................................................143 Figure 38: MDC/MDIO Timing ........................................................................................................................144 Figure 39: ........................................................................................................................................................145 Figure 40: RGMII/MII to 10/100/1000BASE-T Transmit Latency Timing ........................................................146 Figure 41: 10/100/1000BASE-T to RGMII Receive Latency Timing ................................................................147 Figure 42: 10/100/1000BASE-T to SGMII Latency Timing ..............................................................................148 Figure 43: SGMII to 10/100/1000BASE-T Latency Timing ..............................................................................149 Package Mechanical Dimensions .................................................................................................150 Figure 44: 88E1510/88E1518 48-pin QFN Package Mechanical Drawings ....................................................150 Figure 45: 88E1512/88E1514 56-pin QFN Package Mechanical Drawings ....................................................152 Part Order Numbering/Package Marking......................................................................................154 Figure 46: Sample Part Number ......................................................................................................................154 Figure 47: 88E1510 48-pin QFN Commercial Package Marking and Pin 1 Location ......................................155 Figure 48: 88E1518 48-pin QFN Commercial Package Marking and Pin 1 Location ......................................156 Figure 49: 88E1512 56-pin QFN Commercial Package Marking and Pin 1 Location ......................................156 Figure 50: 88E1514 56-pin QFN Commercial Package Marking and Pin 1 Location ......................................157 Figure 51: 88E1510 48-pin QFN Industrial Package Marking and Pin 1 Location...........................................158 Figure 52: 88E1512 56-pin QFN Industrial Package Marking and Pin 1 Location...........................................158 Revision History .............................................................................................................................159 Doc. No. MV-S107146-U0 Rev. E Page 16 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Description 1 Signal Description 1.1 Pin Description Table 2: Pin Type Definitions P in Typ e D e f in it io n H Input with hysteresis I/O Input and output I Input only O Output only PU Internal pull-up PD Internal pull-down D Open drain output Z Tri-state output mA DC sink capability Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 17 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 1.1.1 88E1510/88E1518 48-Pin QFN Package Pinout The 88E1510/88E1518 device is a 10/100/1000BASE-T Gigabit Ethernet transceiver. DVDD REGCAP2 DVDD_OUT AVDD18_OUT REGCAP1 REG_IN AVDDC18 XTAL_IN XTAL_OUT HSDACP HSDACN RSET 36 35 34 33 32 31 30 29 28 27 26 25 Figure 5: 88E1510/88E1518 Device 48-Pin QFN Package (Top View) RX_CTRL 37 24 MDIP[0] RXD[0] 38 23 MDIN[0] RXD[1] 39 22 AVDD18 RX_CLK 40 21 AVDD33 RXD[2] 41 20 MDIP[1] RXD[3] 42 19 MDIN[1] VDDO 43 18 MDIP[2] TXD[0] 44 17 MDIN[2] TXD[1] 45 16 AVDD33 VDDO 46 15 AVDD18 TX_CLK 47 14 MDIP[3] TXD[2] 48 13 MDIN[3] EPAD - VSS 6 7 8 9 10 11 12 VDDO LED[2]/INTn LED[1] LED[0] CONFIG RESETn 4 MDC CLK125 3 DVDD 5 2 TX_CTRL MDIO 1 TXD[3] 88E1510/88E1518 Doc. No. MV-S107146-U0 Rev. E Page 18 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Description Table 3: Media Dependent Interface 48-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 23 24 MDIN[0] MDIP[0] I/O Media Dependent Interface[0]. In 1000BASE-T mode in MDI configuration, MDIN/P[0]correspond to BI_DA±. In MDIX configuration, MDIN/P[0] correspond to BI_DB±. In 100BASE-TX and 10BASE-T modes in MDI configuration, MDIN/P[0] are used for the transmit pair. In MDIX configuration, MDIN/P[0] are used for the receive pair. The device contains an internal 100Ω resistor between the MDIP/N[0] pins. 19 20 MDIN[1] MDIP[1] I/O Media Dependent Interface[1]. In 1000BASE-T mode in MDI configuration, MDIN/P[1]correspond to BI_DB±. In MDIX configuration, MDIN/P[1]correspond to BI_DA±. In 100BASE-TX and 10BASE-T modes in MDI configuration, MDIN/P[1]are used for the receive pair. In MDIX configuration, MDIN/P[1]are used for the transmit pair. The device contains an internal 100Ω resistor between the MDIP/N[1] pins. 17 18 MDIN[2] MDIP[2] I/O Media Dependent Interface[2]. In 1000BASE-T mode in MDI configuration, MDIN/P[2]correspond to BI_DC±. In MDIX configuration, MDIN/P[2] corresponds to BI_DD±. In 100BASE-TX and 10BASE-T modes, MDIN/P[2]are not used. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[2] pins. 13 14 MDIN[3] MDIP[3] I/O Media Dependent Interface[3]. In 1000BASE-T mode in MDI configuration, MDIN/P[3] correspond to BI_DD±. In MDIX configuration, MDIN/P[3] correspond to BI_DC±. In 100BASE-TX and 10BASE-T modes, MDIN/P[3] are not used. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[3] pins. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 19 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public The RGMII supports 10/100/1000BASE-T modes of operation. Table 4: RGMII 48-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 47 TX_CLK I RGMII Transmit Clock provides a 125 MHz, 25 MHz, or 2.5 MHz reference clock with ±50 ppm tolerance depending on speed. 2 TX_CTRL I RGMII Transmit Control. TX_EN is presented on the rising edge of TX_CLK. A logical derivative of TX_EN and TX_ER is presented on the falling edge of TX_CLK. 1 48 45 44 TXD[3] TXD[2] TXD[1] TXD[0] I RGMII Transmit Data. TXD[3:0] run at double data rate with bits [3:0] of each byte to be transmitted on the rising edge of TX_CLK, and bits [7:4] presented on the falling edge of TX_CLK. In 10/100BASE-T modes, the transmit data nibble is presented on TXD[3:0] on the rising edge of TX_CLK. 40 RX_CLK O RGMII Receive Clock provides a 125 MHz, 25 MHz, or 2.5 MHz reference clock with ±50 ppm tolerance derived from the received data stream depending on speed. 37 RX_CTRL O RGMII Receive Control. RX_DV is presented on the rising edge of RX_CLK. A logical derivative of RX_DV and RX_ER is presented on the falling edge of RX_CLK. 42 41 39 38 RXD[3] RXD[2] RXD[1] RXD[0] O RGMII Receive Data. RXD[3:0] run at double data rate with bits [3:0] of each byte received on the rising edge of RX_CLK, and bits [7:4] presented on the falling edge of RX_CLK. In 10/100BASE-T modes, the receive data nibble is presented on RXD[3:0] on the rising edge of RX_CLK. Table 5: Management Interface and Interrupt 48-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 4 MDC I MDC is the management data clock reference for the serial management interface. A continuous clock stream is not expected. The maximum frequency supported is 12 MHz. 5 MDIO I/O MDIO is the management data. MDIO transfers management data in and out of the device synchronously to MDC. This pin requires a pull-up resistor in a range from 1.5 kΩ to 10 kΩ. Table 6: LED Interface 48-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 10 LED[0] O LED output. 9 LED[1] I/O LED output 8 LED[2]/INTn O LED/Interrupt outputs. LED[2] pin also functions as an active low interrupt pin. Doc. No. MV-S107146-U0 Rev. E Page 20 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Description Table 7: Clock/Configuration/Reset/I/O 48-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 11 CONFIG I Hardware Configuration. 6 CLK125 O 125 MHz Clock Output synchronized with the 25 MHz reference clock 29 XTAL_IN I Reference Clock. 25 MHz ± 50 ppm tolerance crystal reference or oscillator input. NOTE: The XTAL_IN pin is not 2.5V/3.3V tolerant. Refer to ‘Oscillator level shifting’ application note to convert a 2.5V/3.3V clock source to 1.8V clock. 28 XTAL_OUT O Reference Clock. 25 MHz ± 50 ppm tolerance crystal reference. When the XTAL_OUT pin is not connected, it should be left floating. 12 RESETn I Hardware reset. Active low. 0 = Reset 1 = Normal operation Table 8: Control and Reference 48-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 25 RSET I Constant voltage reference. External 4.99 kΩ 1% resistor connection to VSS is required for this pin. Table 9: Test 48-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 26 27 HSDACN HSDACP Analog O Test Pins. These pins are used to bring out a differential TX_TCLK. Connect these pins with a 50Ω termination resistor to VSS for IEEE testing. If IEEE testing is not important, these pins may be left floating. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 21 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 10: Power, Ground & Internal Regulators 48-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 30 AVDDC18 Power Analog supply - 1.8V1. AVDDC18 can be supplied externally with 1.8V, or via the 1.8V internal regulator. 15 22 AVDD18 Power Analog supply - 1.8V. AVDD18 can be supplied externally with 1.8V, or via the 1.8V internal regulator. 16 21 AVDD33 Power Analog Supply - 3.3V. 31 REG_IN Power Analog Supply for the internal regulator – 3.3V. If the internal regulator is not used, this pin must be left open – No connect. NOTE: For further details on pin connections, refer to the Section 2.21, Regulators and Power Supplies, on page 68. NOTE: Ensure that these pins are left floating when the internal regulator is not used. Connecting these two pins to either another power supply or ground will damage the device. 32 35 REGCAP1 REGCAP2 Capacitor terminal pins for the internal regulator. Connect a 220 nF ± 10% ceramic capacitor between REGCAP1 and REGCAP2 on the board and place it close to the device. If the internal regulator is not used, these pins must be left open (no connect). Ensure that these pins are left floating when the internal regulator is not used. Connecting these two pins to either another power supply or ground will permanently damage the device. 33 AVDD18_OUT Power Regulator output - 1.8V. If the internal regulator is used, this pin must be connected to 1.8V power plane that connected to AVDD18 and AVDDC18. If the external supply is used, this pin must be left open (no-connect). 34 DVDD_OUT Power Regulator output - 1.0V. If the internal regulator is used, this pin must be connected to 1.0V power plane that connected to DVDD. If the external supply is used, this pin must be left open (no-connect). 7 43 46 VDDO Power 3.3V or 2.5V or 1.8V2 digital I/O supply3. VDDO must be supplied externally if 2.5V or 3.3V is desired. For VDDO 1.8V operation the 1.8V regulator output can be used. 3 36 DVDD Power Digital core supply - 1.0V. DVDD can be supplied externally with 1.0V or via the 1.0V internal regulator. Epad VSS GND Ground to device. The 48-pin QFN package has an exposed die pad (E-PAD) at its base. This E-PAD must be soldered to VSS. Refer to the package mechanical drawings for the exact location and dimensions of the EPAD. 1. AVDDC18 supplies the XTAL_IN and XTAL_OUT pins. 2. For 1.8V VDDO operations, refer to the Part Ordering section for the ordering information. 3. VDDO supplies the MDC, MDIO, RESETn, LED[2:0], CONFIG, CLK125, and the RGMII pins. Doc. No. MV-S107146-U0 Rev. E Page 22 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Description 1.1.2 88E1512 56-Pin QFN Package Pinout The 88E1512 device is a 10/100/1000BASE-T Gigabit Ethernet transceiver. DVDD REGCAP2 DVDD_OUT AVDD18_OUT AVDD18 REGCAP1 REG_IN AVDDC18 XTAL_IN XTAL_OUT HSDACP HSDACN RSET TSTPT 42 41 40 39 38 37 36 35 34 33 32 31 30 29 Figure 6: 88E1512 Device 56-Pin QFN Package (Top View) RX_CTRL 43 28 MDIP[0] RXD[0] 44 27 MDIN[0] RXD[1] 45 26 AVDD18 RX_CLK 46 25 AVDD33 RXD[2] 47 24 MDIP[1] RXD[3] 48 23 MDIN[1] VDDO 49 22 MDIP[2] TXD[0] 50 21 MDIN[2] TXD[1] 51 20 AVDD33 VDDO 52 19 AVDD18 TX_CLK 53 18 MDIP[3] TXD[2] 54 17 MDIN[3] TXD[3] 55 16 RESETn TX_CTRL 56 15 CONFIG EPAD - VSS 1 2 3 4 5 6 7 8 9 10 11 12 13 14 S_INP S_INN AVDD18 S_OUTP S_OUTN DVDD MDC MDIO CLK125 VDDO_SEL VDDO LED[2]/INTn LED[1] LED[0] 88E1512 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 23 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 11: Media Dependent Interface 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 27 28 MDIN[0] MDIP[0] I/O Media Dependent Interface[0]. In 1000BASE-T mode in MDI configuration, MDIN/P[0]correspond to BI_DA±. In MDIX configuration, MDIN/P[0] correspond to BI_DB±. In 100BASE-TX and 10BASE-T modes in MDI configuration, MDIN/P[0] are used for the transmit pair. In MDIX configuration, MDIN/P[0] are used for the receive pair. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[0] pins. 23 24 MDIN[1] MDIP[1] I/O Media Dependent Interface[1]. In 1000BASE-T mode in MDI configuration, MDIN/P[1]correspond to BI_DB±. In MDIX configuration, MDIN/P[1]correspond to BI_DA±. In 100BASE-TX and 10BASE-T modes in MDI configuration, MDIN/P[1]are used for the receive pair. In MDIX configuration, MDIN/P[1]are used for the transmit pair. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[1] pins. 21 22 MDIN[2] MDIP[2] I/O Media Dependent Interface[2]. In 1000BASE-T mode in MDI configuration, MDIN/P[2]correspond to BI_DC±. In MDIX configuration, MDIN/P[2] corresponds to BI_DD±. In 100BASE-TX and 10BASE-T modes, MDIN/P[2]are not used. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[2] pins. 17 18 MDIN[3] MDIP[3] I/O Media Dependent Interface[3]. In 1000BASE-T mode in MDI configuration, MDIN/P[3] correspond to BI_DD±. In MDIX configuration, MDIN/P[3] correspond to BI_DC±. In 100BASE-TX and 10BASE-T modes, MDIN/P[3] are not used. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[3] pins. Doc. No. MV-S107146-U0 Rev. E Page 24 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Description Table 12: RGMII 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 53 TX_CLK I RGMII Transmit Clock provides a 125 MHz, 25 MHz, or 2.5 MHz reference clock with ±50 ppm tolerance depending on speed. 56 TX_CTRL I RGMII Transmit Control. TX_EN is presented on the rising edge of TX_CLK. A logical derivative of TX_EN and TX_ER is presented on the falling edge of TX_CLK. 55 54 51 50 TXD[3] TXD[2] TXD[1] TXD[0] I RGMII Transmit Data. TXD[3:0] run at double data rate with bits [3:0] of each byte to be transmitted on the rising edge of TX_CLK, and bits [7:4] presented on the falling edge of TX_CLK. In 10/100BASE-T modes, the transmit data nibble is presented on TXD[3:0] on the rising edge of TX_CLK. 46 RX_CLK O RGMII Receive Clock provides a 125 MHz, 25 MHz, or 2.5 MHz reference clock with ±50 ppm tolerance derived from the received data stream depending on speed. 43 RX_CTRL O RGMII Receive Control. RX_DV is presented on the rising edge of RX_CLK. A logical derivative of RX_DV and RX_ER is presented on the falling edge of RX_CLK. 48 47 45 44 RXD[3] RXD[2] RXD[1] RXD[0] O RGMII Receive Data. RXD[3:0] run at double data rate with bits [3:0] of each byte received on the rising edge of RX_CLK, and bits [7:4] presented on the falling edge of RX_CLK. In 10/100BASE-T modes, the receive data nibble is presented on RXD[3:0] on the rising edge of RX_CLK. Table 13: Management Interface and Interrupt 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 7 MDC I MDC is the management data clock reference for the serial management interface. A continuous clock stream is not expected. The maximum frequency supported is 12 MHz. 8 MDIO I/O MDIO is the management data. MDIO transfers management data in and out of the device synchronously to MDC. This pin requires a pull-up resistor in a range from 1.5 kΩ to 10 kΩ. Table 14: LED Interface 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 14 LED[0] O LED output. 13 LED[1] I/O LED output 12 LED[2]/INTn O LED/Interrupt outputs. LED[2] pin also functions as an active low interrupt pin. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 25 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 15: Clock/Configuration/Reset/I/O 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 15 CONFIG I Hardware Configuration. 9 CLK125 O 125 MHz Clock Output synchronized with the 25 MHz reference clock 34 XTAL_IN I Reference Clock. 25 MHz ± 50 ppm tolerance crystal reference or oscillator input. NOTE: The XTAL_IN pin is not 2.5V/3.3V tolerant. Refer to ‘Oscillator level shifting’ application note to convert a 2.5V/3.3V clock source to 1.8V clock. 33 XTAL_OUT O Reference Clock. 25 MHz ± 50 ppm tolerance crystal reference. When the XTAL_OUT pin is not connected, it should be left floating. 16 RESETn I Hardware reset. Active low. 0 = Reset 1 = Normal operation Table 16: SGMII I/Os 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 2 1 S_INN S_INP I SGMII Receive Data. 1.25 GBaud input - Positive and Negative. 5 4 S_OUTN S_OUTP O SGMII Transmit Data. 1.25 GBaud output - Positive and Negative. Table 17: Control and Reference 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 30 RSET I Constant voltage reference. External 4.99 kΩ 1% resistor connection to VSS is required for this pin. Table 18: Test 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 31 32 HSDACN HSDACP Analog O Test Pins. These pins are used to bring out a differential TX_TCLK. Connect these pins with a 50Ω termination resistor to VSS for IEEE testing. If IEEE testing are not important, these pins may be left floating. 29 TSTPT O DC Test Point. The TSTPT pin should be left floating. Doc. No. MV-S107146-U0 Rev. E Page 26 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Description Table 19: Power, Ground, and Internal Regulators 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 35 AVDDC18 Power Analog supply - 1.8V1. AVDDC18 can be supplied externally with 1.8V, or via the 1.8V internal regulator. 3 19 26 38 AVDD18 Power Analog supply - 1.8V. AVDD18 can be supplied externally with 1.8V, or via the 1.8V internal regulator. 20 25 AVDD33 Power Analog Supply - 3.3V. 36 REG_IN Power Analog Supply for the internal regulator – 3.3V. If the internal regulator is not used, this pin must be left open – No connect. NOTE: For further details on pin connections, refer to the Section 2.21, Regulators and Power Supplies, on page 68. NOTE: Ensure that these pins are left floating when the internal regulator is not used. Connecting these two pins to either another power supply or ground will damage the device. 37 41 REGCAP1 REGCAP2 Capacitor terminal pins for the internal regulator. Connect a 220 nF ± 10% ceramic capacitor between REGCAP1 and REGCAP2 on the board and place it close to the device. If the internal regulator is not used, these pins must be left open (no connect). NOTE: Ensure that these pins are left floating when the internal regulator is not used. Connecting these two pins to either another power supply or ground will damage the device. 39 AVDD18_OUT Power Regulator output - 1.8V. If the internal regulator is used, this pin must be connected to 1.8V power plane that connected to AVDD18 and AVDDC18. If the external supply is used, this pin must be left open (no-connect). 40 DVDD_OUT Power Regulator output - 1.0V. If the internal regulator is used, this pin must be connected to 1.0V power plane that connected to DVDD. If the external supply is used, this pin must be left open (no-connect). 11 49 52 VDDO Power 3.3V or 2.5V or 1.8V digital I/O supply2. See VDDO_SEL for further details. VDDO must be supplied externally when 3.3V or 2.5V is used. For 1.8V operation, the 1.8V regulator output can be used. 10 VDDO_SEL Power VDDO Voltage Control. For VDDO 2.5V/3.3V operation, VDDO_SEL must be tied to VSS. For VDDO 1.8V operation, VDDO_SEL must be tied to VDDO. 6 42 DVDD Power Digital core supply - 1.0V. DVDD can be supplied externally with 1.0V or via the 1.0V internal regulator. EPAD VSS GND Ground to device. The 56-pin QFN package has an exposed die pad (E-PAD) at its base. This EPAD must be soldered to VSS. Refer to the package mechanical drawings for the exact location and dimensions of the EPAD. 1. AVDDC18 supplies the XTAL_IN and XTAL_OUT pins. 2. VDDO supplies the MDC, MDIO, RESETn, LED[2:0], CONFIG, CLK125, VDDO_SEL, and the RGMII pins. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 27 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 1.1.3 88E1514 56-Pin QFN Package Pinout The 88E1514 device is a 10/100/1000BASE-T Gigabit Ethernet transceiver. DVDD REGCAP2 DVDD_OUT AVDD18_OUT AVDD18 REGCAP1 REG_IN AVDDC18 XTAL_IN XTAL_OUT HSDACP HSDACN RSET TSTPT 42 41 40 39 38 37 36 35 34 33 32 31 30 29 Figure 7: 88E1514 Device 56-Pin QFN Package (Top View) NC 43 28 MDIP[0] NC 44 27 MDIN[0] NC 45 26 AVDD18 NC 46 25 AVDD33 NC 47 24 MDIP[1] NC 48 23 MDIN[1] VDDO 49 22 MDIP[2] VSS 50 21 MDIN[2] VSS 51 20 AVDD33 VDDO 52 19 AVDD18 VSS 53 18 MDIP[3] VSS 54 17 MDIN[3] VSS 55 16 RESETn VSS 56 15 CONFIG EPAD - VSS 1 2 3 4 5 6 7 8 9 10 11 12 13 14 S_INP S_INN AVDD18 S_OUTP S_OUTN DVDD MDC MDIO CLK125 VDDO_SEL VDDO LED[2]/INTn LED[1] LED[0] 88E1514 Doc. No. MV-S107146-U0 Rev. E Page 28 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Description Table 20: Media Dependent Interface 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 27 28 MDIN[0] MDIP[0] I/O Media Dependent Interface[0]. In 1000BASE-T mode in MDI configuration, MDIN/P[0]correspond to BI_DA±. In MDIX configuration, MDIN/P[0] correspond to BI_DB±. In 100BASE-TX and 10BASE-T modes in MDI configuration, MDIN/P[0] are used for the transmit pair. In MDIX configuration, MDIN/P[0] are used for the receive pair. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[0] pins. 23 24 MDIN[1] MDIP[1] I/O Media Dependent Interface[1]. In 1000BASE-T mode in MDI configuration, MDIN/P[1]correspond to BI_DB±. In MDIX configuration, MDIN/P[1]correspond to BI_DA±. In 100BASE-TX and 10BASE-T modes in MDI configuration, MDIN/P[1]are used for the receive pair. In MDIX configuration, MDIN/P[1]are used for the transmit pair. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[1] pins. 21 22 MDIN[2] MDIP[2] I/O Media Dependent Interface[2]. In 1000BASE-T mode in MDI configuration, MDIN/P[2]correspond to BI_DC±. In MDIX configuration, MDIN/P[2] corresponds to BI_DD±. In 100BASE-TX and 10BASE-T modes, MDIN/P[2]are not used. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[2] pins. 17 18 MDIN[3] MDIP[3] I/O Media Dependent Interface[3]. In 1000BASE-T mode in MDI configuration, MDIN/P[3] correspond to BI_DD±. In MDIX configuration, MDIN/P[3] correspond to BI_DC±. In 100BASE-TX and 10BASE-T modes, MDIN/P[3] are not used. NOTE: Unused MDI pins must be left floating. The device contains an internal 100Ω resistor between the MDIP/N[3] pins. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 29 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 21: Management Interface and Interrupt 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 7 MDC I MDC is the management data clock reference for the serial management interface. A continuous clock stream is not expected. The maximum frequency supported is 12 MHz. 8 MDIO I/O MDIO is the management data. MDIO transfers management data in and out of the device synchronously to MDC. This pin requires a pull-up resistor in a range from 1.5 kΩ to 10 kΩ. Table 22: LED Interface 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 14 LED[0] O LED output. 13 LED[1] I/O LED output 12 LED[2]/INTn O LED/Interrupt outputs. LED[2] pin also functions as an active low interrupt pin. Table 23: Clock/Configuration/Reset/I/O 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 15 CONFIG I Hardware Configuration. 9 CLK125 O 125 MHz Clock Output synchronized with the 25 MHz reference clock 34 XTAL_IN I Reference Clock. 25 MHz ± 50 ppm tolerance crystal reference or oscillator input. NOTE: The XTAL_IN pin is not 2.5V/3.3V tolerant. Refer to ‘Oscillator level shifting’ application note to convert a 2.5V/3.3V clock source to 1.8V clock. 33 XTAL_OUT O Reference Clock. 25 MHz ± 50 ppm tolerance crystal reference. When the XTAL_OUT pin is not connected, it should be left floating. 16 RESETn I Hardware reset. Active low. 0 = Reset 1 = Normal operation Table 24: SGMII I/Os 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 2 1 S_INN S_INP I SGMII Receive Data. 1.25 GBaud input - Positive and Negative. 5 4 S_OUTN S_OUTP O SGMII Transmit Data. 1.25 GBaud output - Positive and Negative. Doc. No. MV-S107146-U0 Rev. E Page 30 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Description Table 25: Control and Reference 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 30 RSET I Constant voltage reference. External 4.99 kΩ 1% resistor connection to VSS is required for this pin. Table 26: Test 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 31 32 HSDACN HSDACP Analog O Test Pins. These pins are used to bring out a differential TX_TCLK. Connect these pins with a 50Ω termination resistor to VSS for IEEE testing g. If IEEE testing are not important, these pins may be left floating. 29 TSTPT O DC Test Point. The TSTPT pin should be left floating. Table 27: Power, Ground, and Internal Regulators 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 35 AVDDC18 Power Analog supply - 1.8V1. AVDDC18 can be supplied externally with 1.8V, or via the 1.8V internal regulator. 3 19 26 38 AVDD18 Power Analog supply - 1.8V. AVDD18 can be supplied externally with 1.8V, or via the 1.8V internal regulator. 20 25 AVDD33 Power Analog Supply - 3.3V. 36 REG_IN Power Analog Supply for the internal regulator – 3.3V. If the internal regulator is not used, this pin must be left open – No connect. NOTE: For further details on pin connections, refer to the Section 2.21, Regulators and Power Supplies, on page 68. NOTE: Ensure that these pins are left floating when the internal regulator is not used. Connecting these two pins to either another power supply or ground will damage the device. 37 41 REGCAP1 REGCAP2 Capacitor terminal pins for the internal regulator. Connect a 220 nF ± 10% ceramic capacitor between REGCAP1 and REGCAP2 on the board and place it close to the device. If the internal regulator is not used, these pins must be left open (no connect). NOTE: Ensure that these pins are left floating when the internal regulator is not used. Connecting these two pins to either another power supply or ground will damage the device. 39 AVDD18_OUT Power Regulator output - 1.8V. If the internal regulator is used, this pin must be connected to 1.8V power plane that connected to AVDD18 and AVDDC18. If the external supply is used, this pin must be left open (no-connect). 40 DVDD_OUT Power Regulator output - 1.0V. If the internal regulator is used, this pin must be connected to 1.0V power plane that connected to DVDD. If the external supply is used, this pin must be left open (no-connect). 11 49 52 VDDO Power 3.3V or 2.5V or 1.8V digital I/O supply2. See VDDO_SEL for further details. VDDO must be supplied externally when 3.3V or 2.5V is used. For 1.8V operation, the 1.8V regulator output can be used. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 31 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 27: Power, Ground, and Internal Regulators (Continued) 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 10 VDDO_SEL Power VDDO Voltage Control. For VDDO 2.5V/3.3V operation, VDDO_SEL must be tied to VSS. For VDDO 1.8V operation, VDDO_SEL must be tied to VDDO. 6 42 DVDD Power Digital core supply - 1.0V. DVDD can be supplied externally with 1.0V or via the 1.0V internal regulator. 50 51 53 54 55 56 VSS GND These pins must be tied to the GND. EPAD VSS GND Ground to device. The 56-pin QFN package has an exposed die pad (E-PAD) at its base. This EPAD must be soldered to VSS. Refer to the package mechanical drawings for the exact location and dimensions of the EPAD. 1. AVDDC18 supplies the XTAL_IN and XTAL_OUT pins. 2. VDDO supplies the MDC, MDIO, RESETn, LED[2:0], CONFIG, CLK125, VDDO_SEL, and the RGMII pins. Table 28: No Connect 56-QFN Pi n # P in N a m e P in Ty p e D e s c r i p t io n 43 44 45 46 47 48 NC -- These pins must be left floating. Table 29: I/O State at Various Test or Reset Modes P in (s ) Lo o pb a c k S of tw ar e R e se t Hardware Reset P ow e r D o w n MDIN/MDIP Active Tri-state Tri-state Tri-state S_OUTP/OUTN Active Active Tri-state Tri-state MDIO Active Active Tri-state Active LED[2:0] Active Active Active, drive HIGH Active RX_CLK Active Active Tri-state Active RX_CTRL Active Active Tri-state Active RXD[3:0] Active Active Tri-state Active TX_CLK (MII mode) Active Active Tri-state Active CLK125 Active Active Active Active NOTE: I/O State is valid only when clock is available and stable for minimum 10 clock cycles; otherwise, I/O state is undefined. Doc. No. MV-S107146-U0 Rev. E Page 32 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Assignment List 1.2 Pin Assignment List 1.2.1 88E1510 48-Pin QFN Pin Assignment List - Alphabetical by Signal Name Table 30: 88E1510 48-Pin QFN Pin Assignment List - Alphabetical by Signal Name Pin # P in N a m e Pin # P in N a m e 33 AVDD18_OUT 18 MDIP[2] 15 AVDD18 14 MDIP[3] 22 AVDD18 32 REGCAP1 30 AVDDC18 35 REGCAP2 16 AVDD33 31 REG_IN 21 AVDD33 40 RX_CLK 6 CLK125 37 RX_CTRL 11 CONFIG 12 RESETn 3 DVDD 25 RSET 36 DVDD 38 RXD[0] 34 DVDD_OUT 39 RXD[1] 26 HSDACN 41 RXD[2] 27 HSDACP 42 RXD[3] 10 LED[0] 47 TX_CLK 9 LED[1] 2 TX_CTRL 8 LED[2]/INTn 44 TXD[0] 4 MDC 45 TXD[1] 23 MDIN[0] 48 TXD[2] 19 MDIN[1] 1 TXD[3] 17 MDIN[2] 7 VDDO 13 MDIN[3] 43 VDDO 5 MDIO 46 VDDO 24 MDIP[0] 29 XTAL_IN 20 MDIP[1] 28 XTAL_OUT Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 33 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 1.2.2 88E1518 48-Pin QFN Pin Assignment List - Alphabetical by Signal Name Table 31: 88E1518 48-Pin QFN Pin Assignment List - Alphabetical by Signal Name Pin # P in N a m e Pin # P in N a m e 33 AVDD18_OUT 18 MDIP[2] 15 AVDD18 14 MDIP[3] 22 AVDD18 32 REGCAP1 30 AVDDC18 35 REGCAP2 16 AVDD33 31 REG_IN 21 AVDD33 40 RX_CLK 6 CLK125 37 RX_CTRL 11 CONFIG 12 RESETn 3 DVDD 25 RSET 36 DVDD 38 RXD[0] 34 DVDD_OUT 39 RXD[1] 26 HSDACN 41 RXD[2] 27 HSDACP 42 RXD[3] 10 LED[0] 47 TX_CLK 9 LED[1] 2 TX_CTRL 8 LED[2]/INTn 44 TXD[0] 4 MDC 45 TXD[1] 23 MDIN[0] 48 TXD[2] 19 MDIN[1] 1 TXD[3] 17 MDIN[2] 7 VDDO 13 MDIN[3] 43 VDDO 5 MDIO 46 VDDO 24 MDIP[0] 29 XTAL_IN 20 MDIP[1] 28 XTAL_OUT Doc. No. MV-S107146-U0 Rev. E Page 34 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Signal Description Pin Assignment List 1.2.3 88E1512 56-Pin QFN Pin Assignment List - Alphabetical by Signal Name Table 32: 88E1512 56-Pin QFN Pin Assignment List - Alphabetical by Signal Name Pin # P in N a m e Pin # P in N a m e 39 AVDD18_OUT 37 REGCAP1 3 AVDD18 41 REGCAP2 19 AVDD18 36 REG_IN 26 AVDD18 46 RX_CLK 38 AVDD18 43 RX_CTRL 35 AVDDC18 16 RESETn 20 AVDD33 30 RSET 25 AVDD33 44 RXD[0] 9 CLK125 45 RXD[1] 15 CONFIG 47 RXD[2] 6 DVDD 48 RXD[3] 40 DVDD_OUT 2 S_INN 42 DVDD 1 S_INP 31 HSDACN 5 S_OUTN 32 HSDACP 4 S_OUTP 14 LED[0] 29 TSTPT 13 LED[1] 53 TX_CLK 12 LED[2]/INTn 56 TX_CTRL 7 MDC 50 TXD[0] 27 MDIN[0] 51 TXD[1] 23 MDIN[1] 54 TXD[2] 21 MDIN[2] 55 TXD[3] 17 MDIN[3] 11 VDDO 8 MDIO 49 VDDO 28 MDIP[0] 52 VDDO 24 MDIP[1] 10 VDDO_SEL 22 MDIP[2] 34 XTAL_IN 18 MDIP[3] 33 XTAL_OUT Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 35 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 1.2.4 88E1514 56-Pin QFN Pin Assignment List - Alphabetical by Signal Name Table 33: 88E1514 56-Pin QFN Pin Assignment List - Alphabetical by Signal Name Pin # P in N a m e Pin # P in N a m e 39 AVDD18_OUT 43 NC 3 AVDD18 44 NC 19 AVDD18 45 NC 26 AVDD18 46 NC 38 AVDD18 47 NC 35 AVDDC18 48 NC 20 AVDD33 16 RESETn 25 AVDD33 30 RSET 9 CLK125 37 REGCAP1 15 CONFIG 41 REGCAP2 6 DVDD 36 REG_IN 40 DVDD_OUT 2 S_INN 42 DVDD 1 S_INP 31 HSDACN 5 S_OUTN 32 HSDACP 4 S_OUTP 14 LED[0] 29 TSTPT 13 LED[1] 11 VDDO 12 LED[2]/INTn 49 VDDO 7 MDC 52 VDDO 27 MDIN[0] 10 VDDO_SEL 23 MDIN[1] 53 VSS 21 MDIN[2] 56 VSS 17 MDIN[3] 50 VSS 8 MDIO 51 VSS 28 MDIP[0] 54 VSS 24 MDIP[1] 55 VSS 22 MDIP[2] 34 XTAL_IN 18 MDIP[3] 33 XTAL_OUT Doc. No. MV-S107146-U0 Rev. E Page 36 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Modes of Operation and Major Interfaces 2 PHY Functional Specifications The device is a single-port 10/100/1000 Gigabit Ethernet transceiver. Figure 8 shows the functional block diagram of the device. See Product Overview, on page 3 for a list of features supported by the device. Note Figure 8: Device Functional Block Diagram TX_CLK Waveshape Filter D/A 10/100/1000 Transmit PCS Echo Canceller TXD[3:0] Trellis Decoder MDIP/N[0] MDIP/N[1] MDIP/N[2] MDIP/N[3] Timing Control Active Hybrid Gain Control Baseline A/D 10BASE-T Receiver DPLL Skew Control Near End Crosstalk Canceller Serial Interface 1.0V & 1.8V Regulators REG_IN (3.3V) MDC MDIO Management Interface Feed Forward Equalizer RX_CLK 10/100/1000 Receive PCS Registers LED RX_CTRL RXD[3:0] RSET HSDACP/N XTAL_IN XTAL_OUT RESETn CLK125 Clock/ Reset Auto Negotiation S_INP/N S_OUTP/N Decision Feedback Equalizer BIAS/ Test LED[1:0] LED[2]/INTn 2.1 TX_CTRL Configuration CONFIG Modes of Operation and Major Interfaces The device has three separate major electrical interfaces:  MDI to Copper Cable (88E1510/88E1518/88E1512/88E1514 devices)  SERDES/SGMII (88E1512/88E1514 device only)  RGMII (88E1510/88E1518/88E1512 devices) Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 37 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public The MDI is always a media interface. The RGMII is always a system interface. The SGMII can either be a system interface, or a media interface. (The system interface is also known as MAC interface. It is typically the connection between the PHY and the MAC or the system ASIC). Block diagrams showing the different applications of the 88E1510/88E1518/88E1512/88E1514 devices are provided in Figure 9, Figure 10, and Figure 11. Figure 9: 88E1512/88E1514 SGMII/SERDES System to Copper Media Interface Example 10/100/1000 Mbps Transceiver SERDES SGMII Alaska® 88E1512/88E1514 PHY Device Magnetics RJ-45 Media Type - 10BASE-T - 100BASE-TX - 1000BASE-T The 88E1512/88E1514 device can be used in media conversion applications that require a conversion from 1000BASE-T to 1000BASE-X provided the 1000BASE-X auto negotiation is disabled on both the upstream device and on the 88E1512/88E1514 device. The 88E1512/88E1514 device in this application must be configured to operate in SGMII to Copper(MODE[2:0]=001) for the conversion with the SGMII Auto-Negotiation disabled through Register 0_1.12=0. When used as a system interface, the device implements the PHY SGMII Auto-Negotiation status (link, duplex, etc.) advertisements as specified in the Cisco SGMII specification. The system interface replicates the speed and duplex setting of the media interface. When used as a Media interface, the device implements the MAC SGMII Auto-Negotiation function, which monitors PHY status advertisements. For details of how SGMII Auto-Negotiation operates, see Section 2.8.3, SGMII Auto-Negotiation, on page 53 as well as the Cisco SGMII specification 1.8. Figure 10: 88E1510/88E1518 RGMII System to Copper Interface Example 10/100/1000 Mbps Ethernet MAC System Interface - RGMII Alaska® 88E1510/88E1518 PHY Device Magnetics RJ-45 Media Type - 10BASE-T - 100BASE-TX - 1000BASE-T Figure 11: 88E1512 RGMII System to SERDES Interface Example 10/100/1000 Mbps Ethernet MAC with RGMII System Interface - RGMII Alaska® 88E1512 PHY Device Doc. No. MV-S107146-U0 Rev. E Page 38 SFP Media Type - SGMII - 1000BASE-X - 1000BASE-FX Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Copper Media Interface The 88E1512 device supports 5 modes of operation as shown in Table 34. For modes of operation supported by 88E1510, 88E1518, 88E1514, refer to Table 1. The behavior of the 1.25 GHz SERDES interface is selected by setting the MODE[2:0] register in 20_18.2:0. The SERDES can operate in 100BASE-FX, 1000BASE-X, SGMII (System), and SGMII (Media). Table 34: MODE[2:0] Select M O D E [ 2 : 0 ] R e g i st e r 20 _ 1 8 . 2 : 0 Description 000 RGMII (System mode) to Copper 001 SGMII (System mode) to Copper 010 RGMII (System mode) to 1000BASE-X 011 RGMII (System mode) to 100BASE-FX 100 RGMII (System mode) to SGMII (Media mode) 101 Reserved 110 Reserved 111 Reserved 20_18.2:0 defaults to 111 for 88E1512/88E1514. Therefore 20_18.2:0 must be programmed with the desired mode of operation. 20_18.2:0 defaults to 000 for 88E1510/88E1518. When link is up, two of the three interfaces pass packets back and forth. The unused interface is powered down. There is no need to power down the unused interface via registers 0_0.11 and 0_1.11. The unused interface will automatically power down when not needed. 2.2 Copper Media Interface The copper interface consists of the MDIP/N[3:0] pins that connect to the physical media for 1000BASE-T, 100BASE-TX, and 10BASE-T modes of operation. The device integrates MDI termination resistors. The IEEE 802.3 specification requires that both sides of a link have termination resistors to prevent reflections. Traditionally, these resistors and additional capacitors are placed on the board between a PHY device and the magnetics. The resistors have to be very accurate to meet the strict IEEE return loss requirements. Typically, ± 1% accuracy resistors are used on the board. These additional components between the PHY and the magnetics complicate board layout. Integrating the resistors has many advantages including component cost savings, better ICT yield, board reliability improvements, board area savings, improved layout, and signal integrity improvements. 2.2.1 Transmit Side Network Interface 2.2.1.1 Multi-mode TX Digital to Analog Converter The device incorporates a multi-mode transmit DAC to generate filtered 4D PAM 5, MLT3, or Manchester coded symbols. The transmit DAC performs signal wave shaping to reduce EMI. The transmit DAC is designed for very low parasitic loading capacitances to improve the return loss requirement, which allows the use of low cost transformers. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 39 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 2.2.1.2 Slew Rate Control and Waveshaping In 1000BASE-T mode, partial response filtering and slew rate control are used to minimize high frequency EMI. In 100BASE-TX mode, slew rate control is used to minimize high frequency EMI. In 10BASE-T mode, the output waveform is pre-equalized via a digital filter. 2.2.2 Encoder 2.2.2.1 1000BASE-T In 1000BASE-T mode, the transmit data bytes are scrambled to 9-bit symbols and encoded into 4D PAM5 symbols. Upon initialization, the initial scrambling seed is determined by the PHY address. This prevents multiple devices from outputting the same sequence during idle, which helps to reduce EMI. 2.2.2.2 100BASE-TX In 100BASE-TX mode, the transmit data stream is 4B/5B encoded, serialized, and scrambled. 2.2.2.3 10BASE-T In 10BASE-T mode, the transmit data is serialized and converted to Manchester encoding. 2.2.3 Receive Side Network Interface 2.2.3.1 Analog to Digital Converter The device incorporates an advanced high speed ADC on each receive channel with greater resolution than the ADC used in the reference model of the IEEE 802.3ab standard committee. Higher resolution ADC results in better SNR, and therefore, lower error rates. Patented architectures and design techniques result in high differential and integral linearity, high power supply noise rejection, and low metastability error rate. The ADC samples the input signal at 125 MHz. 2.2.3.2 Active Hybrid The device employs a sophisticated on-chip hybrid to substantially reduce the near-end echo, which is the super-imposed transmit signal on the receive signal. The hybrid minimizes the echo to reduce the precision requirement of the digital echo canceller. The on-chip hybrid allows both the transmitter and receiver to use the same transformer for coupling to the twisted pair cable, which reduces the cost of the overall system. 2.2.3.3 Echo Canceller Residual echo not removed by the hybrid and echo due to patch cord impedance mismatch, patch panel discontinuity, and variations in cable impedance along the twisted pair cable result in drastic SNR degradation on the receive signal. The device employs a fully developed digital echo canceller to adjust for echo impairments from more than 100 meters of cable. The echo canceller is fully adaptive to compensate for the time varying nature of channel conditions. 2.2.3.4 NEXT Canceller The 1000BASE-T physical layer uses all 4 pairs of wires to transmit data to reduce the baud rate requirement to only 125 MHz. This results in significant high frequency crosstalk between adjacent pairs of cable in the same bundle. The device employs 3 parallel NEXT cancellers on each receive channel to cancel any high frequency crosstalk induced by the adjacent 3 transmitters. A fully adaptive digital filter is used to compensate for the time varying nature of channel conditions. Doc. No. MV-S107146-U0 Rev. E Page 40 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Copper Media Interface 2.2.3.5 Baseline Wander Canceller Baseline wander is more problematic in the 1000BASE-T environment than in the traditional 100BASE-TX environment due to the DC baseline shift in both the transmit and receive signals. The device employs an advanced baseline wander cancellation circuit to automatically compensate for this DC shift. It minimizes the effect of DC baseline shift on the overall error rate. 2.2.3.6 Digital Adaptive Equalizer The digital adaptive equalizer removes inter-symbol interference at the receiver. The digital adaptive equalizer takes unequalized signals from ADC output and uses a combination of feedforward equalizer (FFE) and decision feedback equalizer (DFE) for the best-optimized signal-to-noise (SNR) ratio. 2.2.3.7 Digital Phase Lock Loop In 1000BASE-T mode, the slave transmitter must use the exact receive clock frequency it sees on the receive signal. Any slight long-term frequency phase jitter (frequency drift) on the receive signal must be tracked and duplicated by the slave transmitter; otherwise, the receivers of both the slave and master physical layer devices have difficulty canceling the echo and NEXT components. In the device, an advanced DPLL is used to recover and track the clock timing information from the receive signal. This DPLL has very low long-term phase jitter of its own, thereby maximizing the achievable SNR. 2.2.3.8 Link Monitor The link monitor is responsible for determining if link is established with a link partner. In 10BASE-T mode, link monitor function is performed by detecting the presence of valid link pulses (NLPs) on the MDIP/N pins. In 100BASE-TX and 1000BASE-T modes, link is established by scrambled idles. If Force Link Good register 16_0.10 is set high, the link is forced to be good and the link monitor is bypassed for 100BASE-TX and 10BASE-T modes. In the 1000BASE-T mode, register 16_0.10 has no effect. 2.2.3.9 Signal Detection In 1000BASE-T mode, signal detection is based on whether the local receiver has acquired lock to the incoming data stream. In 100BASE-TX mode, the signal detection function is based on the receive signal energy detected on the MDIP/N pins that is continuously qualified by the squelch detect circuit, and the local receiver acquiring lock. 2.2.4 Decoder 2.2.4.1 1000BASE-T In 1000BASE-T mode, the receive idle stream is analyzed so that the scrambler seed, the skew among the 4 pairs, the pair swap order, and the polarity of the pairs can be accounted for. Once calibrated, the 4D PAM 5 symbols are converted to 9-bit symbols that are then descrambled into 8-bit data values. If the descrambler loses lock for any reason, the link is brought down and calibration is restarted after the completion of Auto-Negotiation. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 41 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 2.2.4.2 100BASE-TX In 100BASE-TX mode, the receive data stream is recovered and converted to NRZ. The NRZ stream is descrambled and aligned to the symbol boundaries. The aligned data is then parallelized and 5B/4B decoded. The receiver does not attempt to decode the data stream unless the scrambler is locked. The descrambler “locks” to the scrambler state after detecting a sufficient number of consecutive idle code-groups. Once locked, the descrambler continuously monitors the data stream to make sure that it has not lost synchronization. The descrambler is always forced into the unlocked state when a link failure condition is detected, or when insufficient idle symbols are detected. 2.2.4.3 10BASE-T In 10BASE-T mode, the recovered 10BASE-T signal is decoded from Manchester to NRZ, and then aligned. The alignment is necessary to insure that the start of frame delimiter (SFD) is aligned to the nibble boundary. 2.3 1.25 GHz SERDES Interface The 1.25 GHz SERDES Interface can be configured as an SGMII to be hooked up to a MAC or as a 100BASE-FX/1000BASE-X/SGMII to be hooked up to the media. 2.3.1 Electrical Interface The input and output buffers of the 1.25 GHz SERDES interface are internally terminated by 50Ω impedance. No external terminations are required. The output swing can be adjusted by programming register 26_1.2:0. The 1.25 GHz SERDES I/Os are Current Mode Logic (CML) buffers. CML I/Os can be used to connect to other components with PECL or LVDS I/Os. See the “Reference Design Schematics” and “Fiber Interface” application note for details. Figure 12: CML I/Os CML Outputs CML Inputs Internal bias1 Internal bias1 50 ohm 50 ohm 50 ohm S_OUTP S_OUTN S_INP Internal bias Isink 50 ohm S_INN 1. Internal bias is generated from the AVDD18 supply. Doc. No. MV-S107146-U0 Rev. E Page 42 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications MAC Interfaces 2.4 MAC Interfaces 2.4.1 SGMII The 88E1512/88E1514 device supports the SGMII specification revision 1.8, except for the carrier extension block that has to be carried out in software. This interface supports 10, 100 and 1000 Mbps modes of operation. 2.4.1.1 SGMII Speed and Link When the SGMII MAC interface is used, the media interface can only be copper. The operational speed of the SGMII MAC interface is determined according to Table 35 media interface status and/or loopback mode. Table 35: SGMII (System Interface) Operational Speed L in k S t a t u s o r M e d i a I n t e r f a c e S t a t u s S G M II ( M A C I n t e r f a c e ) S p e e d No Link Determined by speed setting of Register 21_ 2.6,13 MAC Loopback Determined by speed setting of Register 21_2.6, 13 1000BASE-T at 1000 Mbps 1000 Mbps 100BASE-TX at 100 Mbps 100 Mbps 10BASE-T at 10 Mbps 10 Mbps Two registers are available to determine whether the SGMII achieved link and sync. Status Register 17_1.5 indicates that the SERDES locked onto the incoming KDKDKD… sequence. Register 17_ 1.10 indicates whether link is established on the SERDES. If SGMII Auto-Negotiation is disabled, register 17_1.10 has the same meaning as register 17_1.5. If SGMII Auto-Negotiation is enabled, then register 17_1.10 indicates whether SGMII Auto-Negotiation successfully established link. 2.4.1.2 SGMII TRR Blocking When the SGMII receives a packet with odd number of bytes, a single symbol of carrier extension will be passed on and transmitted onto 1000BASE-T. This carrier extension may cause problems with full-duplex MACs that incorrectly handle the carrier extension symbols. When register 16_1.13 is set to 1, all carrier extend and carrier extend with error symbols received by the SGMII will be converted to idle symbols when operating in full-duplex. Carrier extend and carrier extend with error symbols will not be blocked when operating in half-duplex, or if register 16_1.13 is set to 0. Note that symbol errors will continue to be propagated regardless of the setting of register 16_1.13. 2.4.1.3 False SERDES Link Up Prevention The SERDES interface can operate in 1000BASE-X mode where an unconnected optical receiver can sometimes send full swing noise into the PHY. This random noise will look like a real signal and falsely cause the 1000BASE-X PCS to link up. A noise filtering state machine can be enabled to reduce the probability of false link up. When the state machine is enabled it will cause a small delay in link up time. 1000BASE-X noise filtering is enabled through the register below. Table 36: Fiber Noise Filtering R e g is t e r F un c ti o n S e tti ng Mode HW R st SW Rst 26_1.14 1000BASE-X Noise Filtering 1 = Enable 0 = Disable R/W 0 Retain Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 43 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 2.4.2 RGMII The device supports the RGMII specification (Version 1.2a, 9/22/2000, version 2.0, 04/2002). Four RGMII timing modes, with different receive clock to data timing and transmit clock to data timing, can be programmed by setting 21_2.4 and 21_2.5 described in Register 21_2.5. For timing details, see Section 4.10.2, RGMII Delay Timing for Different RGMII Modes, on page 142. Both Tx and Rx delays are enabled by default. Depending on the delay settings in the MAC, these delays may have to be modified. Table 37: RGMII Signal Mapping D e v i c e P in N a m e RGMII Spec Pin Name D e s c r ip t i o n TX_CLK TXC 125 MHz, 25 MHz, or 2.5 MHz transmit clock with ±50 ppm tolerance based on the selected speed. TX_CTRL TX_CTL Transmit Control Signals. TX_EN is encoded on the rising edge of TX_CLK, TX_ER XORed with TX_EN is encoded on the falling edge of TX_CLK. TXD[3:0] TD[3:0] Transmit Data. In 1000BASE-T mode, TXD[3:0] are presented on both edges of TX_CLK. In 100BASE-TX and 10BASE-T modes, TXD[3:0] are presented on the rising edge of TX_CLK. RX_CLK RXC 125 MHz, 25 MHz, or 2.5 MHz receive clock derived from the received data stream and based on the selected speed. RX_CTRL RX_CTL Receive Control Signals. RX_DV is encoded on the rising edge of RX_CLK, RX_ER XORed with RX_DV is encoded on the falling edge of RX_CLK. RXD[3:0] RD[3:0] Receive Data. In 1000BASE-T mode, RXD[3:0] are presented on both edges of RX_CLK. In 100BASE-TX and 10BASE-T modes, RXD[3:0] are presented on the rising edge of RX_CLK. Figure 13: RGMII Signal Diagram RGMII TXC TX_CTL TD[3:0] MAC RXC RX_CTL RD[3:0] Doc. No. MV-S107146-U0 Rev. E Page 44 TX_CLK TX_CTRL TXD[3:0] PHY RX_CLK RX_CTRL RXD[3:0] Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Loopback 2.4.3 10/100 Mbps Functionality The RGMII supports 10 Mbps and 100 Mbps operation by reducing the clock-rate to 2.5 MHz and 25 MHz respectively as shown in Table 37 on page 44. During packet reception, RX_CLK may be stretched on either the positive or negative pulse to accommodate the transition from the free running clock to a data synchronous clock domain. When the speed of the PHY changes, a similar stretching of the positive or negative pulse is allowed. No glitching of the clocks is allowed during speed transitions. The MAC must hold TX_CTRL (TX_CTL) low until the MAC has ensured that TX_CTRL (TX_CTL) is operating at the same speed as the PHY. 2.4.4 TX_ER and RX_ER Coding See the RGMII Specifications for definitions of TX_ER, RX_ER, and in band status coding. In RGMII mode, Register 21_2.3 is the register bit used to block carrier extension. 2.5 Loopback The device implements various different loopback paths. 2.5.1 System Interface Loopback The functionality, timing, and signal integrity of the System interface can be tested by placing the device in System interface loopback mode. This can be accomplished by setting register 0_0.14 = 1, if copper is the selected media, or 0_1.14 = 1, if fiber is the selected media. In loopback mode, the data received from the MAC is not transmitted out on the media interface. Instead, the data is looped back and sent to the MAC. During loopback, media link will be lost and packets will not be received. If loopback is enabled while Auto-Negotiating, FLP Auto-Negotiation codes will be transmitted onto the copper media. If loopback is enabled in forced 10BASE-T mode, 10BASE-T idle link pulses will be transmitted on the copper side. If loopback is enabled in forced 100BASE-T mode, 100BASE-T idles will be transmitted on the copper side. The speed of the SGMII or RGMII is determined by register 21_2.6, 13 during loopback. 21_2.2:6,13 is 00 = 10 Mbps, 01 = 100 Mbps, 10 = 1000 Mbps. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 45 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Figure 14: MAC Interface Loopback Diagram - Copper Media Interface MAC SERDES (SGMII) or RGMII PCS (Copper) System Interface 0_0.14 = 1 PMA (Copper) PMD (Copper) Copper Interface Figure 15: System Interface Loopback Diagram - Fiber Media Interface MAC RGMII PCS (Fiber) System Interface 0_1.14 = 1 PMA (Fiber) PMD (Fiber) Fiber Interface Doc. No. MV-S107146-U0 Rev. E Page 46 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Loopback 2.5.2 Line Loopback Line loopback allows a link partner to send frames into the device to test the transmit and receive data path. Frames from a link partner into the PHY, before reaching the MAC interface pins, are looped back and sent out on the line. They are also sent to the MAC. The packets received from the MAC are ignored during line loopback. Refer to Figure 16. This allows the link partner to receive its own frames. Before enabling the line loopback feature, the PHY must first establish link to another PHY link partner. If Auto-Negotiation is enabled, both link partners should advertise the same speed and full-duplex. If Auto-Negotiation is disabled, both link partners need to be forced to the same speed and full-duplex. Once link is established, the line loopback mode can be enabled. Register 21_2.14 = 1 enables the line loopback on the copper interface. Register 16_1.12 = 1 and 16_1.8 = 0 enables the line loopback of the 1000BASE-X/SGMII media interface. Figure 16: Copper Line Loopback Data Path MAC SERDES (SGMII) or RGMII System Interface PCS (Copper) 21_2.14 = 1 PMA (Copper) PMD (Copper) Copper Interface Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 47 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Figure 17: Fiber Line Loopback Data Path MAC RGMII PCS (Fiber) PMA (Fiber) System Interface 16_1.12 = 1 and 16_1.8 = 0 PMD (Fiber) Fiber Interface (1000BASE-X or SGMII Media) 2.5.3 External Loopback For production testing, an external loopback stub allows testing of the complete data path without the need of a link partner. For 10BASE-T and 100BASE-TX modes, the loopback test requires no register writes. For 1000BASE-T mode, register 18_6.3 must be set to 1 to enable the external loopback. All copper modes require an external loopback stub. The loopback stub consists of a plastic RJ-45 header, connecting RJ-45 pair 1,2 to pair 3,6 and connecting pair 4,5 to pair 7,8, as seen in Figure 18. Figure 18: Loopback Stub (Top View with Tab up) 1 2 3 4 5 6 7 8 Doc. No. MV-S107146-U0 Rev. E Page 48 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Resets The external loopback test setup requires the presence of a MAC that will originate the frames to be sent out through the PHY. Instead of a normal RJ-45 cable, the loopback stubs allows the PHY to self-link at 10/100/1000 Mbps. It also allows the actual external loopback. See Figure 19. The MAC should see the same packets it sent looped back to it. Figure 19: Test Setup for 10/100/1000 Mbps Modes using an External Loopback Stub Loopback Stub Alaska® PHY MAC 2.6 1 2 3 4 5 6 7 8 Magnetics/ RJ-45 Resets In addition to the hardware reset pin (RESETn) there are several software reset bits as summarized in Table 38. The copper, fiber, and RGMII circuits are reset per port via register 0_0.15 and 0_1.15 respectively. A reset in one circuit does not directly affect another circuit. Register 20_18.15 resets the mode control, port power management, and generator and checkers. All the reset registers described so far self clear. Table 38: Reset Control Bits R e s e t R e g i st e r R e g is t e r E f f e c t F un c ti o na l B lo c k 0_0.15 Software Reset for Registers in page 0, 2, 3, 5, 7 Copper 0_1.15 Software Reset for Registers in page 1 Fiber/SGMII 20_18.15 Software Reset for Registers in page 6 and 18 Generator/Checker/Mode 2.7 Power Management The device supports several advanced power management modes that conserve power. 2.7.1 Low Power Modes Four low power modes are supported in the device.  IEEE 22.2.4.1.5 compliant power down  Energy Detect (Mode 1)  Energy Detect+TM (Mode 2) Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 49 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public IEEE 22.2.4.1.5 power down compliance allows for the PHY to be placed in a low-power consumption state by register control. Energy Detect (Mode 1) allows the device to wake up when energy is detected on the wire. Energy Detect+TM (Mode 2) is identical to Mode 1 with the additional capability to wake up a link partner. In Mode 2, the 10BASE-T link pulses are sent once every second while listening for energy on the line. Details of each mode are described below. 2.7.1.1 IEEE Power Down Mode The standard IEEE power down mode is entered by setting register 0_0.11 or 0_1.11. In this mode, the PHY does not respond to any system interface (i.e., RGMII/SGMII) signals except the MDC/MDIO. It also does not respond to any activity on the copper or fiber media. In this power down mode, the PHY cannot wake up on its own by detecting activity on the media. It can only wake up by setting registers 0_0.11 and 16_0.2 = 0 for copper and 0_1.11 = 0 for Fiber. Note that Register 0_0.11 or 16_0.2 may be set to 1 to power down the copper media. As shown in Table 39, each power down control independently powers down its respective circuits. In general, it is not necessary to power down an unused interface. The PHY will automatically power down any unused circuit. The automatic PHY power management can be overridden by setting the power down control bits. These bits have priority over the PHY power management in that the circuit can not be powered up by the power management when its associated power down bit is set to 1. When a circuit is power back up by setting the bit to 0, a software reset is also automatically sent to the corresponding circuit. Table 39: Power Down Control Bits 2.7.1.2 Reset Register Register Effect 0_0.11 Copper Power Down 16_0.2 Copper Power Down 0_1.11 Fiber/SGMII Power Down Copper Energy Detect Modes The device can be placed in energy detect power down modes by selecting either of the two energy detect modes. Both modes enable the PHY to wake up on its own by detecting activity on the CAT 5 cable. The status of the energy detect is reported in register 17_0.4 and the energy detect changes are reported in register 19_0.4. The energy detect modes only apply to the copper media. The energy detect modes will not work while Fiber/Copper Auto Select (2.5 “Fiber/Copper Auto-Selection” on page 45) is enabled. Normal 10/100/1000 Mbps operation can be entered by turning off energy detect mode by setting register 16_0.9:8 to 0x. Energy Detect (Mode 1) Energy Detect (Mode 1) is entered by setting register 16_0.9:8 to 10. In Mode 1, only the signal detection circuitry and serial management interface are active. If the PHY detects energy on the line, it starts to Auto-Negotiate sending FLPs for 5 seconds. If at the end of 5 seconds the Auto-Negotiation is not completed, then the PHY stops sending FLPs and goes back to monitoring receive energy. If Auto-Negotiation is completed, then the PHY goes into normal 10/100/1000 Mbps operation. If during normal operation the link is lost, the PHY will re-start Auto-Negotiation. If no energy is detected after 5 seconds, the PHY goes back to monitoring receive energy. Doc. No. MV-S107146-U0 Rev. E Page 50 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Auto-Negotiation Energy Detect +TM (Mode 2) Energy Detect (Mode 2) is entered by setting register 16_0.9:8 to 11. In Mode 2, the PHY sends out a single 10 Mbps NLP (Normal Link Pulse) every one second. Except for this difference, Mode 2 is identical to Mode 1 operation. If the device is in Mode 1, it cannot wake up a connected device; therefore, the connected device must be transmitting NLPs, or either device must be woken up through register access. If the device is in Mode 2, then it can wake a connected device. Power Down Modes When the PHY exits power down (register 0_0.11= 0 and 16_0.2=0) the active state will depend on whether the energy detect function is enabled (register 16_0.9:8 = 1x). If the energy detect function is enabled, the PHY will transition to the energy detect state first and will wake up only if there is a signal on the wire. Table 40: Power Down Modes R e g is t e r 0 _ 0 . 11 2.7.2 R e g i st e r 16 _ 0 . 2 R e g i s t e r 1 6_ 0 . 9 : 8 Behavior 1 x xx Power down x 1 xx Power down RGMII/SGMII MAC Interface Power Down In some applications, the MAC interface must run continuously regardless of the state of the media interface. Additional power will be required to keep the MAC interface running during low power states. If absolute minimal power consumption is required during network interface power down mode or in the Energy Detect modes, then register 16_2.3 or 16_1.3 should be set to 0 to allow the MAC interface to power down. In general 16_2.3 is used when the network interface is copper and 16_1.3 is used when the network interface is fiber. Note that for these settings to take effect a software reset must be issued. 2.8 Auto-Negotiation The device supports three types of Auto-Negotiation.  10/100/1000BASE-T Copper Auto-Negotiation. (IEEE 802.3 Clauses 28 and 40)  1000BASE-X Fiber Auto-Negotiation (IEEE 802.3 Clause 37)  SGMII Auto-Negotiation (Cisco specification) Auto-Negotiation provides a mechanism for transferring information from the local station to the link partner to establish speed, duplex, and Master/Slave preference (in the case of Copper Auto-Negotiation) during a link session. Auto-Negotiation is initiated upon any of the following conditions:  Power up reset  Hardware reset  Software reset (Register 0_0.15 or 0_1.15)  Restart Auto-Negotiation (Register 0_0.9 or 0_1.9)  Transition from power down to power up (Register 0_0.11 or 0_1.11)  The link goes down The following sections describe each of the Auto-Negotiation modes in detail. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 51 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 2.8.1 10/100/1000BASE-T Auto-Negotiation The 10/100/1000BASE-T Auto-Negotiation (AN) is based on Clause 28 and 40 of the IEEE 802.3 specification. It is used to negotiate speed, duplex, and flow control over CAT5 UTP cable. Once Auto-Negotiation is initiated, the device determines whether or not the remote device has Auto-Negotiation capability. If so, the device and the remote device negotiate the speed and duplex with which to operate. If the remote device does not have Auto-Negotiation capability, the device uses the parallel detect function to determine the speed of the remote device for 100BASE-TX and 10BASE-T modes. If link is established based on the parallel detect function, then it is required to establish link at half-duplex mode only. Refer to IEEE 802.3 clauses 28 and 40 for a full description of Auto-Negotiation. After hardware reset, 10/100/1000BASE-T Auto-Negotiation can be enabled and disabled via Register 0_0.12. Auto MDI/MDIX and Auto-Negotiation may be disabled and enabled independently. When Auto-Negotiation is disabled, the speed and duplex can be set via registers 0_0.13, 0_0.6, and 0_0.8 respectively. When Auto-Negotiation is enabled the abilities that are advertised can be changed via registers 4_0 and 9_0. Changes to registers 0_0.12, 0_0.13, 0_0.6 and 0_0.8 do not take effect unless one of the following takes place:  Software reset (registers 0_0.15)  Restart Auto-Negotiation (register 0_0.9)  Transition from power down to power up (register 0_0.11)  The copper link goes down To enable or disable Auto-Negotiation, Register 0_0.12 should be changed simultaneously with either register 0_0.15 or 0_0.9. For example, to disable Auto-Negotiation and force 10BASE-T half-duplex mode, register 0_0 should be written with 0x8000. Registers 4_0 and 9_0 are internally latched once every time the Auto-Negotiation enters the Ability Detect state in the arbitration state machine. Hence, a write into Register 4_0 or 9_0 has no effect once the device begins to transmit Fast Link Pulses (FLPs).This guarantees that sequences of FLPs transmitted are consistent with one another. Register 7_0 is treated in a similar way as registers 4_0 and 9_0 during additional next page exchanges. If 1000BASE-T mode is advertised, then the device automatically sends the appropriate next pages to advertise the capability and negotiate Master/Slave mode of operation. If the user does not wish to transmit additional next pages, then the next page bit (Register 4_0.15) can be set to zero, and the user needs to take no further action. If next pages in addition to the ones required for 1000BASE-T are needed, then the user can set register 4_0.15 to one, and send and receive additional next pages via registers 7_0 and 8_0, respectively. The device stores the previous results from register 8 in internal registers, so that new next pages can overwrite register 8_0. Note that 1000BASE-T next page exchanges are automatically handled by the device without user intervention, regardless of whether or not additional next pages are sent. Once the device completes Auto-Negotiation, it updates the various status in registers 1_0, 5_0, 6_ 0, and 10_0. Speed, duplex, page received, and Auto-Negotiation completed status are also available in registers 17_0 and 19_0. Refer to Register 17_0 and 19_0. Doc. No. MV-S107146-U0 Rev. E Page 52 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Auto-Negotiation 2.8.2 1000BASE-X Auto-Negotiation 1000BASE-X Auto-Negotiation is defined in Clause 37 of the IEEE 802.3 specification. It is used to Auto-Negotiate duplex and flow control over fiber cable. Registers 0_1, 4_1, 5_1, 6_1, and 15_1 are used to enable AN, advertise capabilities, determine link partner’s capabilities, show AN status, and show the duplex mode of operation respectively. Register 22.7:0 must be set to one to view the fiber Auto-Negotiation registers. The device supports Next Page option for 1000BASE-X Auto-Negotiation. Register 7_1 of the fiber pages is used to transmit Next Pages, and register 8_1 of the fiber pages is used to store the received Next Pages. The Next Page exchange occurs with software intervention. The user must set Register 4_1.15 to enable fiber Next Page exchange. Each Next Page received in the registers should be read before a new Next Page to be transmitted is loaded in Register 7_1. If the PHY enables 1000BASE-X Auto-Negotiation and the link partner does not, the link cannot link up. The device implements an Auto-Negotiation bypass mode. For more details, see Section 2.8.3.1, Serial Interface Auto-Negotiation Bypass Mode, on page 53. 2.8.3 SGMII Auto-Negotiation SGMII is a de-facto standard designed by Cisco. SGMII uses 1000BASE-X coding to send data as well as Auto-Negotiation information between the PHY and the MAC. However, the contents of the SGMII Auto-Negotiation are different than the 1000BASE-X Auto-Negotiation. See the “Cisco SGMII Specification” and the “MAC Interfaces and Auto-Negotiation” application note for further details. The device supports SGMII with and without Auto-Negotiation. Auto-Negotiation can be enabled or disabled by writing to Register 0_1.12 followed by a soft reset. If SGMII Auto-Negotiation is disabled, the MAC interface link, speed, and duplex status (determined by the media side) cannot be conveyed to the MAC from the PHY. The user must program the MAC with this information in some other way (e.g., by reading PHY registers for link, speed, and duplex status). However, the operational speed of the SGMII will follow the speed of the media (See Table 35 on page 43) regardless of whether the Auto-Negotiation is enabled or disabled. In case of RGMII to SGMII mode of operation, the SGMII behaves as if it were the SGMII on the MAC side of the interface. When Auto-Negotiation is enabled, the SGMII Auto-Negotiation information like the speed, duplex, and link received from the PHY is used for determining the mode of operation. The RGMII will be adjusted accordingly when the SGMII Auto-Negotiation is completed. 2.8.3.1 Serial Interface Auto-Negotiation Bypass Mode If the MAC or the PHY implements the Auto-Negotiation function and the other does not, two-way communication is not possible unless Auto-Negotiation is manually disabled and both sides are configured to work in the same operational modes. To solve this problem, the device implements the SGMII Auto-Negotiation Bypass Mode. When entering the state “Ability_Detect”, a bypass timer begins to count down from an initial value of approximately 200 ms. If the device receives idles Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 53 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public during the 200 ms, the device will interpret that the other side is “alive” but cannot send configuration codes to perform Auto-Negotiation. After 200 ms, the state machine will move to a new state called “Bypass_Link_Up” in which the device assumes a link-up status and the operational mode is set to the value listed under the “Comments” column of Table 41. For further details, see Section 2.1, Modes of Operation and Major Interfaces. Table 41: SGMII Auto-Negotiation modes R e g . 0 _ 1 .1 2 Reg. 26_1.6 C om m e n t s 0 X No Auto-Negotiation. User responsible for determining speed, link, and duplex status by reading PHY registers. 1 0 Normal SGMII Auto-Negotiation. Speed, link, and duplex status automatically communicated to the MAC during Auto-Negotiation. 1 1 MAC Auto-Negotiation enabled. Normal operation. MAC Auto-Negotiation disabled. After 200 ms the PHY will disable Auto-Negotiation and link based on idles. 2.9 CRC Error Counter and Frame Counter The CRC counter and packet counters, normally found in MACs, are available in the device. The error counter and packet counter features are enabled through register writes and each counter is stored in eight register bits. Register 18_18.2:0 controls which path the CRC checker and packet counter is counting. If register 18_18.2:0 is set to 010 then the Copper receive path is checked. If register 18_18.2:0 is set to 100 then the SGMII input path is checked. If register 18_18.2:0 is set to 110 then the RGMII input path is checked. 2.9.1 Enabling the CRC Error Counter and Packet Counter To enable the counters to count, set register 18_18.2:0 to a non-zero value. To disable the counters, set register 18_18.2:0 to 000. To read the CRC counter and packet counter, read register 17_18. 17_18.15:8 (Frame count is stored in these bits) 17_18.7:0 (CRC error count is stored in these bits) The CRC counter and packet counter do not clear on a read command. To clear the counters, write Register 18_18.4 = 1. The register 18_18.4 is a self-clear bit. Disabling the counters by writing register 18_18.2:0 to 000 will also reset the counters. 2.10 Packet Generator The device contains a very simple packet generator. Register 16_18.7:5 lists the device Packet Generator register details. When 16_18.7:5 is set to 010 packets are generated on the copper transmit path. When 16_18.7:5 is set to 100 packets are generated on the SGMII transmit path. When 16_18.7:5 is set to 110 packets are generated on the RGMII transmit path. Doc. No. MV-S107146-U0 Rev. E Page 54 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications 1.25G PRBS Generator and Checker Once enabled, fixed length packets of 64 or 1518 bytes (including CRC) will be transmitted separated by 12 bytes of IPG.The preamble length will be 8 bytes. The payload of the packet is either a fixed 5A, A5, 5A, A5 pattern or a pseudo random pattern. A correct IEEE CRC is appended to the end of the packet. An error packet can also be generated. The registers are as follows: 16_18.7:5 Packet generation enable. 000 = Normal operation, Else = Enable internal packet generator. 16_18.2 Payload type. 0 = Pseudo random, 1 = Fixed 5A, A5, 5A, A5,... 16_18.1 Packet length. 0 = 64 bytes, 1 = 1518 bytes 16_18.0 Error packet. 0 = Good CRC, 1 = Symbol error and corrupt CRC. 16_18.15:8 Packet Burst Size. 0x00 = Continuous, 0x01 to 0xFF = Burst 1 to 255 packets. If register 16_18.15:8 is set to a non-zero value, then register 16_18.7:5 will self clear once the required number of packets are generated. Note that if register 16_18.7:5 is manually set to 0 while packets are still bursting, the bursting will cease immediately once the current active packet finishes transmitting. The value in register 16_18.15:8 should not be changed while 16_18.7:5 is set to a non-zero value. 2.11 1.25G PRBS Generator and Checker A PRBS generator and checker are available for use on the 1.25G SERDES. PRBS7,PRBS23, and PRBS31 are supported. A 32-bit checker is implemented. Note that the reads are atomic. A read to the LSB will update the MSB register. The counters only clear when register 23_1.4 is set to 1. This bit self clears. The checker and generator polarity can be inverted by setting registers 23_1.7 and 23_1.6 respectively. Register 23_1.5 controls whether the checker has to lock before counting commences. Table 42: 1.25 GHz SERDES PRBS Registers R e g is t e r F u n c tio n S e tt in g 23_1.7 Invert Checker Polarity 0 = Invert 1 = Normal 23_1.6 Invert Generator Polarity 0 = Invert 1 = Normal 23_1.5 PRBS Lock 0 = Counter Free Runs 1 = Do not start counting until PRBS locks first 23_1.4 Clear Counter 0 = Normal 1 = Clear Counter 23_1.3:2 Pattern Select 00 = PRBS 7 01 = PRBS 23 10 = PRBS 31 11 = Generate 1010101010...pattern 23_1.1 PRBS Checker Enable 0 = Disable 1 = Enable 23_1.0 PRBS Generator Enable 0 = Disable 1 = Enable Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 55 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 42: 1.25 GHz SERDES PRBS Registers (Continued) R e g is t e r F u n c tio n S e tt in g 24_1.15:0 PRBS Error Count LSB A read to this register freezes register 25_1. Cleared only when register 23_1.4 is set to 1. 25_1.15:0 PRBS Error Count MSB This register does not update unless register 24_1 is read first. Cleared only when register 23_1.4 is set to 1. 2.12 MDI/MDIX Crossover The device automatically determines whether or not it needs to cross over between pairs as shown in Table 43 so that an external crossover cable is not required. If the device interoperates with a device that cannot automatically correct for crossover, the device makes the necessary adjustment prior to commencing Auto-Negotiation. If the device interoperates with a device that implements MDI/MDIX crossover, a random algorithm as described in IEEE 802.3 clause 40.4.4 determines which device performs the crossover. When the device interoperates with legacy 10BASE-T devices that do not implement Auto-Negotiation, the device follows the same algorithm as described above since link pulses are present. However, when interoperating with legacy 100BASE-TX devices that do not implement Auto-Negotiation (i.e. link pulses are not present), the device uses signal detect to determine whether or not to crossover. The auto MDI/MDIX crossover function can be disabled via register 16_0.6:5. The pin mapping in MDI and MDIX modes is shown in Table 43. Table 43: Media Dependent Interface Pin Mapping Pi n MDI MDIX 1000BASE-T 100BASE-TX 10BASE-T 10 0 0 B A S E - T 100BASE-TX 10BASE-T MDIP/N[0] BI_DA± TX± TX± BI_DB± RX± RX± MDIP/N[1] BI_DB± RX± RX± BI_DA± TX± TX± MDIP/N[2] BI_DC± unused unused BI_DD± unused unused MDIP/N[3] BI_DD± unused unused BI_DC± unused unused Table 43 assumes no crossover on PCB. Note The MDI/MDIX status is indicated by Register 17_0.6. This bit indicates whether the receive pairs (3,6) and (1,2) are crossed over. In 1000BASE-T operation, the device can correct for crossover between pairs (4,5) and (7,8) as shown in Table 43. However, this is not indicated by Register 17_ 0.6. If 1000BASE-T link is established, pairs (1,2) and (3,6) crossover is reported in register 21_5.4, and pairs (4,5) and (7,8) crossover is reported in register 21_5.5. 2.13 Polarity Correction The device automatically corrects polarity errors on the receive pairs in 1000BASE-T and 10BASE-T modes. In 100BASE-TX mode, the polarity does not matter. Doc. No. MV-S107146-U0 Rev. E Page 56 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications FLP Exchange Complete with No Link In 1000BASE-T mode, receive polarity errors are automatically corrected based on the sequence of idle symbols. Once the descrambler is locked, the polarity is also locked on all pairs. The polarity becomes unlocked only when the receiver loses lock. In 10BASE-T mode, polarity errors are corrected based on the detection of validly spaced link pulses. The detection begins during the MDI crossover detection phase and locks when the 10BASE-T link is up. The polarity becomes unlocked when link is down. The polarity correction status is indicated by Register 17_0.1. This bit indicates whether the receive pair (3,6) is polarity reversed in MDI mode of operation. In MDIX mode of operation, the receive pair is (1,2) and Register 17_0.1 indicates whether this pair is polarity reversed. Although all pairs are corrected for receive polarity reversal, Register 17_0.1 only indicates polarity reversal on the pairs described above. If 1000BASE-T link is established register 21_5.3:0 reports the polarity on all 4 pairs. Polarity correction can be disabled by register write 16_0.1 = 1. Polarity will then be forced in normal 10BASE-T mode. 2.14 FLP Exchange Complete with No Link Sometimes when link does not come up, it is difficult to determine whether the failure is due to the Auto-Negotiation Fast Link Pulse (FLP) not completing or from the 10/100/1000BASE-T link not being able to come up. Register 19_0.3 is a sticky bit that gets set to 1 whenever the FLP exchange is completed but the link cannot be established for some reason. Once the bit is set, it can be cleared only by reading the register. This bit will not be set if the FLP exchange is not completed, or if link is established. 2.15 Duplex Mismatch Indicator When operating in half-duplex mode collisions should occur within the first 512 bit times. Collisions that are detected after this point can indicate an incorrect environment (too many repeaters in the system, too long cable) or it can indicate that the link partner thinks the link is a full-duplex link. Registers 23_6.7:0, 23_6.15:8, 24_6.7:0, and 24_6.15:8 are 8 bit counters that count late collisions. They will increment only when the PHY is in half-duplex mode and only applies to the copper interface. Each counter increments when a late collision is detected in a certain window as shown in Table 44. The four late collision counters will increment based on when the late collision starts. The counters clear on read. If the counter reaches FF it will not roll over. Table 44: Late Collision Registers R e g is t e r F u n c tio n S e tt in g Mode 23_6.15:8 Late Collision 97-128 bytes This counter increments by 1 when the PHY is in half-duplex and a start of packet is received while the 96th to 128th bytes of the packet are transmitted. RO, SC The measurement is done at the internal GMII. The counter will not roll over and will clear on read. 23_6.7:0 Late Collision 65-96 bytes This counter increments by 1 when the PHY is in half-duplex and a start of packet is received while the 65th to 96th bytes of the packet are transmitted. RO, SC The measurement is done at the internal GMII. The counter will not roll over and will clear on read. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 57 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 44: Late Collision Registers (Continued) R e g is t e r F u n c tio n S e tt in g Mode 24_6.15:8 Late Collision >192 bytes This counter increments by 1 when the PHY is in half-duplex and a start of packet is received after 192 bytes of the packet are transmitted. RO, SC The measurement is done at the internal GMII. The counter will not roll over and will clear on read. 24_6.7:0 Late Collision 129-192 bytes This counter increments by 1 when the PHY is in half-duplex and a start of packet is received while the 129th to 192nd bytes of the packet are transmitted. RO, SC The measurement is done at the internal GMII. The counter will not roll over and will clear on read. 25_6.12:8 Late Collision Window Adjust Number of bytes to advance in late collision window. 0 = start at 64th byte, 1 = start at 63rd byte, etc. R/W The real point of measurement for late collision should be done at the MAC and not at the PHY. In order to compensate for additional latency between the PHY and the MAC register 25_6.12:8 is used to move the window earlier. For example, if register 25_6.12.8 is set to 2 then the first window is 63 to 94 bytes, the second window is 95 to 129 bytes, etc. It is up to the user to program this register correctly since it is system dependent. 2.16 LED The LED[2:0] pins can be used to drive LED pins. Registers 16_3, 17_3, and 18_3 control the operation of the LED pins. LED[1:0] are used to configure the PHY per Section 2.18.1, Hardware Configuration, on page 65. After the configuration is completed, LED[1:0] will operate per the setting in 16_3.7:0. In general, 16_3.11:8 control the LED[2] pin, 16_3.7:4 control the LED[1] pin, and 16_3.3:0 control the LED[0] pin. These are referred to as single LED modes. However, there are some LED modes where LED[1:0] operate as a unit. These are entered when 16_3.3:2 are set to 11. These are referred to as dual LED modes. In dual LED modes, register 16_ 3.7:4 have no meaning when 16_3.3:2 are set to 11. Figure 20 shows the general chaining of function for the LEDs. The various functions are described in the following sections. Figure 20: LED Chain Media Link Status Receive Activity Transmit Activity Pulse Stretch Pulse Stretch Logic Logic Blink Logic Mix Polarity LED[2:0] Manual Override and Control Doc. No. MV-S107146-U0 Rev. E Page 58 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications LED 2.16.1 LED Polarity There are a variety of ways to hook up the LEDs. Some examples are shown in Figure 21. In order to make things more flexible registers 17_3.5:4, 17_3.3:2, and 17_3.1:0 specify the output polarity for the LED[2:0]. The lower bit of each pair specifies the on (active) state of the LED, either high or low. The upper bit of each pair specifies whether the off state of the LED should be driven to the opposite level of the on state or Hi-Z. Figure 21: Various LED Hookup Configurations 2.16.2 Single LED High Active Single LED Low Active Table 45: LED Polarity Three terminal bi-color LED High Active Three terminal bi-color LED Low Active Two terminal bi-color LED R e g is t e r P in D e f in it io n 17_3.5:4 LED[2] Polarity 00 = On - drive LED[2] low, Off - drive LED[2] high 01 = On - drive LED[2] high, Off - drive LED[2] low 10 = On - drive LED[2] low, Off - tristate LED[2] 11 = On - drive LED[2] high, Off - tristate LED[2] 17_3.3:2 LED[1] Polarity 00 = On - drive LED[1] low, Off - drive LED[1] high 01 = On - drive LED[1] high, Off - drive LED[1] low 10 = On - drive LED[1] low, Off - tristate LED[1] 11 = On - drive LED[1] high, Off - tristate LED[1] 17_3.1:0 LED[0] Polarity 00 = On - drive LED[0] low, Off - drive LED[0] high 01 = On - drive LED[0] high, Off - drive LED[0] low 10 = On - drive LED[0] low, Off - tristate LED[0] 11 = On - drive LED[0] high, Off - tristate LED[0] Pulse Stretching and Blinking Register 18_3.14:12 specify the pulse stretching duration of a particular activity. Only the transmit activity, receive activity, and (transmit or receive) activity are stretched. All other statuses are not stretched since they are static in nature and no stretching is required. Some status will require blinking instead of a solid on. Register 18_3.10:8 specify the blink rate. Note that the pulse stretching is applied first and the blinking will reflect the duration of the stretched pulse. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 59 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public The stretched/blinked output will then be mixed if needed (Section 2.16.3, Bi-Color LED Mixing, on page 60) and then inverted/Hi-Z according to the polarity described in Section 2.16.1, LED Polarity, on page 59. Table 46: Pulse Stretching and Blinking 2.16.3 R e g is t e r P in D e f in it io n 18_3.14:12 Pulse stretch duration 000 = No pulse stretching 001 = 21 ms to 42 ms 010 = 42 ms to 84 ms 011 = 84 ms to 170 ms 100 = 170 ms to 340 ms 101 = 340 ms to 670 ms 110 = 670 ms to 1.3s 111 = 1.3s to 2.7s 18_3.10:8 Blink Rate 000 = 42 ms 001 = 84 ms 010 = 170 ms 011 = 340 ms 100 = 670 ms 101 to 111 = Reserved Bi-Color LED Mixing In the dual LED modes the mixing function allows the 2 colors of the LED to be mixed to form a third color. This is useful since the PHY is tri-speed and the three colors each represent one of the speeds. Register 17_3.15:12 control the amount to mix in the LED[1] pin. Register 17_3.11:8 control the amount to mix in the LED[0] pin. The mixing is determined by the percentage of time the LED is on during the active state. The percentage is selectable in 12.5% increments. Note that there are two types of bi-color LEDs. There is the three terminal type and the 2 terminal type. For example, the third and fourth LED block from the left in Figure 21 illustrates three terminal types, and the one on the far right is the two terminal type. In the three terminal type both of the LEDs can be turned on at the same time. Hence the sum of the percentage specified by 17_3.15:12 and 17_3.11:8 can exceed 100%. However, in the two terminal type the sum should never exceed 100% since only one LED can be turned on at any given time. Doc. No. MV-S107146-U0 Rev. E Page 60 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications LED The mixing only applies when register 16_3.3:0 are set to 11xx. There is no mixing in single LED modes. Table 47: Bi-Color LED Mixing R e g is t e r F un c ti o n D e f in it io n 17_3.15:12 LED[1] mix percentage When using 2 terminal bi-color LEDs the mixing percentage should not be set greater than 50%. 0000 = 0% 0001 = 12.5% . . 0111 = 87.5% 1000 = 100% 1001 to 1111 = Reserved 17_3.11:8 LED[0] mix percentage When using 2 terminal bi-color LEDs the mixing percentage should not be set greater than 50%. 0000 = 0% 0001 = 12.5%, . . . 0111 = 87.5% 1000 = 100% 1001 to 1111 = Reserved Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 61 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 2.16.4 Modes of Operation The LED pins relay some modes of the PHY so that these modes can be displayed by the LEDs. Most of the single LED modes are self-explanatory from the register map of register 16_3. The non-obvious ones are covered in this section. Table 48: Modes of Operation R e g is t e r P in D e f in it io n 16_3.11:8 LED[2] Control 0000 = On - Link, Off - No Link 0001 = On - Link, Blink - Activity, Off - No Link 0010 = On- Full Duplex, Blink- Collision, Off- Half Duplex 0011 = On - Activity, Off - No Activity 0100 = Blink - Activity, Off - No Activity 0101 = On - Transmit, Off - No Transmit 0110 = On - 10/1000 Mbps Link, Off - Else 0111 = On - 10 Mbps Link, Off - Else 1000 = Force Off 1001 = Force On 1010 = Force Hi-Z 1011 = Force Blink 11xx = Reserved 16_3.7:4 LED[1] Control If 16_3.3:2 is set to 11 then 16_3.7:4 has no effect 0000 = On- Receive, Off- No Receive 0001 = On - Link, Blink - Activity, Off - No Link 0010 = On - Link, Blink - Receive, Off - No Link 0011 = On - Activity, Off - No Activity 0100 = Blink - Activity, Off - No Activity 0101 = On- 100 Mbps Link/ Fiber Link 0110 = On - 100/1000 Mbps Link, Off - Else 0111 = On - 100 Mbps Link, Off - Else 1000 = Force Off 1001 = Force On 1010 = Force Hi-Z 1011 = Force Blink 11xx = Reserved 16_3.3:0 LED[0] Control 0000 = On - Link, Off - No Link 0001 = On - Link, Blink - Activity, Off - No Link 0010 = 3 blinks - 1000 Mbps 2 blinks - 100 Mbps 1 blink - 10 Mbps 0 blink - No Link 0011 = On - Activity, Off - No Activity 0100 = Blink - Activity, Off - No Activity 0101 = On - Transmit, Off - No Transmit 0110 = On - Copper Link, Off - Else 0111 = On - 1000 Mbps Link, Off - Else 1000 = Force Off 1001 = Force On 1010 = Force Hi-Z 1011 = Force Blink 1100 = MODE 1 (Dual LED mode) 1101 = MODE 2 (Dual LED mode) 1110 = MODE 3 (Dual LED mode) 1111 = MODE 4 (Dual LED mode) Doc. No. MV-S107146-U0 Rev. E Page 62 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications LED 2.16.4.1 Compound LED Modes Compound LED modes are defined in Table 49. Table 49: Compound LED Status 2.16.4.2 C o m p o un d M o d e D e s c r i p t io n Activity Transmit Activity OR Receive Activity Link 10BASE-T link OR 100BASE-TX Link OR 1000BASE-T Link Speed Blink When 16_3.3:0 is set to 0010 the LED[0] pin takes on the following behavior. LED[0] outputs the sequence shown in Table 50 depending on the status of the link. The sequence consists of 8 segments. If a 1000 Mbps link is established the LED[0] outputs 3 pulses, 100 Mbps 2 pulses, 10 Mbps 1 pulse, and no link 0 pulses. The sequence repeats over and over again indefinitely. The odd numbered segment pulse duration is specified in 18_3.1:0. The even numbered pulse duration is specified in 18_3.3:2. Table 50: Speed Blinking Sequence S eg m e n t 10 Mbps 1 0 0 M bp s 1000 Mbps N o L in k D u r a t io n 1 On On On Off 18_3.1:0 2 Off Off Off Off 18_3.3:2 3 Off On On Off 18_3.1:0 4 Off Off Off Off 18_3.3:2 5 Off Off On Off 18_3.1:0 6 Off Off Off Off 18_3.3:2 7 Off Off Off Off 18_3.1:0 8 Off Off Off Off 18_3.3:2 Table 51: Speed Blink 2.16.4.3 R e g is t e r P in D e f in i tio n 18_3.3:2 Pulse Period for even segments 00 = 84 ms 01 = 170 ms 10 = 340 ms 11 = 670 ms 18_3.1:0 Pulse Period for odd segments 00 = 84 ms 01 = 170 ms 10 = 340 ms 11 = 670 ms Manual Override When 16_3.11:10, 16_3.7:6, and 16_3.3:2 are set to 10 the LED[2:0] are manually forced. Registers 16_3.9:8, 16_3.5:4, and 16_3.1:0 then select whether the LEDs are to be on, off, Hi-Z, or blink. If bi-color LEDs are used, the manual override will select only one of the 2 colors. In order to get the third color by mixing MODE 1 and MODE 2 should be used (Section 2.16.4.4, MODE 1, MODE 2, MODE 3, MODE 4, on page 64). Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 63 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 2.16.4.4 MODE 1, MODE 2, MODE 3, MODE 4 MODE 1 to 4 are dual LED modes. These are used to mix to a third color using bi-color LEDs. When 16_3.3:0 is set to 11xx then one of the 4 modes are enabled. MODE 1  Solid mixed color. The mixing is discussed in Section 2.16.3, Bi-Color LED Mixing, on page 60. MODE 2  Blinking mixed color. The mixing is discussed in Section 2.16.3, Bi-Color LED Mixing, on page 60. The blinking is discussed in section Section 2.16.2, Pulse Stretching and Blinking, on page 59. MODE 3  Behavior according to Table 52. MODE 4  Behavior according to Table 53. Note that MODE 4 is the same as MODE 3 except the 10 Mbps and 100 Mbps are reversed. Table 52: MODE 3 Behavior S ta tu s L E D [1 ] L ED [0 ] 1000 Mbps Link - No Activity Off Solid On 1000 Mbps Link - Activity Off Blink 100 Mbps Link - No Activity Solid Mix Solid Mix 100 Mbps Link - Activity Blink Mix Blink Mix 10 Mbps Link - No Activity Solid On Off 10 Mbps Link - Activity Blink Off No link Off Off Table 53: MODE 4 Behavior 2.17 S ta tu s L E D [1 ] LED[0] 1000 Mbps Link - No Activity Off Solid On 1000 Mbps Link - Activity Off Blink 100 Mbps Link - No Activity Solid On Off 100 Mbps Link - Activity Blink Off 10 Mbps Link - No Activity Solid Mix Solid Mix 10 Mbps Link - Activity Blink Mix Blink Mix No link Off Off Interrupt When Register 18_3.7 is set to 1, LED[2] outputs the interrupt. Register 18_3.11 selects the polarity of the interrupt signal when it is active, where 18_3.11 = 1 means it is active low and 18_3.11 = 0 means it is active high. Registers 18_0 and 18_2 are the Interrupt Enable registers for the copper media. Registers 19_0 and 19_2 are the Interrupt Status registers for the copper media. Register 18_1 is the Interrupt Enable register and 19_1 is the Interrupt Status register for the fiber media. Doc. No. MV-S107146-U0 Rev. E Page 64 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Configuring the 88E1510/88E1518/88E1512/88E1514 Device There are force bits and polarity bits for fiber and copper media See Table 54 and Table 55. Table 54: R e g is t e r F u nc t io n 18_3.15 Force Interrupt 18_3.11 Set Polarity Table 55: 2.18 Copper Fiber R e g is t e r F u nc t io n 26_1.15 Force Interrupt 16_1.2 Set Polarity Configuring the 88E1510/88E1518/88E1512/88E1514 Device The device can be configured two ways:  Hardware configuration strap options (unmanaged applications)  MDC/MDIO register writes (managed applications) The VDDO_LEVEL configuration bit can be overwritten by software. PHYAD cannot be overwritten. 2.18.1 Hardware Configuration After the deassertion of RESETn the device will be hardware configured. The device is configured through the CONFIG pin. This pin is used to configure 2 bits. The 2-bit value is set depending on what is connected to the CONFIG pin soon after the deassertion of hardware reset. The 2-bit mapping is shown in Table 56. Table 56: Two-Bit Mapping P in Bit 1,0 VSS 00 LED[0] 01 LED[1] 10 LED[2] Unused VDDO 11 The 2 bits for the CONFIG pin is mapped as shown in Table 57. Table 57: Configuration Mapping P in CONFIG Bit1 C O N F I G B it 0 Va l u e A s s ig n m e n t CONFIG 0 0 PHYAD[0] = 0 VDDO_LEVEL = 3.3V/1.8V CONFIG 1 1 PHYAD[0] = 1 VDDO_LEVEL = 3.3V/1.8V CONFIG 1 0 PHYAD[0] = 0 VDDO_LEVEL = 2.5V/1.8V CONFIG 0 1 PHYAD[0] = 1 VDDO_LEVEL = 2.5V/1.8V Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 65 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Each bit in the configuration is defined as shown in Table 58. Table 58: Configuration Definition Bits Defi ni ti o n R e g is t e r A f f e c t e d PHYAD[0]1 PHY Address LSB (Bit 0) None VDDO_LEVEL VDDO level at power up 1 = 2.5V/1.8V 0 = 3.3V/1.8V 3.3V/1.8V is assumed until this bit is initialized. 24_2.13 1. PHYAD[4:1] = 0000. 2.18.2 Software Configuration - Management Interface The management interface provides access to the internal registers via the MDC and MDIO pins and is compliant with IEEE 802.3u Clause 22 and Clause 45 MDIO protocol. MDC is the management data clock input and, it can run from DC to a maximum rate of 12 MHz. At high MDIO fanouts the maximum rate may be decreased depending on the output loading. MDIO is the management data input/output and is a bi-directional signal that runs synchronously to MDC. The MDIO pin requires a pull-up resistor in a range from 1.5 kΩ to 10 kΩ that pulls the MDIO high during the idle and turnaround phases of read and write operations. Bit 0 of the PHY address is configured during the hardware reset sequence. PHY address bits[4:1] are set to “0000” internally in the device. Refer to Section 2.18.1, Hardware Configuration, on page 65 for more information on how to configure this. Typical read and write operations on the management interface are shown in Figure 22 and Figure 23. All the required serial management registers are implemented as well as several optional registers. A description of the registers can be found in Section 3, 88E1510/88E1518/88E1512/88E1514 Register Description, on page 70. Figure 22: Typical MDC/MDIO Read Operation MDC MDIO 0 (STA) 1 1 0 A4 A3 A2 A1 A0 R4 R3 R2 R1 R0 Z MDIO 0 (PHY) IDLE OPCODE START (Read) PHY Address Register Address D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 TA Register Data IDLE Figure 23: Typical MDC/MDIO Write Operation MDC MDIO 0 (STA) IDLE 1 START 0 1 A4 A3 OPCODE (Write) A2 A1 PHY Address A0 R4 R3 R2 R1 R0 Register Address 1 0 D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 TA Doc. No. MV-S107146-U0 Rev. E Page 66 Register Data IDLE Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Jumbo Packet Support Table 59 is an example of a read operation. Table 59: Serial Management Interface Protocol 32-Bit Preamble S ta r t o f Frame O pC od e R e ad = 1 0 Wr it e = 01 5-Bit PHY D e v ic e Address 5 - B it P H Y Register Address (MSB) 2 - B it Tu r n a r o u nd Read = z0 Wr ite = 10 16 - B i t D a ta F ie l d Id le 11111111 01 10 00000 00000 z0 0001001100000000 11111111 2.18.2.1 Preamble Suppression The device is permanently programmed for preamble suppression. A minimum of one idle bit is required between operations. 2.19 Jumbo Packet Support The device supports jumbo packets up to 16Kbytes on all data paths. 2.20 Temperature Sensor The device features an internal temperature sensor. The sensor reports the die temperature and is updated approximately once per second. The temperature is obtained by reading the value in Register 26_6:4:0 and performing conversion functions as described in Table 60. An interrupt can be generated when the temperature exceeds a certain threshold. Register 26_6.6 is set high whenever the temperature is greater than or equal to the value programmed in register 26_6.12:8. Register 26_6.6 remains high until read. Register 26_6.7 controls whether the interrupt pin is asserted when register 26_6.6 is high. Table 60: Temperature Sensor R e g is t e r F un c ti o n S e t ti ng Mode HW Rst SW Rst 26_6.12:8 Temperature Threshold Temperature in C = 5 x 26_6.4:0 - 25 i.e., for 100C the value is 11001 R/W 11001 Retain 26_6.7 Temperature Sensor Interrupt Enable 1= Interrupt Enable 0 = Interrupt Enable R/W 0 Retain 26_6.6 Temperature Sensor Interrupt 1 = Temperature Reached Threshold 0 = Temperature Below Threshold RO, LH 0 0 26_6.4:0 Temperature Sensor Temperature in C = 5 x 26_6.4:0 - 25 i.e., for 100C the value is 11001 RO xxxxx xxxxx Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 67 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 2.21 Regulators and Power Supplies The 88E1510/88E1518/88E1512/88E1514 devices have built-in switch-cap regulators to support single rail operation from a 3.3V source. These internal regulators generate 1.8V and 1.0V. The integrated regulators greatly reduce the PCB BOM cost. If regulators are not used, external supplies (1.8V and 1.0V)are needed. Table 61 and Table 62 lists the valid combinations of regulator usage. The VDDO supply can run at 2.5V or 3.3V for the 88E1510 and 1.8V for 88E1518. 88E1512/88E1514 VDDO can operate at 1.8V/2.5V/3.3V supplies depending on the VDDO_SEL pin selection.  Note  If VDDO is tied to either 1.8V or 2.5V, then the I/Os are not 3.3V tolerant. AVDDC18 is tied to 1.8V, so the XTAL_IN pin is not 2.5V/3.3V tolerant. Table 61: Power Supply Options - Integrated Switching Regulator (REG_IN) F un c ti on a l D e s c r i p t io n AV D D 3 3 AV D D C 1 8 / AV D D 1 8 DVDD S et u p Supply Source 3.3V 1 . 8V from Internal Regulator 1 .0 V from Internal Regulator Single 3.3V external supply Internal regulator enabled Table 62: Power Supply Options - External Supplies F un c ti on a l D e s c r i p t io n AV D D 3 3 AV D D C 1 8 / AV D D 1 8 DVDD S et u p Supply Source 3.3V 1.8V External 1 .0 V from External 3.3V, 1.8V, 1.0V external supplies Internal regulator disabled. Note 2.21.1 When internal regulator option is preferred, both 1.0V and 1.8V regulators must be used. Supplying 1.0V internally and 1.8V externally (or vice versa) is not supported. AVDD18 AVDD18 is used as the 1.8V analog supply. AVDD18 can be supplied externally with 1.8V, or via the 1.8V regulator. 2.21.2 AVDDC18 AVDDC18 is used as a 1.8V analog supply for XTAL_IN/OUT pins. AVDDC18 can be supplied externally with 1.8V, or via the 1.8V regulator. 2.21.3 AVDD33 AVDD33 is used as a 3.3V analog supply. Doc. No. MV-S107146-U0 Rev. E Page 68 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 PHY Functional Specifications Regulators and Power Supplies 2.21.4 DVDD DVDD is used as the 1.0V digital supply. DVDD can be supplied externally with 1.0V, or via the internal switching 1.0V regulator. 2.21.5 REG_IN REG_IN is used as the 3.3V supply to the internal regulator that generates the 1.8V for AVDD18 and AVDDC18 and 1.0V for DVDD. If the 1.8V or 1.0V regulators are not used, REG_IN must be left floating in addition to leaving REGCAP1 and REGCAP2 floating. 2.21.6 AVDD18_OUT AVDD18_OUT is the internal regulator 1.8V output. This must be connected to 1.8V power plane that connects to AVDD18 and AVDDC18. If an external supply is used to supply AVDD18 and AVDDC18, AVDD18_OUT must be left floating. 2.21.7 DVDD_OUT DVDD_OUT is the internal regulator 1.0V output. When internal regulator is used, DVDD_OUT must be connected to the DVDD plane. If an external supply is used to supply DVDD, DVDD_OUT must be left floating. 2.21.8 VDDO VDDO supplies all digital I/O pins which use LVCMOS I/O standards. The supported voltages are 2.5V or 3.3V for 88E1510. 88E1518 supports only 1.8V. 88E1512/88E1514 supports 2.5V/3.3V if VDDO_SEL is tied to VSS and 1.8V if VDDO_SEL is tied to VDDO which is 1.8V. For VDDO 1.8V operation, the power can be supplied by the internal regulator. 2.21.9 Power Supply Sequencing On power-up, no special power supply sequencing is required. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 69 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 3 88E1510/88E1518/88E1512/88E1514 Register Description Table 63 below defines the register types used in the register map. Table 63: Register Types 3.1 Ty p e Description LH Register field with latching high function. If status is high, then the register is set to one and remains set until a read operation is performed through the management interface or a reset occurs. LL Register field with latching low function. If status is low, then the register is cleared to zero and remains zero until a read operation is performed through the management interface or a reset occurs. RES Reserved. All reserved bits are read as zero unless otherwise noted. Retain The register value is retained after software reset is executed. RO Read only. ROC Read only clear. After read, register field is cleared. RW Read and Write with initial value indicated. RWC Read/Write clear on read. All bits are readable and writable. After reset or after the register field is read, register field is cleared to zero. SC Self-Clear. Writing a one to this register causes the desired function to be immediately executed, then the register field is automatically cleared to zero when the function is complete. Update Value written to the register field doesn’t take effect until soft reset is executed. WO Write only. Reads from this type of register field return undefined data. NR Non-Rollover Register PHY MDIO Register Description The device supports Clause 22 MDIO register access protocol. Table 64: Register Map R e g is t e r N a m e R e g i s t e r A d d r e ss Ta b l e a n d P a ge Copper Control Register Page 0, Register 0 Table 65, p. 72 Copper Status Register Page 0, Register 1 Table 66, p. 74 PHY Identifier 1 Page 0, Register 2 Table 67, p. 75 PHY Identifier 2 Page 0, Register 3 Table 68, p. 76 Copper Auto-Negotiation Advertisement Register Page 0, Register 4 Table 69, p. 76 Copper Link Partner Ability Register - Base Page Page 0, Register 5 Table 70, p. 79 Copper Auto-Negotiation Expansion Register Page 0, Register 6 Table 71, p. 80 Copper Next Page Transmit Register Page 0, Register 7 Table 72, p. 80 Copper Link Partner Next Page Register Page 0, Register 8 Table 73, p. 81 1000BASE-T Control Register Page 0, Register 9 Table 74, p. 81 Doc. No. MV-S107146-U0 Rev. E Page 70 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 64: Register Map (Continued) R e g is t e r N a m e R e g i s t e r A d d r e ss Ta b l e a n d P a ge 1000BASE-T Status Register Page 0, Register 10 Table 75, p. 82 Extended Status Register Page 0, Register 15 Table 76, p. 83 Copper Specific Control Register 1 Page 0, Register 16 Table 77, p. 83 Copper Specific Status Register 1 Page 0, Register 17 Table 78, p. 85 Copper Specific Interrupt Enable Register Page 0, Register 18 Table 79, p. 86 Copper Interrupt Status Register Page 0, Register 19 Table 80, p. 87 Copper Specific Control Register 2 Page 0, Register 20 Table 81, p. 88 Copper Specific Receive Error Counter Register Page 0, Register 21 Table 82, p. 88 Page Address Page Any, Register 22 Table 83, p. 89 Global Interrupt Status Page 0, Register 23 Table 84, p. 89 Fiber Control Register Page 1, Register 0 Table 85, p. 89 Fiber Status Register Page 1, Register 1 Table 86, p. 91 PHY Identifier Page 1, Register 2 Table 87, p. 92 PHY Identifier Page 1, Register 3 Table 88, p. 92 Fiber Auto-Negotiation Advertisement Register 1000BASE-X Mode (Register 16_1.1:0 = 01) Page 1, Register 4 Table 89, p. 92 Fiber Auto-Negotiation Advertisement Register - SGMII (System mode) (Register 16_1.1:0 = 10) Page 1, Register 4 Table 90, p. 94 Fiber Auto-Negotiation Advertisement Register - SGMII (Media mode) (Register 16_1.1:0 = 11) Page 1, Register 4 Table 91, p. 94 Fiber Link Partner Ability Register - 1000BASE-X Mode (Register 16_1.1:0 = 01) Page 1, Register 5 Table 92, p. 95 Fiber Link Partner Ability Register - SGMII (System mode) (Register 16_1.1:0 = 10) Page 1, Register 5 Table 93, p. 96 Fiber Link Partner Ability Register - SGMII (Media mode) (Register 16_1.1:0 = 11) Page 1, Register 5 Table 94, p. 96 Fiber Auto-Negotiation Expansion Register Page 1, Register 6 Table 95, p. 97 Fiber Next Page Transmit Register Page 1, Register 7 Table 96, p. 97 Fiber Link Partner Next Page Register Page 1, Register 8 Table 97, p. 98 Extended Status Register Page 1, Register 15 Table 76, p. 83 Fiber Specific Control Register 1 Page 1, Register 16 Table 99, p. 99 Fiber Specific Status Register Page 1, Register 17 Table 100, p. 100 Fiber Interrupt Enable Register Page 1, Register 18 Table 101, p. 101 Fiber Interrupt Status Register Page 1, Register 19 Table 102, p. 102 PRBS Control Page 1, Register 23 Table 103, p. 102 PRBS Error Counter LSB Page 1, Register 24 Table 104, p. 103 PRBS Error Counter MSB Page 1, Register 25 Table 105, p. 103 Fiber Specific Control Register 2 Page 1, Register 26 Table 106, p. 103 MAC Specific Control Register 1 Page 2, Register 16 Table 107, p. 104 MAC Specific Interrupt Enable Register Page 2, Register 18 Table 108, p. 105 MAC Specific Status Register Page 2, Register 19 Table 109, p. 105 MAC Specific Control Register 2 Page 2, Register 21 Table 110, p. 106 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 71 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 64: Register Map (Continued) R e g is t e r N a m e R e g i s t e r A d d r e ss Ta b l e a n d P a ge RGMII Output Impedance Calibration Override Page 2, Register 24 Table 111, p. 107 LED[2:0] Function Control Register Page 3, Register 16 Table 112, p. 108 LED[2:0] Polarity Control Register Page 3, Register 17 Table 113, p. 109 LED Timer Control Register Page 3, Register 18 Table 114, p. 110 1000BASE-T Pair Skew Register Page 5, Register 20 Table 115, p. 111 1000BASE-T Pair Swap and Polarity Page 5, Register 21 Table 116, p. 111 Copper Port Packet Generation Page 6, Register 16 Table 117, p. 111 Copper Port CRC Counters Page 6, Register 17 Table 118, p. 112 Checker Control Page 6, Register 18 Table 119, p. 112 Copper Port Packet Generation Page 6, Register 19 Table 120, p. 113 Late Collision Counters 1 & 2 Page 6, Register 23 Table 121, p. 113 Late Collision Counters 3 & 4 Page 6, Register 24 Table 122, p. 113 Late Collision Window Adjust/Link Disconnect Page 6, Register 25 Table 123, p. 114 Misc Test Page 6, Register 26 Table 124, p. 114 Misc Test: Temperature Sensor Alternative Reading Page 6, Register 27 Table 125, p. 114 Packet Generation Page 18, Register 16 Table 126, p. 115 CRC Counters Page 18, Register 17 Table 127, p. 116 Checker Control Page 18, Register 18 Table 128, p. 116 Packet Generation Page 18, Register 19 Table 129, p. 116 General Control Register 1 Page 18, Register 20 Table 130, p. 117 Table 65: Copper Control Register Page 0, Register 0 B its Fi eld Mode HW Rst SW Rst Description 15 Copper Reset R/W, SC 0x0 SC Copper Software Reset. Affects pages 0, 2, 3, 5, and 7. Writing a 1 to this bit causes the PHY state machines to be reset. When the reset operation is done, this bit is cleared to 0 automatically. The reset occurs immediately. 1 = PHY reset 0 = Normal operation 14 Loopback R/W 0x0 0x0 When loopback is activated, the data from the MAC presented to the PHY is looped back inside the PHY and then sent back to the MAC. Link is broken when loopback is enabled. Loopback speed is determined by Registers 21_2.6,13. 1 = Enable Loopback 0 = Disable Loopback Doc. No. MV-S107146-U0 Rev. E Page 72 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 65: Copper Control Register (Continued) Page 0, Register 0 B its Fi eld Mode HW Rst SW Rst Description 13 Speed Select (LSB) R/W 0x0 Update Changes to this bit are disruptive to the normal operation; therefore, any changes to these registers must be followed by a software reset to take effect. A write to this register bit does not take effect until any one of the following also occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation Bit 6, 13 11 = Reserved 10 = 1000 Mbps 01 = 100 Mbps 00 = 10 Mbps 12 Auto-Negotiation Enable R/W 0x1 Update Changes to this bit are disruptive to the normal operation. A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation If Register 0_0.12 is set to 0 and speed is manually forced to 1000 Mbps in Registers 0.13 and 0.6, then Auto-Negotiation will still be enabled and only 1000BASE-T full-duplex is advertised if register 0_0.8 is set to 1, and 1000BASE-T half-duplex is advertised if 0.8 is set to 0. Registers 4.8:5 and 9.9:8 are ignored. Auto-Negotiation is mandatory per IEEE for proper operation in 1000BASE-T. 1 = Enable Auto-Negotiation Process 0 = Disable Auto-Negotiation Process 11 Power Down R/W 0x0 Retain Power down is controlled via register 0.11 and 16_0.2. Both bits must be set to 0 before the PHY will transition from power down to normal operation. When the port is switched from power down to normal operation, software reset and restart Auto-Negotiation are performed even when bits Reset (0_15) and Restart Auto-Negotiation (0.9) are not set by the user. IEEE power down shuts down the chip except for the RGMII interface if 16_2.3 is set to 1. If 16_2.3 is set to 0, then the RGMII interface also shuts down. 1 = Power down 0 = Normal operation 10 Isolate R/W 0x0 0x0 1 = Isolate 0 = Normal Operation 9 Restart Copper Auto-Negotiation R/W, SC 0x0 SC Auto-Negotiation automatically restarts after hardware or software reset regardless of whether or not the restart bit (0_ 0.9) is set. 1 = Restart Auto-Negotiation Process 0 = Normal operation Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 73 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 65: Copper Control Register (Continued) Page 0, Register 0 B its Fi eld Mode HW Rst SW Rst Description 8 Copper Duplex Mode R/W 0x1 Update Changes to this bit are disruptive to the normal operation; therefore, any changes to these registers must be followed by a software reset to take effect. A write to this register bit does not take effect until any one of the following also occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation 1 = Full-duplex 0 = Half-Duplex 7 Collision Test RO 0x0 0x0 This bit has no effect. 6 Speed Selection (MSB) R/W 0x1 Update Changes to this bit are disruptive to the normal operation; therefore, any changes to these registers must be followed by a software reset to take effect. A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation bit 6, 13 11 = Reserved 10 = 1000 Mbps 01 = 100 Mbps 00 = 10 Mbps 5:0 Reserved RO Always 000000 Always 000000 Will always be 0. Table 66: Copper Status Register Page 0, Register 1 B its Fi eld Mode HW Rst SW Rst Description 15 100BASE-T4 RO Always 0 Always 0 100BASE-T4. This protocol is not available. 0 = PHY not able to perform 100BASE-T4 14 100BASE-X Full-Duplex RO Always 1 Always 1 1 = PHY able to perform full-duplex 100BASE-X 13 100BASE-X Half-Duplex RO Always 1 Always 1 1 = PHY able to perform half-duplex 100BASE-X 12 10 Mbps Full-Duplex RO Always 1 Always 1 1 = PHY able to perform full-duplex 10BASE-T 11 10 Mbps Half-Duplex RO Always 1 Always 1 1 = PHY able to perform half-duplex 10BASE-T 10 100BASE-T2 Full-Duplex RO Always 0 Always 0 This protocol is not available. 0 = PHY not able to perform full-duplex Doc. No. MV-S107146-U0 Rev. E Page 74 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 66: Copper Status Register (Continued) Page 0, Register 1 B its Fi eld Mode HW Rst SW Rst Description 9 100BASE-T2 Half-Duplex RO Always 0 Always 0 This protocol is not available. 0 = PHY not able to perform half-duplex 8 Extended Status RO Always 1 Always 1 1 = Extended status information in Register 15 7 Reserved RO Always 0 Always 0 Must always be 0. 6 MF Preamble Suppression RO Always 1 Always 1 1 = PHY accepts management frames with preamble suppressed 5 Copper Auto-Negotiation Complete RO 0x0 0x0 1 = Auto-Negotiation process complete 0 = Auto-Negotiation process not complete 4 Copper Remote Fault RO,LH 0x0 0x0 1 = Remote fault condition detected 0 = Remote fault condition not detected 3 Auto-Negotiation Ability RO Always 1 Always 1 1 = PHY able to perform Auto-Negotiation 2 Copper Link Status RO,LL 0x0 0x0 This register bit indicates that link was down since the last read. For the current link status, either read this register back-to-back or read Register 17_0.10 Link Real Time. 1 = Link is up 0 = Link is down 1 Jabber Detect RO,LH 0x0 0x0 1 = Jabber condition detected 0 = Jabber condition not detected 0 Extended Capability RO Always 1 Always 1 1 = Extended register capabilities Table 67: PHY Identifier 1 Page 0, Register 2 B its Fi eld Mode 15:0 Organizationally RO Unique Identifier Bit 3:18 HW Rst SW Rst Description 0x0141 0x0141 Marvell® OUI is 0x005043 0000 0000 0101 0000 0100 0011 ^ ^ bit 1....................................bit 24 Register 2.[15:0] show bits 3 to 18 of the OUI. 0000000101000001 ^ ^ bit 3...................bit18 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 75 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 68: PHY Identifier 2 Page 0, Register 3 B its Fi eld Mode HW Rst SW Rst Description 15:10 OUI Lsb RO Always 000011 Always 000011 Organizationally Unique Identifier bits 19:24 00 0011 ^.........^ bit 19...bit24 9:4 Model Number RO Always 011101 Always 011101 Model Number 011101 3:0 Revision Number RO See Descr See Descr Rev Number. Contact Marvell® FAEs for information on the device revision number. Table 69: Copper Auto-Negotiation Advertisement Register Page 0, Register 4 B its Fi eld Mode HW Rst SW Rst Description 15 Next Page R/W 0x0 14 Ack RO Always 0 Always 0 Must be 0. 13 Remote Fault R/W 0x0 Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. 1 = Set Remote Fault bit 0 = Do not set Remote Fault bit 12 Reserved R/W 0x0 Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation Copper link goes down Reserved bit is R/W to allow for forward compatibility with future IEEE standards. Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. If 1000BASE-T is advertised then the required next pages are automatically transmitted. Register 4.15 should be set to 0 if no additional next pages are needed. 1 = Advertise 0 = Not advertised Doc. No. MV-S107146-U0 Rev. E Page 76 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 69: Copper Auto-Negotiation Advertisement Register (Continued) Page 0, Register 4 B its Fi eld Mode HW Rst SW Rst Description 11 Asymmetric Pause R/W 0x0 Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0.15) Restart Auto-Negotiation is asserted (Register 0.9) Power down (Register 0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. 1 = Asymmetric Pause 0 = No asymmetric Pause 10 Pause R/W 0x0 Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0.15) Restart Auto-Negotiation is asserted (Register 0.9) Power down (Register 0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. 1 = MAC PAUSE implemented 0 = MAC PAUSE not implemented 9 100BASE-T4 R/W 0x0 Retain 0 = Not capable of 100BASE-T4 8 100BASE-TX Full-Duplex R/W 0x1 Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0.15) Restart Auto-Negotiation is asserted (Register 0.9) Power down (Register 0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. If register 0.12 is set to 0 and speed is manually forced to 1000 Mbps in Registers 0.13 and 0.6, then Auto-Negotiation will still be enabled and only 1000BASE-T full-duplex is advertised if register 0.8 is set to 1, and 1000BASE-T half-duplex is advertised if 0.8 set to 0. Registers 4.8:5 and 9.9:8 are ignored. Auto-Negotiation is mandatory per IEEE for proper operation in 1000BASE-T. 1 = Advertise 0 = Not advertised Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 77 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 69: Copper Auto-Negotiation Advertisement Register (Continued) Page 0, Register 4 B its Fi eld Mode HW Rst SW Rst Description 7 100BASE-TX Half-Duplex R/W 0x1 Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0.15) Restart Auto-Negotiation is asserted (Register 0.9) Power down (Register 0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. If register 0.12 is set to 0 and speed is manually forced to 1000 Mbps in Registers 0.13 and 0.6, then Auto-Negotiation will still be enabled and only 1000BASE-T full-duplex is advertised if register 0.8 is set to 1, and 1000BASE-T half-duplex is advertised if 0.8 set to 0. Registers 4.8:5 and 9.9:8 are ignored. Auto-Negotiation is mandatory per IEEE for proper operation in 1000BASE-T. 1 = Advertise 0 = Not advertised 6 10BASE-TX Full-Duplex R/W 0x1 Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0.15) Restart Auto-Negotiation is asserted (Register 0.9) Power down (Register 0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. If register 0.12 is set to 0 and speed is manually forced to 1000 Mbps in Registers 0.13 and 0.6, then Auto-Negotiation will still be enabled and only 1000BASE-T full-duplex is advertised if register 0.8 is set to 1, and 1000BASE-T half-duplex is advertised if 0.8 set to 0. Registers 4.8:5 and 9.9:8 are ignored. Auto-Negotiation is mandatory per IEEE for proper operation in 1000BASE-T. 1 = Advertise 0 = Not advertised 5 10BASE-TX Half-Duplex R/W 0x1 Update A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0.15) Restart Auto-Negotiation is asserted (Register 0.9) Power down (Register 0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. If register 0.12 is set to 0 and speed is manually forced to 1000 Mbps in Registers 0.13 and 0.6, then Auto-Negotiation will still be enabled and only 1000BASE-T full-duplex is advertised if register 0.8 is set to 1, and 1000BASE-T half-duplex is advertised if 0.8 set to 0. Registers 4.8:5 and 9.9:8 are ignored. Auto-Negotiation is mandatory per IEEE for proper operation in 1000BASE-T. 1 = Advertise 0 = Not advertised Doc. No. MV-S107146-U0 Rev. E Page 78 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 69: Copper Auto-Negotiation Advertisement Register (Continued) Page 0, Register 4 B its Fi eld Mode HW Rst SW Rst Description 4:0 Selector Field R/W 0x01 Retain Selector Field mode 00001 = 802.3 Table 70: Copper Link Partner Ability Register - Base Page Page 0, Register 5 B its Fi eld Mode HW Rst SW Rst Description 15 Next Page RO 0x0 0x0 Received Code Word Bit 15 1 = Link partner capable of next page 0 = Link partner not capable of next page 14 Acknowledge RO 0x0 0x0 Acknowledge Received Code Word Bit 14 1 = Link partner received link code word 0 = Link partner does not have Next Page ability 13 Remote Fault RO 0x0 0x0 Remote Fault Received Code Word Bit 13 1 = Link partner detected remote fault 0 = Link partner has not detected remote fault 12 Technology Ability RO Field 0x0 0x0 Received Code Word Bit 12 11 Asymmetric Pause RO 0x0 0x0 Pause Capable RO 10 Received Code Word Bit 11 1 = Link partner requests asymmetric pause 0 = Link partner does not request asymmetric pause 0x0 0x0 Received Code Word Bit 10 1 = Link partner is capable of pause operation 0 = Link partner is not capable of pause operation 9 100BASE-T4 Capability RO 0x0 0x0 Received Code Word Bit 9 1 = Link partner is 100BASE-T4 capable 0 = Link partner is not 100BASE-T4 capable 8 100BASE-TX Full-Duplex Capability RO 0x0 0x0 Received Code Word Bit 8 1 = Link partner is 100BASE-TX full-duplex capable 0 = Link partner is not 100BASE-TX full-duplex capable 7 100BASE-TX Half-Duplex Capability RO 0x0 0x0 Received Code Word Bit 7 1 = Link partner is 100BASE-TX half-duplex capable 0 = Link partner is not 100BASE-TX half-duplex capable 6 10BASE-T Full-Duplex Capability RO 0x0 0x0 Received Code Word Bit 6 1 = Link partner is 10BASE-T full-duplex capable 0 = Link partner is not 10BASE-T full-duplex capable 5 10BASE-T Half-Duplex Capability RO 0x0 0x0 Received Code Word Bit 5 1 = Link partner is 10BASE-T half-duplex capable 0 = Link partner is not 10BASE-T half-duplex capable Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 79 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 70: Copper Link Partner Ability Register - Base Page (Continued) Page 0, Register 5 B its Fi eld Mode HW Rst SW Rst Description 4:0 Selector Field RO 0x00 0x00 Selector Field Received Code Word Bit 4:0 Table 71: Copper Auto-Negotiation Expansion Register Page 0, Register 6 B its Fi eld Mode HW Rst SW Rst Description 15:5 Reserved RO 0x000 0x000 Reserved. Must be 00000000000. 4 Parallel Detection RO,LH Fault 0x0 0x0 Register 6_0.4 is not valid until the Auto-Negotiation complete bit (Reg 1_0.5) indicates completed. 1 = A fault has been detected via the Parallel Detection function 0 = A fault has not been detected via the Parallel Detection function 3 Link Partner Next page Able RO 0x0 0x0 Register 6_0.3 is not valid until the Auto-Negotiation complete bit (Reg 1_0.5) indicates completed. 1 = Link Partner is Next Page able 0 = Link Partner is not Next Page able 2 Local Next Page Able RO 0x1 0x1 Register 6_0.2 is not valid until the Auto-Negotiation complete bit (Reg 1_0.5) indicates completed. 1 = Local Device is Next Page able 0 = Local Device is not Next Page able 1 Page Received RO, LH 0x0 0x0 Register 6_0.1 is not valid until the Auto-Negotiation complete bit (Reg 1_0.5) indicates completed. 1 = A New Page has been received 0 = A New Page has not been received 0 Link Partner Auto-Negotiation Able RO 0x0 0x0 Register 6_0.0 is not valid until the Auto-Negotiation complete bit (Reg 1_0.5) indicates completed. 1 = Link Partner is Auto-Negotiation able 0 = Link Partner is not Auto-Negotiation able Table 72: Copper Next Page Transmit Register Page 0, Register 7 B its Fi eld Mode HW Rst SW Rst Description 15 Next Page R/W 0x0 0x0 A write to register 7_0 implicitly sets a variable in the Auto-Negotiation state machine indicating that the next page has been loaded. Link fail will clear Reg 7_0. Transmit Code Word Bit 15 14 Reserved RO 0x0 0x0 Transmit Code Word Bit 14 Doc. No. MV-S107146-U0 Rev. E Page 80 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 72: Copper Next Page Transmit Register (Continued) Page 0, Register 7 B its Fi eld Mode HW Rst SW Rst Description 13 Message Page Mode R/W 0x1 0x1 Transmit Code Word Bit 13 12 Acknowledge2 R/W 0x0 0x0 Transmit Code Word Bit 12 11 Toggle RO 0x0 0x0 Transmit Code Word Bit 11 10:0 Message/ R/W Unformatted Field 0x001 0x001 Transmit Code Word Bit 10:0 Table 73: Copper Link Partner Next Page Register Page 0, Register 8 B its Fi eld Mode HW Rst SW Rst Description 15 Next Page RO 0x0 0x0 Received Code Word Bit 15 14 Acknowledge RO 0x0 0x0 Received Code Word Bit 14 13 Message Page RO 0x0 0x0 Received Code Word Bit 13 12 Acknowledge2 RO 0x0 0x0 Received Code Word Bit 12 11 Toggle RO 0x0 0x0 Received Code Word Bit 11 10:0 Message/ RO Unformatted Field 0x000 0x000 Received Code Word Bit 10:0 Table 74: 1000BASE-T Control Register Page 0, Register 9 B its Fi eld Mode HW Rst SW Rst Description 15:13 Test Mode R/W 0x0 Retain TX_CLK comes from the RX_CLK pin for jitter testing in test modes 2 and 3. After exiting the test mode, hardware reset or software reset (Register 0_0.15) should be issued to ensure normal operation. A restart of Auto-Negotiation will clear these bits. 000 = Normal Mode 001 = Test Mode 1 - Transmit Waveform Test 010 = Test Mode 2 - Transmit Jitter Test (MASTER mode) 011 = Test Mode 3 - Transmit Jitter Test (SLAVE mode) 100 = Test Mode 4 - Transmit Distortion Test 101, 110, 111 = Reserved 12 MASTER/SLAVE R/W Manual Configuration Enable 0x0 Update A write to this register bit does not take effect until any of the following also occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. 1 = Manual MASTER/SLAVE configuration 0 = Automatic MASTER/SLAVE configuration Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 81 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 74: 1000BASE-T Control Register (Continued) Page 0, Register 9 B its Fi eld Mode HW Rst SW Rst Description 11 MASTER/SLAVE R/W Configuration Value 0x0 Update A write to this register bit does not take effect until any of the following also occurs: Software reset is asserted (Register 0.15) Restart Auto-Negotiation is asserted (Register 0.9) Power down (Register 0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. 1 = Manual configure as MASTER 0 = Manual configure as SLAVE 10 Port Type R/W 0x0 Update A write to this register bit does not take effect until any of the following also occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. Register 9_0.10 is ignored if Register 9_0.12 is equal to 1. 1 = Prefer multi-port device (MASTER) 0 = Prefer single port device (SLAVE) 9 1000BASE-T Full-Duplex R/W 0x1 Update A write to this register bit does not take effect until any of the following also occurs: Software reset is asserted (Register 0_0.15) Restart Auto-Negotiation is asserted (Register 0_0.9) Power down (Register 0_0.11, 16_0.2) transitions from power down to normal operation Link goes down 1 = Advertise 0 = Not advertised 8 1000BASE-T Half-Duplex R/W 0x1 Update A write to this register bit does not take effect until any of the following also occurs: Software reset is asserted (Register 0.15) Restart Auto-Negotiation is asserted (Register 0.9) Power down (Register 0.11, 16_0.2) transitions from power down to normal operation Copper link goes down. 1 = Advertise 0 = Not advertised 7:0 Reserved R/W 0x00 Retain 0 Table 75: 1000BASE-T Status Register Page 0, Register 10 B its Fi eld Mode 15 MASTER/SLAVE RO,LH Configuration Fault HW Rst SW Rst Description 0x0 0x0 This register bit will clear on read. 1 = MASTER/SLAVE configuration fault detected 0 = No MASTER/SLAVE configuration fault detected Doc. No. MV-S107146-U0 Rev. E Page 82 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 75: 1000BASE-T Status Register (Continued) Page 0, Register 10 B its Fi eld Mode HW Rst SW Rst Description 14 MASTER/SLAVE RO Configuration Resolution 0x0 0x0 1 = Local PHY configuration resolved to MASTER 0 = Local PHY configuration resolved to SLAVE 13 Local Receiver Status RO 0x0 0x0 1 = Local Receiver OK 0 = Local Receiver is Not OK 12 Remote Receiver RO Status 0x0 0x0 1 = Remote Receiver OK 0 = Remote Receiver Not OK 11 Link Partner 1000BASE-T Full-Duplex Capability RO 0x0 0x0 1 = Link Partner is capable of 1000BASE-T full-duplex 0 = Link Partner is not capable of 1000BASE-T full-duplex 10 Link Partner 1000BASE-T Half-Duplex Capability RO 0x0 0x0 1 = Link Partner is capable of 1000BASE-T half-duplex 0 = Link Partner is not capable of 1000BASE-T half-duplex 9:8 Reserved RO 0x0 0x0 Reserved 7:0 Idle Error Count RO, SC 0x00 0x00 MSB of Idle Error Counter These register bits report the idle error count since the last time this register was read. The counter pegs at 11111111 and will not roll over. Table 76: Extended Status Register Page 0, Register 15 B its Fi eld Mode HW Rst SW Rst Description 15 1000BASE-X Full-Duplex RO Always 0 Always 0 0 = Not 1000BASE-X full-duplex capable 14 1000BASE-X Half-Duplex RO Always 0 Always 0 0 = Not 1000BASE-X half-duplex capable 13 1000BASE-T Full-Duplex RO Always 1 Always 1 1 = 1000BASE-T full-duplex capable 12 1000BASE-T Half-Duplex RO Always 1 Always 1 1 = 1000BASE-T half-duplex capable 11:0 Reserved RO 0x000 0x000 000000000000 Table 77: Copper Specific Control Register 1 Page 0, Register 16 B its Fi eld Mode HW Rst SW Rst Description 15 Disable Link Pulses R/W 0x0 0x0 1 = Disable Link Pulse 0 = Enable Link Pulse 14:12 Reserved R/W 0x3 Update Reserved Do not write any value other than the HW Rst value. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 83 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 77: Copper Specific Control Register 1 (Continued) Page 0, Register 16 B its Fi eld Mode HW Rst SW Rst Description 11 Reserved R/W 0x0 Update Reserved Do not write any value other than the HW Rst value. 10 Force Copper Link Good R/W 0x0 Retain If link is forced to be good, the link state machine is bypassed and the link is always up. In 1000BASE-T mode this has no effect. 1 = Force link good 0 = Normal operation 9:8 Energy Detect R/W 0x0 Update 0x = Off 10 = Sense only on Receive (Energy Detect) 11 = Sense and periodically transmit NLP (Energy Detect+TM) 7 Reserved 6:5 MDI Crossover Mode R/W 0x3 Update Changes to these bits are disruptive to the normal operation; therefore, any changes to these registers must be followed by a software reset to take effect. 00 = Manual MDI configuration 01 = Manual MDIX configuration 10 = Reserved 11 = Enable automatic crossover for all modes 4 Reserved R/W 0x0 Retain Set to 0 3 Copper Transmitter Disable R/W 0x0 Retain 1 = Transmitter Disable 0 = Transmitter Enable 2 Power Down R/W 0x0 Retain Power down is controlled via register 0_0.11 and 16_0.2. Both bits must be set to 0 before the PHY will transition from power down to normal operation. When the port is switched from power down to normal operation, software reset and restart Auto-Negotiation are performed even when bits Reset (0_0.15) and Restart Auto-Negotiation (0_0.9) are not set by the user. 1 = Power down 0 = Normal operation 1 Polarity Reversal R/W Disable 0x0 Retain If polarity is disabled, then the polarity is forced to be normal in 10BASE-T. 1 = Polarity Reversal Disabled 0 = Polarity Reversal Enabled The detected polarity status is shown in Register 17_0.1, or in 1000BASE-T mode, 21_5.3:0. 0 Disable Jabber 0x0 Retain Jabber has effect only in 10BASE-T half-duplex mode. 1 = Disable jabber function 0 = Enable jabber function Reserved. R/W Doc. No. MV-S107146-U0 Rev. E Page 84 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 78: Copper Specific Status Register 1 Page 0, Register 17 B its Fi eld Mode HW Rst SW Rst Description 15:14 Speed RO 0x2 Retain These status bits are valid only after resolved bit 17_0.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. 11 = Reserved 10 = 1000 Mbps 01 = 100 Mbps 00 = 10 Mbps 13 Duplex RO 0x0 Retain This status bit is valid only after resolved bit 17_0.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. 1 = Full-duplex 0 = Half-duplex 12 Page Received RO, LH 0x0 0x0 1 = Page received 0 = Page not received 11 Speed and RO Duplex Resolved 0x0 0x0 When Auto-Negotiation is not enabled 17_0.11 = 1. 1 = Resolved 0 = Not resolved 10 Copper Link (real RO time) 0x0 0x0 1 = Link up 0 = Link down 9 Transmit Pause Enabled RO 0x0 0x0 This is a reflection of the MAC pause resolution. This bit is for information purposes and is not used by the device. This status bit is valid only after resolved bit 17_0.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. 1 = Transmit pause enabled 0 = Transmit pause disable 8 Receive Pause Enabled RO 0x0 0x0 This is a reflection of the MAC pause resolution. This bit is for information purposes and is not used by the device. This status bit is valid only after resolved bit 17_0.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. 1 = Receive pause enabled 0 = Receive pause disabled 7 Reserved RO 0x0 0x0 0 6 MDI Crossover Status RO 0x1 Retain This status bit is valid only after resolved bit 17_0.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. This bit is 0 or 1 depending on what is written to 16.6:5 in manual configuration mode. Register 16.6:5 are updated with software reset. 1 = MDIX 0 = MDI 5 Reserved RO 0x0 0x0 Reserved 4 Copper Energy Detect Status RO 0x0 0x0 1 = Sleep 0 = Active 3 Global Link Status RO 0x0 0x0 1 = Copper link is up 0 = Copper link is down Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 85 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 78: Copper Specific Status Register 1 (Continued) Page 0, Register 17 B its Fi eld Mode HW Rst SW Rst Description 2 Reserved RO 0x0 0x0 Reserved 1 Polarity (real time) RO 0x0 0x0 1 = Reversed 0 = Normal Polarity reversal can be disabled by writing to Register 16_0.1. In 1000BASE-T mode, polarity of all pairs are shown in Register 21_5.3:0. 0 Jabber (real time) RO 0x0 0x0 1 = Jabber 0 = No jabber Table 79: Copper Specific Interrupt Enable Register Page 0, Register 18 B its Fi eld Mode HW Rst SW Rst Description 15 Auto-Negotiation Error Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 14 Speed Changed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 13 Duplex Changed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 12 Page Received Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 11 Auto-Negotiation Completed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 10 Link Status Changed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 9 Symbol Error Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 8 False Carrier Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 7 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 6 MDI Crossover Changed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 5 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 4 Copper Energy Detect Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable Doc. No. MV-S107146-U0 Rev. E Page 86 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 79: Copper Specific Interrupt Enable Register (Continued) Page 0, Register 18 B its Fi eld Mode HW Rst SW Rst Description 3 FLP Exchange Complete but no Link Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 2 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 1 Polarity Changed R/W Interrupt Enable 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 0 Jabber Interrupt Enable 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable R/W Table 80: Copper Interrupt Status Register Page 0, Register 19 B its Fi eld Mode HW Rst SW Rst Description 15 Copper AutoRO,LH Negotiation Error 0x0 0x0 An error is said to occur if MASTER/SLAVE does not resolve, parallel detect fault, no common HCD, or link does not come up after negotiation is completed. 1 = Auto-Negotiation Error 0 = No Auto-Negotiation Error 14 Copper Speed Changed RO,LH 0x0 0x0 1 = Speed changed 0 = Speed not changed 13 Copper Duplex Changed RO,LH 0x0 0x0 1 = Duplex changed 0 = Duplex not changed 12 Copper Page Received RO,LH 0x0 0x0 1 = Page received 0 = Page not received 11 Copper AutoNegotiation Completed RO,LH 0x0 0x0 1 = Auto-Negotiation completed 0 = Auto-Negotiation not completed 10 Copper Link Status Changed RO,LH 0x0 0x0 1 = Link status changed 0 = Link status not changed 9 Copper Symbol Error RO,LH 0x0 0x0 1 = Symbol error 0 = No symbol error 8 Copper False Carrier RO,LH 0x0 0x0 1 = False carrier 0 = No false carrier 7 Reserved RO, LH 0x0 0x0 Reserved 6 MDI Crossover Changed RO,LH 0x0 0x0 1 = Crossover changed 0 = Crossover not changed 5 Reserved RO,LH 0x0 0x0 Reserved 4 Copper Energy Detect Changed RO,LH 0x0 0x0 1 = Energy Detect state changed 0 = No Energy Detect state change detected Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 87 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 80: Copper Interrupt Status Register (Continued) Page 0, Register 19 B its Fi eld Mode HW Rst SW Rst Description 3 FLP Exchange Complete but no Link RO,LH 0x0 0x0 1 = FLP Exchange Completed but Link Not Established 0 = No Event Detected 2 Reserved RO,LH 0x0 0x0 Reserved 1 Polarity Changed RO,LH 0x0 0x0 1 = Polarity Changed 0 = Polarity not changed 0 Jabber 0x0 0x0 1 = Jabber 0 = No jabber RO,LH Table 81: Copper Specific Control Register 2 Page 0, Register 20 B its Fi eld Mode HW Rst SW Rst Description 15:8 Reserved R/W 0x000 Retain Write all 0s. 7 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 6 Break Link On Insufficient IPG R/W 0x0 Retain 0 = Break link on insufficient IPGs in 10BASE-T and 100BASE-TX 1 = Do not break link on insufficient IPGs in 10BASE-T and 100BASE-TX 5 Reserved R/W 0x1 Update Reserved Do not write any value other than the HW Rst value. 4 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 3 Reverse MDIP/N[3] Transmit Polarity R/W 0x0 Retain 0 = Normal Transmit Polarity 1 = Reverse Transmit Polarity 2 Reverse MDIP/N[2] Transmit Polarity R/W 0x0 Retain 0 = Normal Transmit Polarity 1 = Reverse Transmit Polarity 1 Reverse MDIP/N[1] Transmit Polarity R/W 0x0 Retain 0 = Normal Transmit Polarity 1 = Reverse Transmit Polarity 0 Reverse MDIP/N[0] Transmit Polarity R/W 0x0 Retain 0 = Normal Transmit Polarity 1 = Reverse Transmit Polarity Table 82: Copper Specific Receive Error Counter Register Page 0, Register 21 B its Fi eld Mode HW Rst SW Rst Description 15:0 Receive Error Count RO, LH 0x0000 Retain Counter will peg at 0xFFFF and will not roll over. Both False carrier and symbol errors are reported. Doc. No. MV-S107146-U0 Rev. E Page 88 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 83: Page Address Page Any, Register 22 B its Fi eld Mode HW Rst SW Rst Description 15:8 Reserved RO 0x00 0x00 All 0's 7:0 Page select for registers 0 to 28 R/W 0x00 Retain Page Number Table 84: Global Interrupt Status Page 0, Register 23 B its Fi eld Mode HW Rst SW Rst Description 15:1 Reserved RO 0x0000 0x0000 Reserved. 0 Interrupt RO 0x0 0x0 1 = Interrupt active on port X 0 = No interrupt active on port X Table 85: Fiber Control Register Page 1, Register 0 B its Fi eld Mode HW Rst SW Rst Description 15 Fiber Reset R/W 0x0 SC Fiber Software Reset. Affects page 1. Writing a 1 to this bit causes the PHY state machines to be reset. When the reset operation is done, this bit is cleared to 0 automatically. The reset occurs immediately. 1 = PHY reset 0 = Normal operation 14 Loopback R/W 0x0 0x0 When loopback is activated, the transmitter data presented on TXD of the internal bus is looped back to RXD of the internal bus. Link is broken when loopback is enabled. Loopback speed is determined by the mode the device is in. 1000BASE-X - loopback is always in 1000Mbps. 100BASE-FX - loopback is always in 100Mbps. 1 = Enable Loopback 0 = Disable Loopback 13 Speed Select (LSB) RO, R/W 0x0 Retain If register 16_1.1:0 (MODE[1:0]) = 00 then this bit is always 1. If register 16_1.1:0 (MODE[1:0]) = 01 then this bit is always 0. If register 16_1.1:0 (MODE[1:0]) = 10 then this bit is 1 when the PHY is at 100Mb/s, else it is 0. If register 16_1.1:0 (MODE[1:0]) = 11 then this bit is R/W. bit 6,13 10 = 1000 Mbps 01 = 100 Mbps 00 = 10 Mbps Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 89 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 85: Fiber Control Register (Continued) Page 1, Register 0 B its Fi eld Mode HW Rst SW Rst Description 12 Auto-Negotiation Enable R/W See Descr Retain If the value of this bit is changed, the link will be broken and Auto-Negotiation Restarted This bit has no effect when in 100BASE-FX mode When this bit gets set/reset, Auto-negotiation is restarted (bit 0_1.9 is set to 1). On hardware reset this bit takes on the value of S_ANEG 1 = Enable Auto-Negotiation Process 0 = Disable Auto-Negotiation Process 11 Power Down R/W 0x0 0x0 When the port is switched from power down to normal operation, software reset and restart Auto-Negotiation are performed even when bits Reset (0_1.15) and Restart Auto-Negotiation (0_1.9) are not set by the user. On hardware reset, bit 0_1.11 1 = Power down 0 = Normal operation 10 Isolate RO 0x0 0x0 This function is not supported 9 Restart Fiber Auto-Negotiation R/W, SC 0x0 SC Auto-Negotiation automatically restarts after hardware, software reset (0_1.15) or change in Auto-Negotiation enable (0_1.12) regardless of whether or not the restart bit (0_1.9) is set. The bit is set when Auto-negotiation is Enabled or Disabled in 0_1.12 1 = Restart Auto-Negotiation Process 0 = Normal operation 8 Duplex Mode R/W 0x1 Retain Writing this bit has no effect unless one of the following events occur: Software reset is asserted (Register 0_1.15) Restart Auto-Negotiation is asserted (Register 0_1.9) Auto-Negotiation Enable changes (Register 0_1.12) Power down (Register 0_1.11) transitions from power down to normal operation 1 = Full-duplex 0 = Half-Duplex 7 Collision Test RO 0x0 0x0 This bit has no effect. 6 Speed Selection (MSB) RO, R/W 0x1 Retain If register 16_1.1:0 (MODE[1:0]) = 00 then this bit is always 0. If register 16_1.1:0 (MODE[1:0]) = 01 then this bit is always 1. If register 16_1.1:0 (MODE[1:0]) = 10 then this bit is 1 when the PHY is at 1000Mb/s, else it is 0. If register 16_1.1:0 (MODE[1:0]) = 11 then this bit is R/W. bit 6,13 10 = 1000 Mbps 01 = 100 Mbps 00 = 10 Mbps 5:0 Reserved RO Always 000000 Always 0. Always 000000 Doc. No. MV-S107146-U0 Rev. E Page 90 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 86: Fiber Status Register Page 1, Register 1 B its Fi eld Mode HW Rst SW Rst Description 15 100BASE-T4 RO Always 0 Always 0 100BASE-T4. This protocol is not available. 0 = PHY not able to perform 100BASE-T4 14 100BASE-X Full-Duplex RO See Descr See Descr If register 16_1.1:0 (MODE[1:0]) = 00 then this bit is 1, else this bit is 0. bit 6,13 1 = PHY able to perform full duplex 100BASE-X 0 = PHY not able to perform full duplex 100BASE-X 13 100BASE-X Half-Duplex RO See Descr See Descr If register 16_1.1:0 (MODE[1:0]) = 00 then this bit is 1, else this bit is 0. bit 6,13 1 = PHY able to perform half-duplex 100BASE-X 0 = PHY not able to perform half-duplex 100BASE-X 12 10 Mb/s Full Duplex RO Always 0 Always 0 0 = PHY not able to perform full-duplex 10BASE-T 11 10 Mbps Half-Duplex RO Always 0 Always 0 0 = PHY not able to perform half-duplex 10BASE-T 10 100BASE-T2 Full-Duplex RO Always 0 Always 0 This protocol is not available. 0 = PHY not able to perform full-duplex 9 100BASE-T2 Half-Duplex RO Always 0 Always 0 This protocol is not available. 0 = PHY not able to perform half-duplex 8 Extended Status RO Always 1 Always 1 1 = Extended status information in Register 15 7 Reserved RO Always 0 Always 0 Must always be 0. 6 MF Preamble Suppression RO Always 1 Always 1 1 = PHY accepts management frames with preamble suppressed 5 Fiber AutoNegotiation Complete RO 0x0 0x0 1 = Auto-Negotiation process complete 0 = Auto-Negotiation process not complete Bit is not set when link is up due of Fiber Auto-negotiation Bypass or if Auto-negotiation is disabled. 4 Fiber Remote Fault RO,LH 0x0 0x0 1 = Remote fault condition detected 0 = Remote fault condition not detected This bit is always 0 in SGMII modes. 3 AutoRO Negotiation Ability See Descr See Descr If register 16_1.1:0 (MODE[1:0]) = 00 then this bit is 0, else this bit is 1. bit 6,13 1 = PHY able to perform Auto-Negotiation 0 = PHY not able to perform Auto-Negotiation 2 Fiber Link Status RO,LL 0x0 0x0 This register bit indicates when link was lost since the last read. For the current link status, either read this register back-to-back or read Register 17_1.10 Link Real Time. 1 = Link is up 0 = Link is down 1 Reserved Always 0 Always 0 Must be 0 RO,LH Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 91 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 86: Fiber Status Register (Continued) Page 1, Register 1 B its Fi eld Mode HW Rst SW Rst Description 0 Extended Capability RO Always 1 Always 1 1 = Extended register capabilities Table 87: PHY Identifier Page 1, Register 2 B its Fi eld Mode 15:0 Organizationally RO Unique Identifier Bit 3:18 HW Rst SW Rst Description 0x0141 0x0141 Marvell® OUI is 0x005043 0000 0000 0101 0000 0100 0011 ^ ^ bit 1....................................bit 24 Register 2.[15:0] show bits 3 to 18 of the OUI. 0000000101000001 ^ ^ bit 3...................bit18 Table 88: PHY Identifier Page 1, Register 3 B its Fi eld Mode HW Rst SW Rst Description 15:10 OUI Lsb RO Always 000011 Always 000011 Organizationally Unique Identifier bits 19:24 000011 ^.........^ bit 19...bit24 9:4 Model Number RO Always 011101 Always 011101 Model Number 011101 3:0 Revision Number RO Always 0000 0x0 Rev Number = 0000 Table 89: Fiber Auto-Negotiation Advertisement Register - 1000BASE-X Mode (Register 16_1.1:0 = 01) Page 1, Register 4 B its Fi eld Mode HW Rst SW Rst Description 15 Next Page R/W 0x0 Retain A write to this register bit does not take effect until any one of the following occurs: Software reset is asserted (Register 0_1.15) Restart Auto-Negotiation is asserted (Register 0_1.9) Power down (Register 0_1.11) transitions from power down to normal operation Link goes down 1 = Advertise 0 = Not advertised Doc. No. MV-S107146-U0 Rev. E Page 92 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 89: Fiber Auto-Negotiation Advertisement Register - 1000BASE-X Mode (Register 16_1.1:0 = 01) (Continued) Page 1, Register 4 B its Fi eld Mode HW Rst SW Rst Description 14 Reserved RO Always 0 Always 0 Reserved 13:12 Remote Fault 2/ RemoteFault 1 R/W 0x0 Retain A write to this register bit does not take effect until any one of the following also occurs: Software reset is asserted (Register 0_1.15) Re-start Auto-Negotiation is asserted (Register 0_1.9) Power down (Register 0_1.11) transitions from power down to normal operation Link goes down Device has no ability to detect remote fault. 00 = No error, link OK (default) 01 = Link Failure 10 = Offline 11 = Auto-Negotiation Error 11:9 Reserved RO Always 000 Always 000 Reserved 8:7 Pause R/W See Descr. Retain A write to this register bit does not take effect until any one of the following also occurs: Software reset is asserted (Register 0_1.15) Re-start Auto-Negotiation is asserted (Register 0_1.9) Power down (Register 0_1.11) transitions from power down to normal operation Link goes down Upon hardware reset both bits takes on the value of ENA_ PAUSE. 00 = No PAUSE 01 = Symmetric PAUSE 10 = Asymmetric PAUSE toward link partner 11 = Both Symmetric PAUSE and Asymmetric PAUSE toward local device. 6 1000BASE-X Half-Duplex R/W See Descr. Retain A write to this register bit does not take effect until any one of the following also occurs: Software reset is asserted (Register 0_1.15) Re-start Auto-Negotiation is asserted (Register 0_1.9) Power down (Register 0_1.11) transitions from power down to normal operation Link goes down Upon hardware reset this bit takes on the value of C_ANEG[0]. 1 = Advertise 0 = Not advertised 5 1000BASE-X Full-Duplex R/W 0x1 Retain A write to this register bit does not take effect until any one of the following also occurs: Software reset is asserted (Register 0_1.15) Re-start Auto-Negotiation is asserted (Register 0_1.9) Power down (Register 0_1.11) transitions from power down to normal operation Link goes down 1 = Advertise 0 = Not advertised Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 93 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 89: Fiber Auto-Negotiation Advertisement Register - 1000BASE-X Mode (Register 16_1.1:0 = 01) (Continued) Page 1, Register 4 B its Fi eld Mode HW Rst SW Rst Description 4:0 Reserved R/W 0x00 0x00 Reserved Table 90: Fiber Auto-Negotiation Advertisement Register - SGMII (System mode) (Register 16_ 1.1:0 = 10) Page 1, Register 4 B its Fi eld Mode HW Rst SW Rst Description 15 Link Status RO 0x0 14 Reserved RO Always 0 Always 0 Reserved 13 Reserved RO Always 0 Always 0 Reserved 12 Duplex Status RO 0x0 0x0 0 = Interface Resolved to Half-duplex 1 = Interface Resolved to Full-duplex 11:10 Speed[1:0] RO 0x0 0x0 00 = Interface speed is 10 Mbps 01 = Interface speed is 100 Mbps 10 = Interface speed is 1000 Mbps 11 = Reserved 9 Transmit Pause RO 0x0 0x0 Note that if register 16_1.7 is set to 0 then this bit is always forced to 0. 0 = Disabled, 1 = Enabled 8 Receive Pause RO 0x0 0x0 Note that if register 16_1.7 is set to 0 then this bit is always forced to 0. 0 = Disabled, 1 = Enabled 7 Fiber/Copper RO 0x0 0x0 Note that if register 16_1.7 is set to 0 then this bit is always forced to 0. 0 = Copper media, 1 = Fiber media 6:0 Reserved RO Always Always Reserved 0000001 0000001 0x0 0 = Link is Not up on the Copper Interface 1 = Link is up on the Copper Interface Table 91: Fiber Auto-Negotiation Advertisement Register - SGMII (Media mode) (Register 16_1.1:0 = 11) Page 1, Register 4 B its Fi eld Mode HW Rst SW Rst Description 15:0 Reserved RO Always 0x0001 Always 0x0001 Reserved Doc. No. MV-S107146-U0 Rev. E Page 94 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 92: Fiber Link Partner Ability Register - 1000BASE-X Mode (Register 16_1.1:0 = 01) Page 1, Register 5 B its Fi eld Mode HW Rst SW Rst Description 15 Next Page RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bit 15 1 = Link partner capable of next page 0 = Link partner not capable of next page 14 Acknowledge RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Acknowledge Received Code Word Bit 14 1 = Link partner received link code word 0 = Link partner has not received link code word 13:12 Remote Fault 2/ Remote Fault 1 RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bit 13:12 00 = No error, link OK (default) 01 = Link Failure 10 = Offline 11 = Auto-Negotiation Error 11:9 Reserved RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bit 11:9 8:7 Asymmetric Pause RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bit 8:7 00 = No PAUSE 01 = Symmetric PAUSE 10 = Asymmetric PAUSE toward link partner 11 = Both Symmetric PAUSE and Asymmetric PAUSE toward local device. 6 1000BASE-X Half-Duplex RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word bit 6 1 = Link partner capable of 1000BASE-X half-duplex. 0 = Link partner not capable of 1000BASE-X half-duplex. 5 1000BASE-X Full-Duplex RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word bit 5 1 = Link partner capable of 1000BASE-X full-duplex. 0 = Link partner not capable of 1000BASE-X full-duplex. 4:0 Reserved RO 0x00 0x00 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bits 4:0 Must be 0 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 95 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 93: Fiber Link Partner Ability Register - SGMII (System mode) (Register 16_1.1:0 = 10) Page 1, Register 5 B its Fi eld Mode HW Rst SW Rst Description 15 Reserved RO 0x0 0x0 Must be 0 14 Acknowledge RO 0x0 0x0 Acknowledge Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bit 14 1 = Link partner received link code word 0 = Link partner has not received link code word 13:0 Reserved RO 0x0000 0x0000 Received Code Word Bits 13:0 Must receive 00_0000_0000_0001 per SGMII spec Table 94: Fiber Link Partner Ability Register - SGMII (Media mode) (Register 16_1.1:0 = 11) Page 1, Register 5 B its Fi eld Mode HW Rst SW Rst Description 15 Link RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bit 15 1 = Copper Link is up on the link partner 0 = Copper Link is not up on the link partner 14 Acknowledge RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Acknowledge Received Code Word Bit 14 1 = Link partner received link code word 0 = Link partner has not received link code word 13 Reserved RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bit 13 Must be 0 12 Duplex Status RO 0x0 0x0 Register bit is cleared when link goes down and loaded when a base page is received Received Code Word Bit 12 1 = Copper Interface on the link Partner is capable of Full Duplex 0 = Copper Interface on the link partner is capable of Half Duplex 11:10 Speed Status RO 0x0 0x0 Register bits are cleared when link goes down and loaded when a base page is received Received Code Word Bit 11:10 00 = 10 Mbps 01 = 100 Mbps 10 = 1000 Mbps 11 = reserved 9 Reserved RO 0x0 0x0 Reserved 8 Reserved RO 0x0 0x0 Reserved Doc. No. MV-S107146-U0 Rev. E Page 96 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 94: Fiber Link Partner Ability Register - SGMII (Media mode) (Register 16_1.1:0 = 11) (Continued) B its Fi eld Mode HW Rst SW Rst Description 7 Reserved RO 0x0 0x0 Reserved 6:0 Reserved RO 0x00 0x00 Register bits are cleared when link goes down and loaded when a base page is received Received Code Word Bits 6:0 Must be 0000001 Table 95: Fiber Auto-Negotiation Expansion Register Page 1, Register 6 B its Fi eld Mode HW Rst SW Rst Description 15:4 Reserved RO 0x000 0x000 Reserved. Must be 00000000000. 3 Link Partner Next page Able RO 0x0 0x0 SGMII and 100BASE-FX modes this bit is always 0. In 1000BASE-X mode register 6_1.3 is set when a base page is received and the received link control word has bit 15 set to 1. The bit is cleared when link goes down. 1 = Link Partner is Next Page able 0 = Link Partner is not Next Page able 2 Local Next Page Able RO Always 1 Always 1 1 = Local Device is Next Page able 1 Page Received RO, LH 0x0 0x0 Register 6_1.1 is set when a valid page is received. 1 = A New Page has been received 0 = A New Page has not been received 0 Link Partner Auto-Negotiation Able RO 0x0 0x0 This bit is set when there is sync status, the fiber receiver has received 3 non-zero matching valid configuration code groups and Auto-negotiation is enabled in register 0_1.12 1 = Link Partner is Auto-Negotiation able 0 = Link Partner is not Auto-Negotiation able Table 96: Fiber Next Page Transmit Register Page 1, Register 7 B its Fi eld Mode HW Rst SW Rst Description 15 Next Page R/W 0x0 0x0 A write to register 7_1 implicitly sets a variable in the Auto-Negotiation state machine indicating that the next page has been loaded. Register 7_1 only has effect in the 1000BASE-X mode. Transmit Code Word Bit 15 14 Reserved RO 0x0 0x0 Transmit Code Word Bit 14 13 Message Page Mode R/W 0x1 0x1 Transmit Code Word Bit 13 12 Acknowledge2 R/W 0x0 0x0 Transmit Code Word Bit 12 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 97 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 96: Fiber Next Page Transmit Register (Continued) Page 1, Register 7 B its Fi eld Mode HW Rst SW Rst Description 11 Toggle RO 0x0 0x0 Transmit Code Word Bit 11. This bit is internally set to the opposite value each time a page is received 10:0 Message/ R/W Unformatted Field 0x001 0x001 Transmit Code Word Bit 10:0 Table 97: Fiber Link Partner Next Page Register Page 1, Register 8 B its Fi eld Mode HW Rst SW Rst Description 15 Next Page RO 0x0 0x0 Register 8_1 only has effect in the 1000BASE-X mode. The register is loaded only when a next page is received from the link partner. It is cleared each time the link goes down. Received Code Word Bit 15 14 Acknowledge RO 0x0 0x0 Received Code Word Bit 14 13 Message Page RO 0x0 0x0 Received Code Word Bit 13 12 Acknowledge2 RO 0x0 0x0 Received Code Word Bit 12 11 Toggle RO 0x0 0x0 Received Code Word Bit 11 10:0 Message/ RO Unformatted Field 0x000 0x000 Received Code Word Bit 10:0 Table 98: Extended Status Register Page 1, Register 15 B its Fi eld Mode HW Rst SW Rst Description 15 1000BASE-X Full-Duplex RO See Descr See Descr If register 16_1.1:0 (MODE[1:0]) = 00 then this bit is 0, else this bit is 1. 1 = 1000BASE-X full duplex capable 0 = not 1000BASE-X full duplex capable 14 1000BASE-X Half-Duplex RO See Descr See Descr If register 16_1.1:0 (MODE[1:0]) = 00 then this bit is 0, else this bit is 1. 1 = 1000BASE-X half duplex capable 0 = not 1000BASE-X half duplex capable 13 1000BASE-T Full-Duplex RO 0x0 0x0 0 = not 1000BASE-T full duplex capable 12 1000BASE-T Half-Duplex RO 0x0 0x0 0 = not 1000BASE-T half duplex capable 11:0 Reserved RO 0x000 0x000 000000000000 Doc. No. MV-S107146-U0 Rev. E Page 98 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 99: Fiber Specific Control Register 1 Page 1, Register 16 B its Fi eld Mode HW Rst SW Rst Description 15:14 Reserved R/W 0x1 Retain Reserved Do not write any value other than the HW Rst value. 13 Block Carrier Extension Bit R/W 0x0 Retain Carrier extension and carrier extension with error are converted to idle symbols on the RXD only during full duplex mode. 1 = Enable Block Carrier Extension 0 = Disable Block Carrier Extension 12 Reserved R/W 0x0 0x0 Reserved Do not write any value other than the HW Rst value. 11 Assert CRS on Transmit R/W 0x0 Retain This bit has no effect in full-duplex. 1 = Assert on transmit 0 = Never assert on transmit 10 Force Link Good R/W 0x0 Retain If link is forced to be good, the link state machine is bypassed and the link is always up. 1 = Force link good 0 = Normal operation 9 Reserved R/W 0x0 Retain Set to 0. 8 SERDES Loopback Type R/W 0x0 Retain 0 = Loopback Through PCS (Tx and Rx can be asynchronous) 1 = Loopback raw 10 bit data (Tx and Rx must be synchronous) 7:6 Reserved R/W 0x0 Update Reserved Do not write any value other than the HW Rst value. 5 Marvell Remote Fault Indication Enable R/W 0x0 Retain 0 = Disable 1 = Enable, Remote Fault is indicated to link partner in less than 2 ms, only one bit of bit 5:4 can be set to 1 4 IEEE Remote Fault Indication Enable R/W 0x0 Retain 0 = Disable 1 = Enable, Remote Fault is indicated to link partner after 20ms according to IEEE standard, only one bit of bit 5:4 can be set to 1 3 Reserved R/W 0x1 Update 2 Interrupt Polarity R/W 0x1 Retain 1 = INTn active low 0 = INTn active high 1:0 MODE[1:0] RO See Desc. See Desc. These bits reflects the mode as programmed in register of 20_ 6.2:0 00 = 100BASE-FX 01 = 1000BASE-X 10 = SGMII System mode 11 = SGMII Media mode Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 99 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 100: Fiber Specific Status Register Page 1, Register 17 B its Fi eld Mode HW Rst SW Rst Description 15:14 Speed RO 0x0 Retain These status bits are valid only after resolved bit 17_1.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. In 100BASE-FX mode this bit is always 01. 11 = Reserved 10 = 1000 Mbps 01 = 100 Mbps 00 = 10 Mbps 13 Duplex RO 0x0 Retain This status bit is valid only after resolved bit 17_1.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. In 100BASE-FX mode this bit follows register 0_1.8. 1 = Full-duplex 0 = Half-duplex 12 Page Received RO, LH 0x0 0x0 In 100BASE-FX mode this bit is always 0. 1 = Page received 0 = Page not received 11 Speed and RO Duplex Resolved 0x0 0x0 When Auto-Negotiation is not enabled or in 100BASE-FX mode this bit is always 1. 1 = Resolved 0 = Not resolved If bit 26_1.5 is 1, then this bit will be 0. 10 Link (real time) RO 0x0 0x0 1 = Link up 0 = Link down 9:8 Reserved RO Always 00 Always 00 7:6 Remote Fault Received RO, LH 0x0 0x0 The mapping for this status is as follows: 00 = No Fault 01 = Link Failure detected at link partner 10 = Offline 11 = Auto-neg Error 5 Sync status RO 0x0 0x0 1 = Sync 0 = No Sync 4 Fiber Energy Detect Status RO 0x1 0x1 1 = No energy detected 0 = Energy Detected 3 Transmit Pause Enabled RO 0x0 0x0 This is a reflection of the MAC pause resolution. This bit is for information purposes and is not used by the device. This status bit is valid only after resolved bit 17_1.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. In 100BASE-FX mode this bit is always 0. 1 = Transmit pause enabled 0 = Transmit pause disable Doc. No. MV-S107146-U0 Rev. E Page 100 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 100: Fiber Specific Status Register (Continued) Page 1, Register 17 B its Fi eld Mode HW Rst SW Rst Description 2 Receive Pause Enabled RO 0x0 0x0 This is a reflection of the MAC pause resolution. This bit is for information purposes and is not used by the device. This status bit is valid only after resolved bit 17_1.11 = 1. The resolved bit is set when Auto-Negotiation is completed or Auto-Negotiation is disabled. In 100BASE-FX mode this bit is always 0. 1 = Receive pause enabled 0 = Receive pause disabled 1:0 Reserved RO Always 00 Always 00 00 Table 101: Fiber Interrupt Enable Register Page 1, Register 18 B its Fi eld Mode HW Rst SW Rst Description 15 Reserved RO Always 0 Always 0 0 14 Speed Changed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 13 Duplex Changed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 12 Page Received Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 11 Auto-Negotiation Completed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 10 Link Status Changed Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 9 Symbol Error Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 8 False Carrier Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 7 Fiber FIFO Over/Underflow Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 6 Reserved RO Always 0 Always 0 0 5 Remote Fault Receive Interrupt Enable R/W 0x0 0x0 1 = Interrupt enable 0 = Interrupt disable 4 Fiber Energy Detect Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 101 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 101: Fiber Interrupt Enable Register (Continued) Page 1, Register 18 B its Fi eld Mode HW Rst SW Rst Description 3:0 Reserved RO Always 0000 Always 0000 0000 Table 102: Fiber Interrupt Status Register Page 1, Register 19 B its Fi eld Mode HW Rst SW Rst Description 15 Reserved RO Always 0 Always 0 0 14 Speed Changed RO,LH 0x0 0x0 1 = Speed changed 0 = Speed not changed 13 Duplex Changed RO,LH 0x0 0x0 1 = Duplex changed 0 = Duplex not changed 12 Page Received RO,LH 0x0 0x0 1 = Page received 0 = Page not received 11 Auto-Negotiation Completed RO,LH 0x0 0x0 1 = Auto-Negotiation completed 0 = Auto-Negotiation not completed 10 Link Status Changed RO,LH 0x0 0x0 1 = Link status changed 0 = Link status not changed 9 Symbol Error RO,LH 0x0 0x0 1 = Symbol error 0 = No symbol error 8 False Carrier RO,LH 0x0 0x0 1 = False carrier 0 = No false carrier 7 Fiber FIFO Over/Underflow RO,LH 0x0 0x0 1 = Over/Underflow Error 0 = No FIFO Error 6 Reserved RO 0x0 0x0 0 5 Remote Fault Receive Interrupt Enable RO, LH 0x0 0x0 1 = Remote Fault received changed, read 1.17.7:6 for detail 0 = No change on remote fault received 4 Fiber Energy Detect Changed RO,LH 0x0 0x0 1 = Energy Detect state changed 0 = No Energy Detect state change detected 3:0 Reserved RO Always 00000 Always 00000 00000 Table 103: PRBS Control Page 1, Register 23 B its Fi eld Mode HW Rst SW Rst Description 15:8 Reserved R/W 0x00 Retain Set to 0s 7 Invert Checker Polarity R/W 0x0 Retain 0 = Normal 1 = Invert Doc. No. MV-S107146-U0 Rev. E Page 102 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 103: PRBS Control (Continued) Page 1, Register 23 B its Fi eld Mode HW Rst SW Rst Description 6 Invert Generator Polarity R/W 0x0 Retain 0 = Normal 1 = Invert 5 PRBS Lock R/W 0x0 Retain 0 = Counter Free Runs 1 = Do not start counting until PRBS locks first 4 Clear Counter R/W, SC 0x0 0x0 0 = Normal 1 = Clear Counter 3:2 Pattern Select R/W 0x0 Retain 00 = PRBS 7 01 = PRBS 23 10 = PRBS 31 11 = Generate 1010101010... pattern 1 PRBS Checker Enable R/W 0x0 0x0 0 = Disable 1 = Enable 0 PRBS Generator R/W Enable 0x0 0x0 0 = Disable 1 = Enable Table 104: PRBS Error Counter LSB Page 1, Register 24 B its Fi eld Mode HW Rst SW Rst Description 15:0 PRBS Error Count LSB RO 0x0000 Retain A read to this register freezes register 25_1. Cleared only when register 23_1.4 is set to 1. Table 105: PRBS Error Counter MSB Page 1, Register 25 B its Fi eld Mode HW Rst SW Rst Description 15:0 PRBS Error Count MSB RO 0x0000 Retain This register does not update unless register 24_1 is read first. Cleared only when register 23_1.4 is set to 1. Table 106: Fiber Specific Control Register 2 Page 1, Register 26 B its Fi eld Mode HW Rst SW Rst Description 15 Force INT R/W 0x0 Retain 1 = Force INTn to assert 0 = Normal Operation 14 1000BASE-X Noise Filtering R/W 0x0 Retain 1 = Enable 0 = Disable 13:10 Reserved R/W 0x0 Retain Must set to 0 9 FEFI Enable R/W 0x0 Retain 100BASE-FX FEFI 1 = Enable 0 = Disable 8:7 Reserved R/W 0x0 Retain Must set to 0 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 103 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 106: Fiber Specific Control Register 2 (Continued) Page 1, Register 26 B its Fi eld Mode HW Rst SW Rst Description 6 Serial Interface AutoNegotiation bypass enable R/W 0x1 Update Changes to this bit are disruptive to the normal operation; hence, any changes to these registers must be followed by software reset to take effect. 1 = Bypass Allowed 0 = No Bypass Allowed 5 Serial Interface AutoNegotiation bypass status RO 0x0 0x0 1 = Serial interface link came up because bypass mode timer timed out and fiber Auto-Negotiation was bypassed. 0 = Serial interface link came up because regular fiber Auto-Negotiation completed. If this bit is 1, then bit 17_1.11 will be 0. 4 Reserved R/W 0x0 Update Must set to 0 3 Fiber Transmitter R/W Disable 0x0 Retain 1 = Transmitter Disable 0 = Transmitter Enable 2:0 SGMII R/W Output Amplitude 0x2 Retain Differential voltage peak measured. See AC/DC section for valid VOD values. 000 = 14mV 001 = 112mV 010 = 210 mV 011 = 308mV 100 = 406mV 101 = 504mV 110 = 602mV 111 = 700mV Table 107: MAC Specific Control Register 1 Page 2, Register 16 B its Fi eld Mode HW Rst SW Rst Description 15:14 Reserved R/W 0x1 Retain Reserved Do not write any value other than the HW Rst value. 13 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 12 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 11 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 10 Reserved R/W 0x1 Retain Reserved Do not write any value other than the HW Rst value. 9:7 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 6 Pass Odd Nibble R/W Preambles 0x1 Update 0 = Pad odd nibble preambles in copper receive packets. 1 = Pass as is and do not pad odd nibble preambles in copper receive packets. Doc. No. MV-S107146-U0 Rev. E Page 104 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 107: MAC Specific Control Register 1 (Continued) Page 2, Register 16 B its Fi eld Mode HW Rst SW Rst Description 5 Reserved R/W 0x0 Retain 4 Reserved R/W 0x0 Retain 3 RGMII Interface Power Down R/W 0x1 Update Changes to this bit are disruptive to the normal operation; therefore, any changes to these registers must be followed by a software reset to take effect. This bit determines whether the RGMII RX_CLK powers down when Register 0.11, 16_0.2 are used to power down the device or when the PHY enters the energy detect state. 1 = Always power up 0 = Can power down 2 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 1 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 0 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. Table 108: MAC Specific Interrupt Enable Register Page 2, Register 18 B its Fi eld Mode HW Rst SW Rst Description 15:8 Reserved R/W 0x00 Retain 000000000 7 Copper FIFO Over/Underflow Interrupt Enable R/W 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 6:4 Reserved R/W 0x0 Retain 000 3 Copper FIFO Idle R/W Inserted Interrupt Enable 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 2 Copper FIFO Idle R/W Deleted Interrupt Enable 0x0 Retain 1 = Interrupt enable 0 = Interrupt disable 1:0 Reserved 0x0 Retain 00 R/W Table 109: MAC Specific Status Register Page 2, Register 19 B its Fi eld Mode HW Rst SW Rst Description 15:8 Reserved RO Always 00 Always 00 00000000 7 Copper FIFO Over/Underflow RO,LH 0x0 0x0 1 = Over/Underflow Error 0 = No FIFO Error Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 105 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 109: MAC Specific Status Register (Continued) Page 2, Register 19 B its Fi eld Mode HW Rst SW Rst Description 6:4 Reserved RO Always 0 Always 0 000 3 Copper FIFO Idle RO,LH Inserted 0x0 0x0 1 = Idle Inserted 0 = No Idle Inserted 2 Copper FIFO Idle RO,LH Deleted 0x0 0x0 1 = Idle Deleted 0 = Idle not Deleted 1:0 Reserved Always 0 Always 0 00 RO Table 110: MAC Specific Control Register 2 Page 2, Register 21 B its Fi eld Mode HW Rst SW Rst Description 15 Reserved R/W 0x0 0x0 0 14 Copper Line Loopback R/W 0x0 0x0 1 = Enable Loopback of MDI to MDI 0 = Normal Operation 13 Default MAC interface speed (LSB) R/W 0x0 Update Changes to these bits are disruptive to the normal operation; therefore, any changes to these registers must be followed by software reset to take effect. Also, used for setting speed of MAC interface during MAC side loopback. Requires that customer set both these bits and force speed using register 0 to the same speed. MAC Interface Speed during Link down. Bits 6,13 00 = 10 Mbps 01 = 100 Mbps 10 = 1000 Mbps 12:7 Reserved 0x20 0x20 Reserved. 6 Default MAC interface speed (MSB) R/W 0x1 Update Changes to these bits are disruptive to the normal operation; therefore, any changes to these registers must be followed by software reset to take effect. Also, used for setting speed of MAC interface during MAC side loopback. Requires that customer set both these bits and force speed using register 0 to the same speed. MAC Interface Speed during Link down. Bits 6, 13 00 = 10 Mbps 01 = 100 Mbps 10 = 1000 Mbps 5 RGMII Receive Timing Control R/W 0x1 Update Changes to these bits are disruptive to the normal operation; therefore, any changes to these registers must be followed by software reset to take effect. 1 = Receive clock transition when data stable 0 = Receive clock transition when data transitions Doc. No. MV-S107146-U0 Rev. E Page 106 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 110: MAC Specific Control Register 2 (Continued) Page 2, Register 21 B its Fi eld Mode HW Rst SW Rst Description 4 RGMII Transmit Timing Control R/W 0x1 Update Changes to these bits are disruptive to the normal operation; therefore, any changes to these registers must be followed by software reset to take effect. 1 = Transmit clock internally delayed 0 = Transmit clock not internally delayed 3 Block Carrier Extension Bit R/W 0x0 Retain 1 = Enable Block Carrier Extension 0 = Disable Block Carrier Extension 2:0 Reserved R/W 0x6 0x6 Reserved. Table 111: RGMII Output Impedance Calibration Override Page 2, Register 24 B its Fi eld Mode HW Rst SW Rst Description 15 Reserved R/W, SC 0x0 Retain Reserved Do not write any value other than the HW Rst value. 14 Reserved RO 0x0 Retain Reserved 13 VDDO Level R/W See Descr. Retain VDDO level- must be programmed to indicate the VDDO supply voltage used The bit mapping is: 0 = 3.3V/1.8V 1 = 2.5V/1.8V If the CONFIG pin input values bit 1:0 are: 00, then VDDO Level = 3.3V/1.8V 11, then VDDO Level = 3.3V/1.8V 10, then VDDO Level = 2.5V/1.8V 01, then VDDO Level = 2.5V/1.8V Note: 3.3V/1.8V is assumed initially until this value is changed. 12 1.8V VDDO Used R/O See Descr Retain This bit indicates whether VDDO = 1.8V is used or not. 1 = VDDO = 1.8V 0 = VDDO = 2.5V or 3.3V 11:8 Reserved R/W See Descr Retain Reserved Do not write any value other than the HW Rst value. In this case, a read must be done first to get the HW Rst value and then it should be used in a subsequent write. 7 Reserved RW 0x0 Retain Reserved Do not write any value other than the HW Rst value. 6 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 5:4 Reserved R/O 0x0 Retain Reserved Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 107 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 111: RGMII Output Impedance Calibration Override (Continued) Page 2, Register 24 B its Fi eld Mode HW Rst SW Rst Description 3:0 Reserved R/W See Descr Retain Reserved Do not write any value other than the HW Rst value. In this case, a read must be done first to get the HW Rst value and then it should be used in a subsequent write. Table 112: LED[2:0] Function Control Register Page 3, Register 16 B its Fi eld Mode HW Rst SW Rst Description 15:12 Reserved R/W 0x1 Retain 11:8 LED[2] Control R/W 0x0 Retain 0000 = On - Link, Off - No Link 0001 = On - Link, Blink - Activity, Off - No Link 0010 = On- Full Duplex, Blink- Collision, Off- Half Duplex 0011 = On - Activity, Off - No Activity 0100 = Blink - Activity, Off - No Activity 0101 = On - Transmit, Off - No Transmit 0110 = On - 10/1000 Mbps Link, Off - Else 0111 = On - 10 Mbps Link, Off - Else 1000 = Force Off 1001 = Force On 1010 = Force Hi-Z 1011 = Force Blink 11xx = Reserved 7:4 LED[1] Control R/W 0x1 Retain If 16_3.3:2 is set to 11 then 16_3.7:4 has no effect 0000 = On- Receive, Off- No Receive 0001 = On - Link, Blink - Activity, Off - No Link 0010 = On - Link, Blink - Receive, Off - No Link 0011 = On - Activity, Off - No Activity 0100 = Blink - Activity, Off - No Activity 0101 = On- 100 Mbps Link/ Fiber Link 0110 = On - 100/1000 Mbps Link, Off - Else 0111 = On - 100 Mbps Link, Off - Else 1000 = Force Off 1001 = Force On 1010 = Force Hi-Z 1011 = Force Blink 11xx = Reserved Doc. No. MV-S107146-U0 Rev. E Page 108 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 112: LED[2:0] Function Control Register (Continued) Page 3, Register 16 B its Fi eld Mode HW Rst SW Rst Description 3:0 LED[0] Control R/W 0xE Retain 0000 = On - Link, Off - No Link 0001 = On - Link, Blink - Activity, Off - No Link 0010 = 3 blinks - 1000 Mbps 2 blinks - 100 Mbps 1 blink - 10 Mbps 0 blink - No Link 0011 = On - Activity, Off - No Activity 0100 = Blink - Activity, Off - No Activity 0101 = On - Transmit, Off - No Transmit 0110 = On - Copper Link, Off - Else 0111 = On - 1000 Mbps Link, Off - Else 1000 = Force Off 1001 = Force On 1010 = Force Hi-Z 1011 = Force Blink 1100 = MODE 1 (Dual LED mode) 1101 = MODE 2 (Dual LED mode) 1110 = MODE 3 (Dual LED mode) 1111 = MODE 4 (Dual LED mode) Table 113: LED[2:0] Polarity Control Register Page 3, Register 17 B its Fi eld Mode HW Rst SW Rst Description 15:12 LED[1] mix percentage R/W 0x4 Retain When using 2 terminal bi-color LEDs the mixing percentage should not be set greater than 50%. 0000 = 0% 0001 = 12.5% ... 0111 = 87.5% 1000 = 100% 1001 to 1111 = Reserved 11:8 LED[0] mix percentage R/W 0x4 Retain When using 2 terminal bi-color LEDs the mixing percentage should not be set greater than 50%. 0000 = 0% 0001 = 12.5% ..., 0111 = 87.5%, 1000 = 100% 1001 to 1111 = Reserved 7:6 Reserved R/W 0x0 Retain Reserved. 5:4 LED[2] Polarity R/W 0x0 Retain 00 = On - drive LED[2] low, Off - drive LED[2] high 01 = On - drive LED[2] high, Off - drive LED[2] low 10 = On - drive LED[2] low, Off - tristate LED[2] 11 = On - drive LED[2] high, Off - tristate LED[2] 3:2 LED[1] Polarity R/W 0x0 Retain 00 = On - drive LED[1] low, Off - drive LED[1] high 01 = On - drive LED[1] high, Off - drive LED[1] low 10 = On - drive LED[1] low, Off - tristate LED[1] 11 = On - drive LED[1] high, Off - tristate LED[1] Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 109 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 113: LED[2:0] Polarity Control Register (Continued) Page 3, Register 17 B its Fi eld Mode HW Rst SW Rst Description 1:0 LED[0] Polarity R/W 0x0 Retain 00 = On - drive LED[0] low, Off - drive LED[0] high 01 = On - drive LED[0] high, Off - drive LED[0] low 10 = On - drive LED[0] low, Off - tristate LED[0] 11 = On - drive LED[0] high, Off - tristate LED[0] Table 114: LED Timer Control Register Page 3, Register 18 B its Fi eld Mode HW Rst SW Rst Description 15 Force INT R/W 0x0 Retain 1 = Force INTn to assert 0 = Normal Operation 14:12 Pulse stretch duration R/W 0x4 Retain 000 = No pulse stretching 001 = 21 ms to 42ms 010 = 42 ms to 84ms 011 = 84 ms to 170ms 100 = 170 ms to 340ms 101 = 340 ms to 670ms 110 = 670 ms to 1.3s 111 = 1.3s to 2.7s 11 Interrupt Polarity R/W 0x1 Retain 0 = INTn active high 1 = INTn active low 10:8 Blink Rate R/W 0x1 Retain 000 = 42 ms 001 = 84 ms 010 = 170 ms 011 = 340 ms 100 = 670 ms 101 to 111 = Reserved 7 Interrupt Enable R/W 0x0 Retain Allows the INTn output to be brought out on LED[2]. 1 = INTn is brought out LED[2] 0 = LED[2] outputs based on current LED[2] functionality 6:4 Reserved R/W 0x0 Retain 000 3:2 Speed Off Pulse Period R/W 0x1 Retain 00 = 84 ms 01 = 170 ms 10 = 340 ms 11 = 670 ms 1:0 Speed On Pulse Period R/W 0x1 Retain 00 = 84ms 01 = 170ms 10 = 340ms 11 = 670ms Doc. No. MV-S107146-U0 Rev. E Page 110 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 115: 1000BASE-T Pair Skew Register Page 5, Register 20 B its Fi eld Mode HW Rst SW Rst Description 15:12 Pair 7,8 (MDI[3]±) RO 0x0 Retain Skew = Bit value x 8n s. Value is correct to within ± 8 ns. The contents of 20_5.15:0 are valid only if Register 21_5.6 = 1 11:8 Pair 4,5 (MDI[2]±) RO 0x0 Retain Skew = bit value x 8 ns. Value is correct to within ± 8 ns. 7:4 Pair 3,6 (MDI[1]±) RO 0x0 Retain Skew = bit value x 8ns. Value is correct to within ± 8 ns. 3:0 Pair 1,2 (MDI[0]±) RO 0x0 Retain Skew = bit value x 8 ns. Value is correct to within ± 8ns. Table 116: 1000BASE-T Pair Swap and Polarity Page 5, Register 21 B its Fi eld Mode HW Rst SW Rst Description 15:7 Reserved RO 0x000 Retain 6 Register 20_5 and 21_5 valid RO 0x0 Retain The contents of 21_5.5:0 and 20_5.15:0 are valid only if Register 21_5.6 = 1 1= Valid 0 = Invalid 5 C, D Crossover RO 0x0 Retain 1 = Channel C received on MDI[2]± Channel D received on MDI[3]± 0 = Channel D received on MDI[2]± Channel C received on MDI[3]± 4 A, B Crossover RO 0x0 Retain 1 = Channel A received on MDI[0]± Channel B received on MDI[1]± 0 = Channel B received on MDI[0]± Channel A received on MDI[1]± 3 Pair 7,8 (MDI[3]±) RO Polarity 0x0 Retain 1 = Negative 0 = Positive 2 Pair 4,5 (MDI[2]±) Polarity 0x0 Retain 1 = Negative 0 = Positive 1 Pair 3,6 (MDI[1]±) RO Polarity 0x0 Retain 1 = Negative 0 = Positive 0 Pair 1,2 (MDI[0]±) RO Polarity 0x0 Retain 1 = Negative 0 = Positive Table 117: Copper Port Packet Generation Page 6, Register 16 B its Fi eld Mode HW Rst SW Rst Description 15:8 Packet Burst R/W 0x00 Retain 0x00 = Continuous 0x01 to 0xFF = Burst 1 to 255 packets Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 111 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 117: Copper Port Packet Generation (Continued) Page 6, Register 16 B its Fi eld Mode HW Rst SW Rst Description 7 Packet Generator Transmit Trigger R/W 0x0 Retain This bit is only valid when all of the following are true: bit 6 =1 bit3 =1 bit15:8 is not equal to all 0s A read of this bit gives the following: 1: Packet generator transmit done 0: Packet generator is transmitting data When this bit is 1 a write of 0 will trigger the packet generator to transmit again. When this bit is 0 a write of 0 or 1 will have no effect. 6 Packet Generator R/W Enable Self Clear Control 0x0 Retain 0 = Bit 3 will self clear after all packets are sent 1 = Bit 3 will stay high after all packets are sent 5 Reserved R/W 0x0 Retain Reserved 4 Enable CRC Checker R/W 0x0 Retain 1 = Enable 0 = Disable 3 Enable Packet Generator R/W 0x0 Retain 1 = Enable 0 = Disable 2 Payload of Packet to Transmit R/W 0x0 Retain 0 = Pseudo-random 1 = 5A,A5,5A,A5,... 1 Length of Packet R/W to Transmit 0x0 Retain 1 = 1518 bytes 0 = 64 bytes 0 Transmit an Errored Packet 0x0 Retain 1 = Tx packets with CRC errors & Symbol Error 0 = No error R/W Table 118: Copper Port CRC Counters Page 6, Register 17 B its Fi eld Mode HW Rst SW Rst Description 15:8 Packet Count RO 0x00 Retain 0x00 = No packets received 0xFF = 256 packets received (max count). Bit 16_6.4 must be set to 1 in order for register to be valid. 7:0 CRC Error Count RO 0x00 Retain 0x00 = No CRC errors detected in the packets received. 0xFF = 256 CRC errors detected in the packets received (max count). Bit 16_6.4 must be set to 1 in order for register to be valid. Table 119: Checker Control Page 6, Register 18 B its Fi eld Mode HW Rst SW Rst Description 15:5 Reserved R/W 0x000 Retain Set to 0s Doc. No. MV-S107146-U0 Rev. E Page 112 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 119: Checker Control (Continued) Page 6, Register 18 B its Fi eld Mode HW Rst SW Rst Description 4 CRC Counter Reset R/W, SC 0x0 Retain 1 = Reset This bit will self-clear after writing 1. 3 Enable Stub Test R 0x0 Retain 1 = Enable stub test 0 = Normal Operation 2:0 Reserved 0x0 Retain Reserved. R/W Table 120: Copper Port Packet Generation Page 6, Register 19 B its Fi eld Mode HW Rst SW Rst Description 15:8 Reserved R/W 0x00 Retain Reserved. 7:0 IPG Length R/W 8'd12 Retain The number in bit [7:0]+1 is the number of bytes for IPG Table 121: Late Collision Counters 1 & 2 Page 6, Register 23 B its Fi eld Mode HW Rst SW Rst Description 15:8 Late Collision 97-128 bytes RO, SC 0x00 Retain This counter increments by 1 when the PHY is in half duplex and a start of packet is received while the 97th to 128th bytes of the packet are transmitted. The measurement is done at the internal GMII interface. The counter will not roll over and will clear on read. 7:0 Late Collision 65-96 bytes RO, SC 0x00 Retain This counter increments by 1 when the PHY is in half duplex and a start of packet is received while the 65th to 96th bytes of the packet are transmitted. The measurement is done at the internal GMII interface. The counter will not roll over and will clear on read. Table 122: Late Collision Counters 3 & 4 Page 6, Register 24 B its Fi eld Mode HW Rst SW Rst Description 15:8 Late Collision >192 bytes RO, SC 0x00 Retain This counter increments by 1 when the PHY is in half duplex and a start of packet is received after 192 bytes of the packet are transmitted. The measurement is done at the internal GMII interface. The counter will not roll over and will clear on read. 7:0 Late Collision 129-192 bytes RO, SC 0x00 Retain This counter increments by 1 when the PHY is in half duplex and a start of packet is received while the 129th to 192nd bytes of the packet are transmitted. The measurement is done at the internal GMII interface. The counter will not roll over and will clear on read. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 113 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 123: Late Collision Window Adjust/Link Disconnect Page 6, Register 25 B its Fi eld Mode HW Rst SW Rst Description 15:13 Reserved R/W 0x0 Retain Set to 0s 12:8 Late Collision Window Adjust R/W 0x00 Retain Number of bytes to advance in late collision window. 0 = start at 64th byte, 1 = start at 63rd byte, etc. 7:0 Reserved R/W 0x00 Retain Set to 0s Table 124: Misc Test Page 6, Register 26 B its Fi eld Mode HW Rst SW Rst Description 15 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 14:13 Temperature Sensor Acceleration R/W 0x0 Retain 00 = Sample once per second 01 = Sample once per 10ms 1x = Disable Polling 12:8 Temperature Threshold R/W 0x19 Retain Temperature in C = 5 x 26_6.4:0 - 25 i.e. for 100C the value is 11001 7 Temperature Sensor Interrupt Enable R/W 0x0 Retain 1 = Interrupt Enable 0 = Interrupt Disable 6 Temperature Sensor Interrupt RO, LH 0x0 Retain 1 = Temperature Reached Threshold 0 = Temperature Below Threshold 5 Temperature Manual Control R/W 0x0 Retain Manual Control of temp_sense_en 1 = Temperature Acquire 0 = Temperature Read Set register 250_8.5:4 = 10 to use 4:0 Temperature Sensor RO xxxxx xxxxx Temperature is the 5MSBs of temperature value - Temp_ val[5:1] Table 125: Misc Test: Temperature Sensor Alternative Reading Page 6, Register 27 B its Fi eld Mode HW Rst SW Rst Description 15:13 Reserved R/W 0x0 Retain Reserved. 12:11 R/W Temp Sensor: Number to average samples 2'b01 Retain 00: average over 2^9 samples 01: average over 2^11 samples 10: average over 2^13 samples 11: average over 2^15 samples Doc. No. MV-S107146-U0 Rev. E Page 114 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 125: Misc Test: Temperature Sensor Alternative Reading (Continued) Page 6, Register 27 B its Fi eld Mode HW Rst SW Rst Description 10:8 Temp Sensor: sampling rate R/W 3'b100 Retain Sampling rate 000: 28 us 001: 56 us 010: 168 us 011: 280 us 100: 816 us 101: 2.28 ms 110: 6.22 ms 111: 11.79 ms 7:0 Temperature Sensor Alternative reading RO xxxxx Retain Temperature in C = 1 x 27_6.7:0 - 25 i.e. for 100C the value is 0111_1101 Table 126: Packet Generation Page 18, Register 16 B its Fi eld Mode HW Rst SW Rst Description 15:8 Packet Burst R/W 0x00 Retain 0x00 = Continuous 0x01 to 0xFF = Burst 1 to 255 packets 7:5 Enable Packet Generator R/W, SC 0x0 Retain 000 = Normal Operation 010 = Generate Packets on Copper Interface 100 = Generate Packets on SGMII Interface 101 = Reserved 110 = Generate Packets on RGMII Interface 111 = Reserved else = Reserved 4 Packet Generator R/W Transmit Trigger 0x0 Retain This bit is only valid when all of the following are true: bit 7:5 are not equal to 000 bit3 =1 bit15:8 is not equal to all 0s A read of this bit gives the following: 1: Packet generator transmit done 0: Packet generator is transmitting data When this bit is 1 a write of 0 will trigger the packet generator to transmit again. When this bit is 0 a write of 0 or 1 will have no effect. 3 R/W Packet Generator Enable Self Clear Control 0x0 Retain 0 = Bit 7:5 will self clear after all packets are sent 1 = Bit 7:5 will stay at the current value after all packets are sent 2 Payload of packet R/W to transmit 0x0 Retain 0 = Pseudo-random 1 = 5A,A5,5A,A5,... 1 Length of packet to transmit 0x0 Retain 1 = 1518 bytes 0 = 64 bytes R/W Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 115 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 126: Packet Generation (Continued) Page 18, Register 16 B its Fi eld Mode HW Rst SW Rst Description 0 Transmit an Errored packet R/W 0x0 Retain 1 = Tx packets with CRC errors & Symbol Error 0 = No error Table 127: CRC Counters Page 18, Register 17 B its Fi eld Mode HW Rst SW Rst Description 15:8 Packet Count RO 0x00 Retain 0x00 = No packets received 0xFF = 256 packets received (max count). Bit 18_18.2:0. must not be all 0 in order for these bits to be valid. 7:0 CRC Error Count RO 0x00 Retain 0x00 = No CRC errors detected in the packets received 0xFF = 256 CRC errors detected in the packets received (max count) Bit 18_18.2:0. must not be all 0 in order for these bits to be valid. Table 128: Checker Control Page 18, Register 18 B its Fi eld Mode HW Rst SW Rst Description 15:5 Reserved R/W 0x000 Retain Set to 0s 4 CRC Counter Reset R/W, SC 0x0 Retain 1 = Reset This bit will self-clear after writing 1. 3 Reserved R/W 0x0 Retain Reserved. 2:0 Enable CRC Checker R/W 0x0 Retain 000 = Disable/reset CRC checker 010 = Check data from Copper Interface 100 = Check data from SGMII Interface 101 = Reserved 110 = Check data from RGMII Interface 111 = Reserved else = Reserved Table 129: Packet Generation Page 18, Register 19 B its Fi eld Mode HW Rst SW Rst Description 15:8 Reserved R/W 0x00 Retain Reserved. 7:0 IPG Length R/W 0xC Retain The number in bit 7:0+1 is the number of bytes for IPG Doc. No. MV-S107146-U0 Rev. E Page 116 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 88E1510/88E1518/88E1512/88E1514 Register Description PHY MDIO Register Description Table 130: General Control Register 1 Page 18, Register 20 B its Fi eld Mode HW Rst SW Rst Description 15 Reset R/W, SC 0x0 SC Mode Software Reset. Affects page 6 and 18 Writing a 1 to this bit causes the main PHY state machines to be reset. When the reset operation is done, this bit is cleared to 0 automatically. The reset occurs immediately. 1 = PHY reset 0 = Normal operation 14:13 Reserved R/W 0x0 Retain Set to 0s. 12:10 Reserved R/W 0x0 Retain Reserved for future use. 9:7 Reserved R/W 0x4 Retain Set to 100 6 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 5:4 Reserved R/W 0x0 Retain Reserved Do not write any value other than the HW Rst value. 3 Reserved R/W 0x0 Update Set to 0 2:0 MODE[2:0] R/W See Descr. Update Changes to this bit are disruptive to the normal operation; therefore, any changes to these registers must be followed by a software reset to take effect. 000 = RGMII (System mode) to Copper 001 = SGMII (System mode) to Copper 010 = RGMII (System mode) to 1000BASE-X 011 = RGMII (System mode) to 100BASE-FX 100 = RGMII (System mode) to SGMII (Media mode) 101 = Reserved 110 = Reserved 111 = Reserved 20_18.2:0 defaults to 111 for 88E1512/88E1514. Therefore, 20_18.2:0 must be programmed with the desired mode of operation. 20_18.2:0 defaults to 000 for 88E1510/88E1518. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 117 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4 Electrical Specifications This section includes information on the following topics:  Section 4.1, Absolute Maximum Ratings  Section 4.2, Recommended Operating Conditions  Section 4.3, Package Thermal Information  Section 4.4, 88E1510/88E1518 Current Consumption  Section 4.5, 88E1512 Current Consumption  Section 4.6, 88E1514 Current Consumption  Section 4.7, DC Operating Conditions  Section 4.8, AC Electrical Specifications  Section 4.9, SGMII Timing  Section 4.10, RGMII Timing  Section 4.11, MDC/MDIO Timing  Section 4.12, IEEE AC Transceiver Parameters  Section 4.13, Latency Timing 4.1 Absolute Maximum Ratings Table 131: Absolute Maximum Ratings Stresses above those listed in Absolute Maximum Ratings may cause permanent device failure. Functionality at or above these limits is not implied. Exposure to absolute maximum ratings for extended periods may affect device reliability. Sy m b o l Parameter M in Ty p Max Units VDDA Power Supply Voltage on AVDD18 with respect to VSS -0.5 2.5 V VDDAC Power Supply Voltage on AVDDC18 with respect to VSS -0.5 2.5 V VDDAR Power Supply Voltage on AVDD33 with respect to VSS -0.5 3.6 V VDD Power Supply Voltage on DVDD with respect to VSS -0.5 1.5 V VDDO Power Supply Voltage on VDDO with respect to VSS -0.5 3.6 V VPIN Voltage applied to any digital input pin -0.5 3.6V or VDDO + 0.7 whichever is less V TSTORAGE Storage temperature -55 +1251 C 1. 125 C is only used as bake temperature for not more than 24 hours. Long term storage (e.g weeks or longer) should be kept at 85 C or lower. Doc. No. MV-S107146-U0 Rev. E Page 118 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications Recommended Operating Conditions 4.2 Recommended Operating Conditions Table 132: Recommended Operating Conditions Sy m b o l Parameter C on d it io n M in Ty p Max Units VDDA1 AVDD18 supply For AVDD18 1.71 1.8 1.890 V AVDDC18 supply For AVDDC18 1.71 1.8 1.890 V AVDD33 supply For AVDD33 3.14 3.3 3.46 V DVDD supply For DVDD 0.95 1.0 1.05 V VDDO supply For VDDO at 1.8V (88E1518/88E1512/88E1514) 1.71 1.8 1.890 V For VDDO at 2.5V 2.38 2.5 2.62 V For VDDO at 3.3V 3.14 3.3 3.46 V VDDAC 1 VDDAR1 VDD 1 VDDO 1  4990 ± 1% Tolerance RSET Internal bias reference Resistor connected to VSS TA Ambient operating temperature Commercial Grade 0 702 C Industrial Grade -40 +85 C 1253 C TJ Maximum junction temperature 1. Maximum noise allowed on supplies is 50 mV peak-peak. 2. Commercial operating temperatures are typically below 70 C, e.g, 45 C ~55 C. The 70C max is Marvell® specification limit 3. Refer to white paper on TJ Thermal Calculations for more information. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 119 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.3 Package Thermal Information 4.3.1 Thermal Conditions for 88E1510/88E1518 48-pin, QFN Package Table 133: Thermal Conditions for 88E1510/88E151848-pin, QFN Package S y m b ol Parameter C o n di ti on resistance1 JA Max Units 35.2 C/W 30.5 C/W JEDEC 3 in. x 4.5 in. 4-layer PCB with 2 meter/sec air flow 29.3 C/W JEDEC 3 in. x 4.5 in. 4-layer PCB with 3 meter/sec air flow 28.4 C/W Thermal characteristic parametera - JEDEC 3 in. x 4.5 in. 4-layer PCB junction to top center of the device with no air flow 48-Pin, QFN package JEDEC 3 in. x 4.5 in. 4-layer PCB with 1 meter/sec air flow  = (T -T )/P. 0.63 C/W 1.07 C/W P = Total power dissipation, Ttop: Temperature on the top center of the package. JEDEC 3 in. x 4.5 in. 4-layer PCB with 2 meter/sec air flow 1.36 C/W JEDEC 3 in. x 4.5 in. 4-layer PCB with 3 meter/sec air flow 1.52 C/W JEDEC with no air flow 18.6 C/W JEDEC with no air flow 22.7 C/W P = Total power dissipation JT J top Thermal resistance1 - junction to case for the device 48-Pin, QFN package JC Ty p Thermal - junction to JEDEC 3 in. x 4.5 in. 4-layer PCB ambient for the device 48-Pin, QFN with no air flow package JEDEC 3 in. x 4.5 in. 4-layer PCB with 1 meter/sec air flow JA = (TJ - TA)/ P JT Min JC = (TJ - TC)/ Ptop Ptop = Power dissipation from the top of the package Thermal resistance1 - junction to board for the device 48-Pin, QFN package JB JB = (TJ - TB)/ Pbottom Pbottom = Power dissipation from the bottom of the package to the PCB surface. 1. Refer to white paper on TJ Thermal Calculations for more information. Doc. No. MV-S107146-U0 Rev. E Page 120 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications Package Thermal Information 4.3.2 Thermal Conditions for 88E1512/88E1514 56-pin, QFN Package Table 134: Thermal Conditions for 88E1512/88E1514 56-pin, QFN Package S y m b ol Parameter C o n di ti on 1 JA Max Units 33.1 C/W 28.7 C/W JEDEC 3 in. x 4.5 in. 4-layer PCB with 2 meter/sec air flow 27.6 C/W JEDEC 3 in. x 4.5 in. 4-layer PCB with 3 meter/sec air flow 26.7 C/W Thermal characteristic parametera - JEDEC 3 in. x 4.5 in. 4-layer PCB junction to top center of the device with no air flow 56-Pin QFN package JEDEC 3 in. x 4.5 in. 4-layer PCB with 1 meter/sec air flow  = (T -T )/P. 0.54 C/W 0.92 C/W P = Total power dissipation Ttop: Temperature on the top center of the package. JEDEC 3 in. x 4.5 in. 4-layer PCB with 2 meter/sec air flow 1.17 C/W JEDEC 3 in. x 4.5 in. 4-layer PCB with 3 meter/sec air flow 1.31 C/W JEDEC with no air flow 17.8 C/W JEDEC with no air flow 20.7 C/W P = Total power dissipation JT J top Thermal resistance1 - junction to case for the device 56-Pin QFN package JC Ty p Thermal resistance - junction to JEDEC 3 in. x 4.5 in. 4-layer PCB ambient for the device 56-Pin QFN with no air flow package JEDEC 3 in. x 4.5 in. 4-layer PCB with 1 meter/sec air flow JA = (TJ - TA)/ P JT Min JC = (TJ - TC)/ Ptop Ptop = Power dissipation from the top of the package Thermal resistance1 - junction to board for the device 56-Pin QFN package JB JB = (TJ - TB)/ Pbottom Pbottom = Power dissipation from the bottom of the package to the PCB surface. 1. Refer to white paper on TJ Thermal Calculations for more information. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 121 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.4 88E1510/88E1518 Current Consumption 4.4.1 Current Consumption when using External Regulators Note The following current consumption numbers are shown when external supplies are used. If internal regulators are used, the current consumption will not change; however, the power consumed inside the package will increase. Care must be exercised when calculating the total current drawn on a rail when internal regulators are used. If the 1.0V and 1.8V internal regulators are used, the 1.0V and 1.8V current must be multiplied by 3.3V for power consumption calculation. Table 135: Current Consumption AVDD18 + AVDDC18 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IAVDD 1.8V Power to analog core AVDD18 RGMII to 1000BASE-T with traffic Min Ty p Max 63 Units mA RGMII to 100BASE-TX with traffic 25 mA RGMII to 10BASE-T with traffic 17 mA Energy Detect 10 mA IEEE Power Down 4 mA Table 136: Current Consumption AVDD331 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n Min Ty p Max Units IAVDDR Analog 3.3V supply AVDD33 RGMII to 1000BASE-T with traffic 50 mA RGMII to 100BASE-TX with traffic 12 mA RGMII to 10BASE-T with traffic 30 mA Energy Detect 2 mA IEEE Power Down 1 mA 1. AVDD33 current shown assumes no internal regulator are used. Table 137: Current Consumption DVDD (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IVDD 1.0V Power to digital core DVDD RGMII to 1000BASE-T with traffic 72 mA RGMII to 100BASE-TX with traffic 14 mA RGMII to 10BASE-T with traffic 9 mA Ty p Max Units Energy Detect 7 mA IEEE Power Down 7 mA Doc. No. MV-S107146-U0 Rev. E Page 122 Min Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications 88E1510/88E1518 Current Consumption Table 138: Current Consumption VDDO (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o nd i tio n IVDDO Power to the digital I/Os VDDO RGMII to 1000BASE-T with traffic VDDO = 3.3V 45 mA VDDO = 2.5V 36 mA VDDO = 1.8V 27 mA RGMII to 100BASE-TX with traffic VDDO = 3.3V 14 mA VDDO = 2.5V 10 mA VDDO = 1.8V 8 mA RGMII to 10BASE-T with traffic VDDO = 3.3V 9 mA VDDO = 2.5V 7 mA VDDO = 1.8V 6 mA VDDO = 3.3V 9 mA VDDO = 2.5V 7 mA Energy Detect IEEE Power Down 4.4.2 Min Ty p Max Units VDDO = 1.8V 6 mA VDDO = 3.3V 9 mA VDDO = 2.5V 7 mA VDDO = 1.8V 6 mA Current Consumption when using Internal Regulators Table 139: Current Consumption REG_IN (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IREG_IN 3.3V Internal Regulator Supply REG_IN RGMII to 1000BASE-T with traffic 80 mA RGMII to 100BASE-TX with traffic 32 mA RGMII to 10BASE-T with traffic 22 mA Energy Detect 25 mA IEEE Power Down 13 mA Note Ty p Max Units See Section 2.21, Regulators and Power Supplies, on page 68 for more details on internal regulator usage. Copyright © 2021 Marvell June 3, 2021 Min Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 123 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.5 88E1512 Current Consumption Note 4.5.1 The following current consumption numbers are shown when external supplies are used. If internal regulators are used, the current consumption will not change; however, the power consumed inside the package will increase. Care must be exercised when calculating the total current drawn on a rail when internal regulators are used. If the 1.0V and 1.8V internal regulators are used, the 1.0V and 1.8V current must be multiplied by 3.3V for power consumption calculation. Current Consumption when using External Regulators Table 140: Current Consumption AVDD18 + AVDDC18 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IAVDD 1.8V Power to analog core AVDD18 RGMII to 1000BASE-T with traffic Ty p 63 Max Units mA RGMII to 100BASE-TX with traffic 25 mA RGMII to 10BASE-T with traffic 17 mA SGMII to 1000BASE-T with traffic 84 mA SGMII to 100BASE-TX with traffic 49 mA SGMII to 10BASE-T with traffic 35 mA RGMII to SGMII at 1000 Mbps with traffic 25 mA RGMII to 1000BASE-X 25 mA RGMII to SGMII at 100 Mbps with traffic 25 mA RGMII to SGMII at 10 Mbps with traffic 25 mA Energy Detect 10 mA IEEE Power Down 4 mA Doc. No. MV-S107146-U0 Rev. E Page 124 Min Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications 88E1512 Current Consumption Table 141: Current Consumption AVDD331 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IAVDDR Analog 3.3V supply AVDD33 RGMII to 1000BASE-T with traffic Min Ty p 50 Max Units mA RGMII to 100BASE-TX with traffic 12 mA RGMII to 10BASE-T with traffic 30 mA SGMII to 1000BASE-T with traffic 52 mA SGMII to 100BASE-TX with traffic 13 mA SGMII to 10BASE-T with traffic 26 mA RGMII to 1000BASE-X 0 mA RGMII to SGMII at 1000 Mbps with traffic 0 mA RGMII to SGMII at 100 Mbps with traffic 0 mA RGMII to SGMII at 10 Mbps with traffic 0 mA Energy Detect 2 mA IEEE Power Down 1 mA 1. AVDD33 current shown assumes no internal regulator are used. Table 142: Current Consumption DVDD (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IVDD 1.0V Power to digital core DVDD RGMII to 1000BASE-T with traffic 72 mA RGMII to 100BASE-TX with traffic 14 mA RGMII to 10BASE-T with traffic 8 mA SGMII to 1000BASE-T with traffic 73 mA SGMII to 100BASE-TX with traffic 16 mA Ty p Max Units SGMII to 10BASE-T with traffic 9 mA RGMII to 1000BASE-X 14 mA RGMII to SGMII at 1000 Mbps with traffic 14 mA RGMII to SGMII at 100 Mbps with traffic 11 mA RGMII to SGMII at 10 Mbps with traffic 10 mA Energy Detect 7 mA IEEE Power Down 7 mA Copyright © 2021 Marvell June 3, 2021 Min Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 125 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 143: Current Consumption VDDO (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o nd i tio n IVDDO Power to the digital I/Os VDDO SGMII to 1000BASE-T with traffic VDDO = 3.3V 4 mA SGMII to 100BASE-TX with traffic VDDO = 2.5V 4 mA SGMII to 10BASE-T with traffic VDDO = 1.8V 4 mA RGMII to SGMII at 1000 Mbps with traffic VDDO = 3.3V 44 mA VDDO = 2.5V 36 mA VDDO = 1.8V 27 mA VDDO = 3.3V 12 mA VDDO = 2.5V 10 mA VDDO = 1.8V 9 mA VDDO = 3.3V 7 mA VDDO = 2.5V 7 mA VDDO = 1.8V 7 mA VDDO = 3.3V 9 mA VDDO = 2.5V 7 mA RGMII to SGMII at 100 Mbps with traffic RGMII to SGMII at 10 Mbps with traffic Energy Detect IEEE Power Down 4.5.2 Min Ty p Max Units VDDO = 1.8V 6 mA VDDO = 3.3V 9 mA VDDO = 2.5V 7 mA VDDO = 1.8V 6 mA Current Consumption when using Internal Regulators Table 144: Current Consumption REG_IN (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IREG_IN 3.3V Internal Regulator Supply REG_IN RGMII to 1000BASE-T with traffic 80 mA RGMII to 100BASE-TX with traffic 32 mA 3.3V Internal Regulator Supply REG_IN IREG_IN Ty p Max Units RGMII to 10BASE-T with traffic 22 mA SGMII to 1000BASE-T with traffic 92 mA SGMII to 100BASE-TX with traffic 53 mA SGMII to 10BASE-T with traffic 43 mA RGMII to 1000BASE-X 28 mA RGMII to SGMII at 1000 Mbps 28 mA RGMII to SGMII at 100 Mbps 27 mA RGMII to SGMII at 10 Mbps 26 mA Energy Detect 25 mA IEEE Power Down 13 mA Doc. No. MV-S107146-U0 Rev. E Page 126 Min Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications 88E1514 Current Consumption Note See Section 2.21, Regulators and Power Supplies, on page 68 for more details on internal regulator usage. 4.6 88E1514 Current Consumption 4.6.1 Current Consumption when using External Regulators Table 145: Current Consumption AVDD18 + AVDDC18 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IAVDD 1.8V Power to analog core AVDD18, AVDDC18 SGMII to 1000BASE-T with traffic Min 88 Ty p Max mA Units SGMII to 100BASE-TX with traffic 51 mA SGMII to 10BASE-T with traffic 41 mA Energy Detect 10 mA IEEE Power Down 4 mA Table 146: Current Consumption AVDD33 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IAVDDR Analog 3.3V supply AVDD33 SGMII to 1000BASE-T with traffic Min 58 Ty p Max mA Units SGMII to 100BASE-TX with traffic 16 mA SGMII to 10BASE-T with traffic 32 mA Energy Detect 2 mA IEEE Power Down 1 mA Table 147: Current Consumption DVDD (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IVDD 1.0V Power to digital core DVDD SGMII to 1000BASE-T with traffic 90 mA SGMII to 100BASE-TX with traffic 21 mA SGMII to 10BASE-T with traffic 11 mA Energy Detect 7 mA IEEE Power Down 7 mA Copyright © 2021 Marvell June 3, 2021 Min Ty p Max Units Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 127 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Table 148: Current Consumption VDDO (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IVDDO Power to the digital I/Os VDDO SGMII to 1000BASE-T with traffic VDDO = 3.3V 6 mA SGMII to 100BASE-TX with traffic VDDO = 2.5V 6 mA SGMII to 10BASE-T with traffic VDDO = 1.8V 6 mA Energy Detect IEEE Power Down 4.6.2 Min Ty p Max Units VDDO = 3.3V 6 mA VDDO = 2.5V 6 mA VDDO = 1.8V 6 mA VDDO = 3.3V 6 mA VDDO = 2.5V 6 mA VDDO = 1.8V 6 mA Current Consumption when using Internal Regulators Table 149: Current Consumption REG_IN (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P i ns C o n di ti o n IREG_IN 3.3V Internal Regulator Supply REG_IN SGMII to 1000BASE-T with traffic 92 mA SGMII to 100BASE-TX with traffic 53 mA SGMII to 10BASE-T with traffic 43 mA Note Ty p Max Units Energy Detect 25 mA IEEE Power Down 13 mA See Section 2.21, Regulators and Power Supplies, on page 68 for more details on internal regulator usage. Doc. No. MV-S107146-U0 Rev. E Page 128 Min Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications DC Operating Conditions 4.7 DC Operating Conditions 4.7.1 Digital Pins Table 150: Digital Pins (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter Pi n s 1 C o nd i tio n VIH Input high voltage All digital inputs VDDO = 3.3V 2.0 VDDO+0.4V V VDDO = 2.5V 1.75 VDDO+0.4 V VDDO = 1.8V 1.26 VDDO+0.6V V VIL Input low voltage All digital inputs High level output voltage All digital outputs VOL Low level output voltage All digital outputs IOH High level output Current All digital Outputs Low level output Current All digital Outputs IOL IILK Input leakage current CIN Input capacitance Ty p Max Units VDDO = 3.3V 0.8 V VDDO = 2.5V 0.75 V 0.54 V VDDO = 1.8V (88E1518/ 88E1512/ 88E1514) VOH Min -0.3 VDDO - 0.4V V 0.4 V VDDO = 3.3V 4 mA VDDO = 2.5V 4 mA VDDO = 1.8V 1 mA VDDO = 3.3V -4 mA VDDO = 2.5V -4 mA VDDO = 1.8V -1 mA All pins 10 uA 5 pF 1. VDDO supplies the CLK125, MDC, MDIO, RESETn, LED[2:0], CONFIG, TX_CLK, TX_CTRL, TXD[3:0], RX_CLK, RX_ CTRL, and RXD[3:0]. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 129 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.7.2 LED Pins Table 151: LED Pins Sy m b o l Parameter P i ns C o n d iti o n Min VOH High level output voltage All LED outputs IOH = -8 mA VDDO - 0.4V VOL Low level output voltage All LED outputs IOL = 8 mA IMAX Total maximum current per port IILK CIN Max U n it s V 0.4 V All LED pins 10 mA Input leakage current All LED pins 10 uA Input capacitance All LED pins 5 pF Doc. No. MV-S107146-U0 Rev. E Page 130 Ty p Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications DC Operating Conditions 4.7.3 IEEE DC Transceiver Parameters Table 152: IEEE DC Transceiver Parameters IEEE tests are typically based on template and cannot simply be specified by a number. For an exact description of the template and the test conditions, refer to the IEEE specifications. -10BASE-T IEEE 802.3 Clause 14 -100BASE-TX ANSI X3.263-1995 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter P in s C o n d it io n M in Ty p Max U ni ts VODIFF Absolute peak differential output voltage MDIP/N[1:0] 10BASE-T no cable 2.2 2.5 2.8 V VIDIFF 1 MDIP/N[1:0] 10BASE-T cable model 585 MDIP/N[1:0] 100BASE-TX mode 0.950 1.0 0.67 0.75 mV 1.050 V MDIP/N[3:0] 1000BASE-T2 0.82 V Overshoot2 MDIP/N[:0] 100BASE-TX mode 0 5% V Amplitude Symmetry (positive/negative) MDIP/N[1:0] 100BASE-TX mode 0.98x 1.02x V+/V- Peak Differential Input Voltage MDIP/N[1:0] 10BASE-T mode 5853 Signal Detect Assertion MDIP/N[1:0] 100BASE-TX mode 1000 4604 mV peak-peak Signal Detect De-assertion MDIP/N[1:0] 100BASE-TX mode 200 3605 mV peak-peak mV 1. IEEE 802.3 Clause 14, Figure 14.9 shows the template for the “far end” wave form. This template allows as little as 495 mV peak differential voltage at the far end receiver. 2. IEEE 802.3ab Figure 40 -19 points A&B. 3. The input test is actually a template test; IEEE 802.3 Clause 14, Figure 14.17 shows the template for the receive wave form. 4. The ANSI TP-PMD specification requires that any received signal with peak-to-peak differential amplitude greater than 1000 mV should turn on signal detect (internal signal in 100BASE-TX mode). The device will accept signals typically with 460 mV peak-to-peak differential amplitude. 5. The ANSI-PMD specification requires that any received signal with peak-to-peak differential amplitude less than 200 mV should de-assert signal detect (internal signal in 100BASE-TX mode). The Alaska® Quad will reject signals typically with peak-to-peak differential amplitude less than 360 mV. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 131 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.7.4 SGMII Interface SGMII specification is a de-facto standard proposed by Cisco. It is available at the Cisco website ftp://ftp-eng.cisco/smii/sgmii.pdf. It uses a modified LVDS specification based on the IEEE standard 1596.3. Refer to that standard for the exact definition of the terminology used in the following table. The device adds flexibility by allowing programmable output voltage swing and supply voltage option. 4.7.4.1 Transmitter DC Characteristics Table 153: Transmitter DC Characteristics Sy m b o l P ar a m e te r 1 VOH Output Voltage High VOL Output Voltage Low 2 Ty p Max U ni ts 1600 mV 700 Output Ringing VRING |VOD| Min mV 10 % Output Voltage Swing (differential, peak) Programmable - see Table 154. mV peak VOS Output Offset Voltage (also called Common mode voltage) Variable - see 4.7.4.2 for details. mV RO Output Impedance (single-ended) (50 ohm termination) 40 60 s Delta RO Mismatch in a pair 10 % Delta VOD Change in VOD between 0 and 1 25 mV Delta VOS Change in VOS between 0 and 1 25 mV IS+, IS- Output current on short to VSS 40 mA IS+- Output current when S_OUT+ and S_ OUT- are shorted 12 mA IX+, IX- Power off leakage current 10 mA 1. Parameters are measured with outputs AC connected with 100 ohm differential load. 2. Output amplitude is programmable by writing to Register 26_1.2:0. Table 154: Programming SGMII Output Amplitude R e g is t e r 2 6 _1 B it s F i e ld 2:0 D e s c r i p t io n SGMII/Fiber Output Differential voltage peak measured. Amplitude1 Note that internal bias minus the differential peak voltage must be greater than 700 mV. 000 = 14 mV 001 = 112 mV 010 = 210 mV 011 = 308 mV 100 = 406 mV 101 = 504 mV 110 = 602 mV 111 = 700 mV 1. Cisco SGMII specification limits are |VOD| = 150 mV - 400 mV peak differential. Doc. No. MV-S107146-U0 Rev. E Page 132 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications DC Operating Conditions Figure 24: CML I/Os CML Outputs CML Inputs Internal bias1 50 ohm Internal bias1 50 ohm 50 ohm S_OUT+ S_OUT- S_IN+ Internal bias Isink 50 ohm S_IN1. Internal bias is generated from the AVDDH supply and is typically 1.05V. 4.7.4.2 Common Mode Voltage (Voffset) Calculations There are four different main configurations for the SGMII/Fiber interface connections. These are: • • • • DC connection to an LVDS receiver AC connection to an LVDS receiver DC connection to an CML receiver AC connection to an CML receiver If AC coupling or DC coupling to an LVDS receiver is used, the DC output levels are determined by the following: • • • Internal bias. See Figure 24 for details. (If AVDD18 is used to generate the internal bias, the internal bias value will typically be 1.05V.) The output voltage swing is programmed by Register 26_1.2:0 (see Table 154). Voffset (i.e., common mode voltage) = internal bias - single-ended peak-peak voltage swing. See Figure 25 for details. If DC coupling is used with a CML receiver, then the DC levels will be determined by a combination of the MACs output structure and the input structure shown in the CML Inputs diagram in Figure 26. Assuming the same MAC CML voltage levels and structure, the common mode output levels will be determined by: • • Voffset (i.e., common mode voltage) = internal bias - single-ended peak-peak voltage swing/2. See Figure 26 for details. If DC coupling is used, the output voltage DC levels are determined by the AC coupling considerations above, plus the I/O buffer structure of the MAC. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 133 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Figure 25: AC connections (CML or LVDS receiver) or DC connection LVDS receiver CML Outputs Internal bias1 V = Internal bias - Vpeak 50 ohm 50 ohm S_OUT+ AC coupling Cap. V = Voffset S_OUT(opposite of S_OUT+) Isink 1. Internal bias is generated from the AVDDH supply and is typically 1.05V. Single-ended Voltage details Internal bias - Vpeak Vpeak S_OUTP V = Voffset (i.e., common mode voltage) = Internal bias - Vpeak-peak Vmin = Internal bias - 3 * Vpeak Vmin must be greater than 700 mV S_OUTN Doc. No. MV-S107146-U0 Rev. E Page 134 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications DC Operating Conditions Figure 26: DC connection to a CML receiver CML Inputs CML Outputs Internal bias1 Internal bias1 V = Internal bias 50 ohm 50 ohm S_OUT+ S_OUT(opposite of S_OUT+) 50 ohm V = Voffset S_IN+ V = Internal bias Vpeak-peak Internal bias Isink 50 ohm S_IN- 1. Internal bias is generated from the AVDDH supply and is typically 1.05V. Single-ended Voltage details Internal bias Vpeak S_OUTP V = Voffset (i.e., common mode voltage) = Internal bias - Vpeak Internal bias Vmin = Internal bias - Vpeak-peak (single ended) (V min must be greater than 700 mV) S_OUTN Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 135 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.7.4.3 Receiver DC Characteristics Table 155: Receiver DC Characteristics Sy m b o l P ar a m e te r Min Ty p Max Units VI Input Voltage range a or b 675 1725 mV VIDTH Input Differential Threshold 50 50 mV VHYST Input Differential Hysteresis 25 RIN Receiver 100 W Differential Input Impedance 80 mV 120 W Figure 27: Input Differential Hysteresis Receiver High -50 mV +50 mV -VIDTH VIDTH VS_IN+ - VS_IN- Receiver Low VHYST Doc. No. MV-S107146-U0 Rev. E Page 136 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications AC Electrical Specifications 4.8 AC Electrical Specifications 4.8.1 Reset Timing Table 156: Reset Timing (Over Full range of values listed in the Recommended Operating Conditions unless otherwise specified) S ym bo l Parameter TPU_RESET Valid power to RESETn de-asserted 10 ms TSU_XTAL_ Number of valid XTAL_IN cycles prior to RESETn de-asserted 10 clks Minimum reset pulse width during normal operation 10 ms IN TRESET Min Ty p Max Units Figure 28: Reset Timing TPU_RESET Power TSU_XTAL_IN XTAL RESETn TRESET Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 137 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.8.2 XTAL_IN/XTAL_OUT Timing1 Table 157: XTAL_IN/XTAL_OUT Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l Parameter TP_XTAL_IN TH_XTAL_IN C o nd i tio n Min Ty p Max Units XTAL_IN Period 40-50 ppm 40 40+50 ppm ns XTAL_IN High time 13 20 27 ns TL_XTAL_IN XTAL_IN Low time 13 20 27 ns TR_XTAL_IN XTAL_IN Rise 10% to 90% - 3.0 - ns TF_XTAL_IN XTAL_IN Fall 90% to 10% - 3.0 - ns TJ_XTAL_IN XTAL_IN total jitter1 - - 200 ps2 XTAL_ESR Crystal ESR3 - 30 50 W 1. PLL generated clocks are not recommended as input to XTAL_IN since they can have excessive jitter. Zero delay buffers are also not recommended for the same reason. 2. 12 kHz to 20 MHz rms jitter on XTAL_IN = 4 ps. 3. See “How to use Crystals as Clock Sources” application note for details. Figure 29: XTAL_IN/XTAL_OUT Timing TP_XTAL_IN TH_XTAL_IN TL_XTAL_IN XTAL_IN TR_XTAL_IN TF_XTAL_IN 1. If the crystal option is used, ensure that the frequency is 25 MHz ± 50 ppm. Capacitors must be chosen carefully - see application note supplied by the crystal vendor. Doc. No. MV-S107146-U0 Rev. E Page 138 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications AC Electrical Specifications 4.8.3 LED to CONFIG Timing Table 158: LED to CONFIG Timing S ym bo l P a r a m e te r Min TDLY_CONFIG LED to CONFIG Delay 0 Ty p Max Units 25 ns Figure 31: LED to CONFIG Timing LED CONFIG TDLY_CONFIG Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 139 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.9 SGMII Timing 4.9.1 SGMII Output AC Characteristics Table 159: SGMII Output AC Characteristics S ym bo l Parameter Min Ty p Max TFALL VOD Fall time (20% - 80%) 100 200 ps TRISE VOD Rise time (20% - 80%) 100 200 ps TSKEW11 Skew between two members of a differential pair 20 ps TOutputJitter Total Output Jitter (Deterministic + 14*rms Random) 127 U nits ps 1. Skew measured at 50% of the transition. 4.9.2 SGMII Input AC Characteristics Table 160: SGMII Input AC Characteristics S ym bo l Parameter Min TInputJitter Total Input Jitter Tolerance (Deterministic + 14*rms Random) Doc. No. MV-S107146-U0 Rev. E Page 140 Ty p Max U nits 599 ps Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications RGMII Timing 4.10 RGMII Timing 4.10.1 RGMII AC Characteristics Table 161: RGMII AC Characteristics (This table is copied from the RGMII Specification. See Application Note “RGMII Timing Modes” for details of how to convert the timings in this table to the four timing modes discussed in Section 4.10.2, RGMII Delay Timing for Different RGMII Modes, on page 142). Sy m b o l P a r a m e te r Min Ty p Max Units TskewT Data to Clock output Skew (at transmitter) -500 0 500 ps TskewR Data to Clock input Skew (at receiver) 1.0 - 2.8 ns TCYCLE Clock Cycle Duration 7.2 8.0 8.8 ns TCYCLE_HIGH1000 High Time for 1000BASE-T 1 3.6 4.0 4.4 ns TCYCLE_HIGH100 High Time for 100BASE-T1 16 20 24 ns 160 200 240 ns 0.75 ns 10BASE-T1 TCYCLE_HIGH10 High Time for TRISE/TFALL Rise/Fall Time (20-80%) 1. Duty cycle may be stretched/shrunk during speed changes or while transitioning to a received packet’s clock domain as long as minimum duty cycle is not violated and stretching occurs for no more than three TCYCLE of the lowest speed transitioned between. Figure 33: RGMII Multiplexing and Timing TX_CLK (TXC) at transmitter TXD[7:4][3:0] TSKEWT TXD[3:0] TXD[7:4] TX_EN TX_ER RXD[3:0] RXD[7:4] RX_DV RX_ER TSKEWR TX_CTRL(TX_CTL) TX_CLK (TXC) at receiver RX_CLK (RXC) at transmitter TSKEWT RXD[7:4][3:0] TSKEWR RX_CTRL (RX_CTL) RX_CLK (RXC) at receiver This figure is copied from the RGMII Specification. See Application Note “RGMII Timing Modes” for details of how to convert the timings in this table to the four timing modes discussed in Section 4.10.2, RGMII Delay Timing for Different RGMII Modes, on page 142 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 141 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.10.2 RGMII Delay Timing for Different RGMII Modes 4.10.2.1 PHY Input - TX_CLK Delay when Register 21_2.4 = 0 Table 162: PHY Input - TX_CLK Delay when Register 21_2.4 = 0 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) S ym bo l Parameter tsetup Register 21_2.4 = 0 Min thold Ty p M ax U ni ts 1.0 ns 0.8 ns Figure 34: TX_CLK Delay Timing - Register 21_2.4 = 0 TX_CLK TXD[3:0], TX_CTRL thold thold tsetup 4.10.2.2 tsetup PHY Input - TX_CLK Delay when Register 21_2.4 = 1 Table 163: PHY Input - TX_CLK Delay when Register 21_2.4 = 1 (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) S ym bo l Parameter Min tsetup Register 21_2.4 = 1 (add delay) -0.9 ns 2.7 ns thold Ty p M ax U ni ts Figure 35: TX_CLK Delay Timing - Register 21_2.4 = 1 (add delay) TX_CLK TXD[3:0], TX_CTRL tsetup tsetup thold Doc. No. MV-S107146-U0 Rev. E Page 142 thold Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications RGMII Timing 4.10.2.3 PHY Output - RX_CLK Delay Table 164: PHY Output - RX_CLK Delay (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) S ym bo l Parameter Min tskew Register 21_2.5 = 0 - 0.5 Ty p Max Units 0.5 ns Figure 36: RGMII RX_CLK Delay Timing - Register 21_2.5 = 0 RX_CLK RXD[3:0], RX_CTRL tskew tskew tskew 4.10.2.4 tskew PHY Output - RX_CLK Delay Table 165: PHY Output - RX_CLK Delay (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) S ym bo l Parameter Min tsetup Register 21_2.5 = 1 (add delay) 1.2 ns 1.2 ns thold Ty p Max Units Figure 37: RGMII RX_CLK Delay Timing - Register 21_2.5 = 1 (add delay) RX_CLK RXD[3:0], RX_CTRL thold thold tsetup Copyright © 2021 Marvell June 3, 2021 tsetup Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 143 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.11 MDC/MDIO Timing Table 166: MDC/MDIO Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) S ym bo l Parameter M in TDLY_MDIO MDC to MDIO (Output) Delay Time 0 Ty p Max U ni ts 20 ns TSU_ MDIO MDIO (Input) to MDC Setup Time 10 THD_ MDIO MDIO (Input) to MDC Hold Time 10 ns TP_ MDC MDC Period 83.3 ns1 TH_ MDC MDC High 30 ns TL_ MDC MDC Low 30 ns ns 1. Maximum frequency = 12 MHz. Figure 38: MDC/MDIO Timing TH_MDC TL_MDC MDC TP_MDC TDLY_MDIO MDIO (Output) MDC THD_MDIO TSU_MDIO Valid Data MDIO (Input) Doc. No. MV-S107146-U0 Rev. E Page 144 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications IEEE AC Transceiver Parameters 4.12 IEEE AC Transceiver Parameters Table 167: IEEE AC Transceiver Parameters IEEE tests are typically based on templates and cannot simply be specified by number. For an exact description of the templates and the test conditions, refer to the IEEE specifications: -10BASE-T IEEE 802.3 Clause 14-2000 -100BASE-TX ANSI X3.263-1995 -1000BASE-T IEEE 802.3ab Clause 40 Section 40.6.1.2 Figure 40-26 shows the template waveforms for transmitter electrical specifications. (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l P a r a m e te r P in s C o n d iti o n Min Ty p Max Units TRISE Rise time MDIP/N[1:0] 100BASE-TX 3.0 4.0 5.0 ns TFALL Fall Time MDIP/N[1:0] 100BASE-TX 3.0 4.0 5.0 ns MDIP/N[1:0] 100BASE-TX 0 0.5 ns MDIP/N[1:0] 100BASE-TX 0 0.51 ns, peak-peak MDIP/N[1:0] 100BASE-TX 0 1.4 ns, peak-peak TRISE/TFALL Symmetry DCD Duty Cycle Distortion Transmit Jitter 1. ANSI X3.263-1995 Figure 9-3 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 145 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.13 Latency Timing 4.13.1 RGMII to 1000BASE-T Transmit Latency Timing Table 168: RGMII to 1000BASE-T Transmit Latency Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified, assuming default FIFO setting) S ym bo l P a r a m e te r Min TAS_TXC_MDI_1000 1000BASE-T TX_CTRL Asserted to MDI SSD1 141 Ty p Max Units 153 ns 4.13.2 RGMII to 100BASE-TX Transmit Latency Timing Table 169: RGMII to 100BASE-TX Transmit Latency Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified, assuming default FIFO setting S ym bo l P a r a m e te r Min TAS_TXC_ MDI_100 100BASE-TX TX_CTRL Asserted to /J/ 634 Ty p Max Units 679 ns 4.13.3 RGMII to 10BASE-T Transmit Latency Timing Table 170: RGMII to 10BASE-T Transmit Latency Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified, assuming default FIFO setting) S ym bo l P a r a m e te r Min TAS_TXC_ MDI _10 10BASE-T TX_CTRL Asserted to Preamble 5.874 Ty p Max Units 6.258 s Figure 40: RGMII/MII to 10/100/1000BASE-T Transmit Latency Timing TX_CLK(TXC) TX_CTRL/ (TX_CTL) MDI (CSExtend, CSExtend_Err) 1000 SSD1 SSD2 CSReset 100 /J/ /K/ /T/ 10 PREAMBLE /R/ ETD TAS_TXC_ MDI Doc. No. MV-S107146-U0 Rev. E Page 146 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications Latency Timing 4.13.4 1000BASE-T to RGMII Receive Latency Timing Table 171: 1000BASE-T to RGMII Receive Latency Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) 4.13.5 S ym bo l P a r a m e te r Min TAS_MDI_RXC_1000 1000BASE-T MDI start of Packet to RX_CTRL Asserted 227 Ty p Max Units 235 ns 100BASE-TX to RGMII Receive Latency Timing Table 172: 100BASE-TX to RGMII Receive Latency Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) 4.13.6 S ym bo l P a r a m e te r Min TAS_MDI_RXC_100 100BASE-TX MDI start of Packet to RX_CTRL Asserted 362 Ty p Max Units 362 ns 10BASE-T to RGMII Receive Latency Timing Table 173: 10BASE-T to RGMII Receive Latency Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) S ym bo l P a r a m e te r Min TAS_MDI_RXC_10 10BASE-T MDI start of Packet to RX_ CTRL Asserted 2.082 Ty p Max Units 2.178 s Figure 41: 10/100/1000BASE-T to RGMII Receive Latency Timing (CSExtend, CSExtend_Err) MDI 1000 100 10 SSD1 SSD2 CSReset /J/ /K/ /T/ /R/ ETD PREAMBLE RX_CTRL/ (RX_CTL) RX_CLK(RXC) TAS_MDI_RXC Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 147 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 4.13.7 10/100/1000BASE-T to SGMII Latency Timing Table 174: 10/100/1000BASE-T to SGMII Latency Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l P a r a m e te r Min TAS_MDI_SERTX_10001,2 TAS_MDI_SERTX_1002 TAS_MDI_SERTX_102,3 MDI SSD1 to S_OUTP/N Start of Packet MDI /J/ to S_OUTP/N Start of Packet MDI Preamble to S_OUTP/N Start of Packet Ty p Max Units 326 361 ns 776 866 ns 5.702 6.103 us 1. In 1000BASE-T the signals on the 4 MDI pairs arrive at different times because of the skew introduced by the cable. All timing on MDIP/N[3:0] is referenced from the latest arriving signal. 2. Assumes Register 16_1.15:14 is set to 01, which is the default. 3. Actual values depend on number of bits in preamble and number of dribble bits, since nibbles on MII are aligned to start of frame delimiter and dribble bits are truncated. Figure 42: 10/100/1000BASE-T to SGMII Latency Timing (CSExtend, CSExtend_Err) MDI 1000 100 10 SSD1 SSD2 CSReset /J/ /K/ /T/ ETD PREAMBLE S_OUTP/N T 1ST /S/ 1ST /T/ /S/ /T/ AS_MDI_SERTX Doc. No. MV-S107146-U0 Rev. E Page 148 /R/ Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Electrical Specifications Latency Timing 4.13.8 SGMII to 10/100/1000BASE-T Latency Timing Table 175: SGMII to 10/100/1000BASE-T Latency Timing (Over full range of values listed in the Recommended Operating Conditions unless otherwise specified) Sy m b o l P a r a m e te r Min TAS_SERRX_MDI_10001 TAS_SERRX_MDI_1001 TAS_SERRX_MDI_101 S_INP/N Start of Packet /S/ to MDI SSD1 S_INP/N Start of Packet /S/ to MDI /J/ S_INP/N Start of Packet /S/ to MDI Preamble Ty p Max Units 206 232 ns 626 706 ns 4.991 5.779 us 1. Assumes register 16_2.15:14 is set to 01, which is the default. Figure 43: SGMII to 10/100/1000BASE-T Latency Timing S_INP/N 1st /T/ /T/ 1st /S/ /S/ (CSExtend, CSExtend_Err) MDI 1000 SSD1 SSD2 CSReset 100 /J/ /K/ /T/ 10 PREAMBLE /R/ ETD T AS_SERRX_MDI Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 149 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 5 Package Mechanical Dimensions This section includes information on the following topics:  Section 5.1, 48-Pin QFN Package  Section 5.2, 56-Pin QFN Package 5.1 48-Pin QFN Package Figure 44: 88E1510/88E1518 48-pin QFN Package Mechanical Drawings D 4X L A1 A3 E E1 A A2 D1 b DETAIL : B A ''B'' SEATING PLANE 0.6 max "A" 0.6 max E2 b D2 DETAIL : A e NOTE: 1. CONTROLLING DIMENSION : MILLIMETER Doc. No. MV-S107146-U0 Rev. E Page 150 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Package Mechanical Dimensions 48-Pin QFN Package Table 176: 48-Pin QFN Mechanical Dimensions S ym bo l D im e ns i on s in m m M IN NOM MAX A 0.80 0.85 1.00 A1 0.00 0.02 0.05 A2 -- 0.65 1.00 A3 b 0.20 REF 0.18 0.23 D 7.00 BSC D1 6.75 BSC E 7.00 BSC E1 6.75 BSC e 0.50 BSC 0.30 L 0.30 0.40 0.50  0 -- 12 aaa -- -- 0.25 bbb -- -- 0.10 chamfer -- -- 0.60 D i e P a d S iz e S ym bo l D im en s i on in m m D2 3.10 E2 3.10 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 151 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 5.2 56-Pin QFN Package Figure 45: 88E1512/88E1514 56-pin QFN Package Mechanical Drawings D D1 Ø1.0mm 4 XO N 1 A3 L A1 E E1 A 3 A2 2 b DETAIL : B 0.08 C A "B" SEATING PLANE 0.6max E2 b D2 0.6max "A" e DETAIL : A All dimensions in mm. Note Doc. No. MV-S107146-U0 Rev. E Page 152 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Package Mechanical Dimensions 56-Pin QFN Package Table 177: 56-Pin QFN Mechanical Dimensions S ym bo l D im e ns i on s in m m M IN NOM MAX A 0.80 0.85 1.00 A1 0.00 0.02 0.05 A2 -- 0.65 1.00 A3 0.20 REF b 0.18 0.23 0.30 D 8.00 BSC D1 7.75 BSC E 8.00 BSC E1 7.75 BSC e 0.50 BSC L 0.30 0.40 0.50  0 -- 12 aaa -- -- 0.15 bbb -- -- 0.10 chamfer -- -- 0.60 D i e P a d S iz e S ym bo l D im en s i on in m m D2 4.37 E2 4.37 Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 153 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 6 Part Order Numbering/Package Marking This section includes information on the following topics:  Section 6.1, Part Order Numbering  Section 6.2, Package Marking 6.1 Part Order Numbering Figure 46 shows the part order numbering scheme for the 88E1510/88E1518/88E1512/88E1514. Refer to Marvell Field Application Engineers (FAEs) or representatives for further information when ordering parts. Figure 46: Sample Part Number 88Exxxx –xx–xxx–x000–xxxx Custom Code (optional) P123 = Tape-and-Reel Custom Code Part Number 88E1510 88E1512 88E1514 88E1518 Temperature Code C = Commercial I = Industrial Custom Code Environmental Code 2 = Green (RoHS 6/6 and Halogen-free) Custom Code Package Code NNB = 48-pin QFN NNP = 56-pin QFN R. Table 178: 88E1510/88E1518/88E1512/88E1514 Part Order Options P a c k a g e Ty p e P ar t O r d e r N u m b e r Commercial 88E1510 48-pin QFN 88E1510-xx-NNB2C000 (Commercial, Green, RoHS 6/6 and Halogen-free package) 88E1510 48-pin QFN Tape-and-Reel 88E1510-xx-NNB2C000-P123 (Commercial, Green, RoHS 6/6 and Halogen-free package) 88E1518 48-pin QFN 88E1518-xx-NNB2C000 (Commercial, Green, RoHS 6/6 and Halogen-free package) Doc. No. MV-S107146-U0 Rev. E Page 154 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Part Order Numbering/Package Marking Package Marking Table 178: 88E1510/88E1518/88E1512/88E1514 Part Order Options (Continued) P a c k a g e Ty p e P ar t O r d e r N u m b e r 88E1518 48-pin QFN Tape-and-Reel 88E1518-xx-NNB2C000-P123 (Commercial, Green, RoHS 6/6 and Halogen-free package) 88E1512 56-pin QFN 88E1512-xx-NNP2C000 (Commercial, Green, RoHS 6/6 and Halogen-free package) 88E1514 56-pin QFN 88E1514-xx-NNP2C000 (Commercial, Green, RoHS 6/6 and Halogen-free package) 88E1514 56-pin QFN Tape-and-Reel 88E1514-xx-NNP2C000-P123 (Commercial, Green, RoHS 6/6 and Halogen-free package) In d u st r i a l 88E1510 48-pin QFN 88E1510-xx-NNB2I000 (Industrial, Green, RoHS 6/6 and Halogen-free package) 88E1512 56-pin QFN 88E1512-xx-NNP2I000 (Industrial, Green, RoHS 6/6 and Halogen-free package) 88E1512 56-pin QFN Tape-and-Reel 88E1512-xx-NNP2I000-P123 (Industrial, Green, RoHS 6/6 and Halogen-free package) 6.2 Package Marking 6.2.1 Commercial The following figures show sample Commercial package markings and pin 1 location for the 88E1510/88E1518/88E1512/88E1514:  Figure 47 for 88E1510 48-pin QFN  Figure 48 for 88E1518 48-pin QFN  Figure 49 for 88E1512 56-pin QFN  Figure 50 for 88E1514 56-pin QFN Figure 47: 88E1510 48-pin QFN Commercial Package Marking and Pin 1 Location Marvell Logo Country of Origin (Contained in the mold ID or marked as the last line on the package.) Pin 1 Location 88E1510-NNB2 Lot Number YYWW xx@ Country of Origin Part Number, Package Code, Environmental Code 88E1510 = Part Number NNB = Package Code 2 = Environmental Code (2 = RoHS 6/6 + Halogen-free (Green)) Date code, Custom Code, Assembly Plant Code YYWW = Date code (YY = year, WW = Work Week) xx = Custom Code/Die Revision @ = Assembly Plant Code Note: The above drawing is not drawn to scale. Location of markings is approximate. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 155 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public Figure 48: 88E1518 48-pin QFN Commercial Package Marking and Pin 1 Location Marvell Logo Country of Origin (Contained in the mold ID or marked as the last line on the package.) 88E1518-NNB2 Lot Number YYWW xx@ Country of Origin Pin 1 Location Part Number, Package Code, Environmental Code 88E1518 = Part Number NNB = Package Code 2 = Environmental Code (2 = RoHS 6/6 + Halogen-free (Green)) Date code, Custom Code, Assembly Plant Code YYWW = Date code (YY = year, WW = Work Week) xx = Custom Code/Die Revision @ = Assembly Plant Code Note: The above drawing is not drawn to scale. Location of markings is approximate. Figure 49: 88E1512 56-pin QFN Commercial Package Marking and Pin 1 Location Marvell Logo Country of Origin (Contained in the mold ID or marked as the last line on the package.) Pin 1 Location 88E1512-NNP2 Lot Number YYWW xx@ Country of Origin Part Number, Package Code, Environmental Code 88E1512 = Part Number NNP = Package Code 2 = Environmental Code (2 = RoHS 6/6 + Halogen-free (Green)) Date code, Custom Code, Assembly Plant Code YYWW = Date code (YY = year, WW = Work Week) xx = Custom Code/Die Revision @ = Assembly Plant Code Note: The above drawing is not drawn to scale. Location of markings is approximate. Doc. No. MV-S107146-U0 Rev. E Page 156 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Part Order Numbering/Package Marking Package Marking Figure 50: 88E1514 56-pin QFN Commercial Package Marking and Pin 1 Location Marvell Logo Country of Origin (Contained in the mold ID or marked as the last line on the package.) Pin 1 Location 88E1514-NNP2 Lot Number YYWW xx@ Country of Origin Part Number, Package Code, Environmental Code 88E1514 = Part Number NNP = Package Code 2 = Environmental Code (2 = RoHS 6/6 + Halogen-free (Green)) Date code, Custom Code, Assembly Plant Code YYWW = Date code (YY = year, WW = Work Week) xx = Custom Code/Die Revision @ = Assembly Plant Code Note: The above drawing is not drawn to scale. Location of markings is approximate. Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 157 Alaska 88E1510/88E1518/88E1512/88E1514 Datasheet - Public 6.2.2 Industrial The following figures show sample Industrial package markings and pin 1 location for the 88E1510/88E1518/88E1512/88E1514:  Figure 51 for 88E1510 48-pin QFN  Figure 52 for 88E1512 56-pin QFN Figure 51: 88E1510 48-pin QFN Industrial Package Marking and Pin 1 Location Marvell Logo Country of Origin (Contained in the mold ID or marked as the last line on the package.) 88E1510-NNB2 Lot Number YYWW xx@ Country of Origin I Pin 1 location Temperature Code (I = Industrial) Part Number, Package Code, Environmental Code 88E1510 = Part Number NNB = Package Code 2 = Environmental Code (2 = RoHS 6/6 + Halogen-free (Green)) Date Code, Custom Code, Assembly Plant Code YYWW = Date Code (YY = Year, WW = Work Week) xx = Custom code/Die revision @ = Assembly plant code Note: The above drawing is not drawn to scale. Location of markings is approximate. Figure 52: 88E1512 56-pin QFN Industrial Package Marking and Pin 1 Location Marvell Logo Country of Origin (Contained in the mold ID or marked as the last line on the package.) 88E1512-NNP2 Lot Number YYWW xx@ Country of Origin I Pin 1 location Temperature Code (I = Industrial) Part Number, Package Code, Environmental Code 88E1512 = Part Number NNP = Package Code 2 = Environmental Code (2 = RoHS 6/6 + Halogen-free (Green)) Date Code, Custom Code, Assembly Plant Code YYWW = Date Code (YY = Year, WW = Work Week) xx = Custom code/Die revision @ = Assembly plant code Note: The above drawing is not drawn to scale. Location of markings is approximate. Doc. No. MV-S107146-U0 Rev. E Page 158 Copyright © 2021 Marvell Document Classification: Public June 3, 2021 Revision History A Table 179: Revision History Revision History R e v i s io n Date S e c t io n D et a il Rev. E May 5, 2021 Signal Description Added Table 29, I/O State at Various Test or Reset Modes Electrical Specifications Added Section 4.7.2, LED Pins Added Section 4.7.4, SGMII Interface Table 159, SGMII Output AC Characteristics Symbol TOutputJitter, Parameter removed the word “Tolerance”. Rev, D June 3, 2021 Datasheet release. March 9, 2021 Electrical Specifications Section 4.4, 88E1510/88E1518 Current Consumption, Section 4.5, 88E1512 Current Consumption, and Section 4.6, 88E1514 Current Consumption - changed all occurrences of “over” to “to”. Section 4.5, 88E1512 Current Consumption, Added RGMII details, and changed RGMII conditions from “...over with traffic” to “...at with traffic” Table 150, Digital Pins, added VIH = 3.3V and VDDO = 2.5V Max values, added IOH and IOL Rev. C Rev. B Rev. A April 2, 2021 Datasheet release. September 22, 2020 All applicable September 22, 2020 Datasheet release. February 23, 2018 All applicable Cosmetic enhancements Part Order Numbering/Package Marking Table 173: 88E1510/88E1518/88E1512/88E1514 Part Order Options: added part number for 88E1512 56-pin QFN Tape-and-Reel — Initial release January 4, 2018 Disclaimer updated Corporate rebranding and template update New Marvell logos added to all figures with Marvell logo marking Copyright © 2021 Marvell June 3, 2021 Doc. No. MV-S107146-U0 Rev. E Document Classification: Public Page 159 Contact Information Marvell first revolutionized the digital storage industry by moving information at speeds never thought possible. Today, that same breakthrough innovation remains at the heart of the company's storage, networking and connectivity solutions. With leading intellectual property and deep system-level knowledge, Marvell semiconductor solutions continue to transform the enterprise, cloud, automotive, industrial, and consumer markets. For more information, visit www.marvell.com. © 2021 Marvell. All rights reserved. The MARVELL mark and M logo are registered and/or common law trademarks of Marvell and/or its Affiliates in the US and/or other countries. This document may also contain other registered or common law trademarks of Marvell and/or its Affiliates. Doc. No. MV-S107146-U0 Rev. E Revised: June 3, 2021