LAN9218I High-Performance SingleChip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
PRODUCT FEATURES
Highlights
Optimized for the highest performance applications Efficient architecture with low CPU overhead Easily interfaces to most 32-bit and 16-bit embedded CPU’s Integrated PHY with HP Auto-MDIX Supports audio & video streaming over Ethernet: multiple high-definition (HD) MPEG2 streams Compatible with other members of LAN9218 family Reduced Power Modes
— — — — — — — — — — — — — — — — — — — — — — Numerous power management modes Wake on LAN* Magic packet wakeup* Wakeup indicator event signal Link Status Change Fully compliant with IEEE 802.3/802.3u standards Integrated Ethernet MAC and PHY 10BASE-T and 100BASE-TX support Full- and Half-duplex support Full-duplex flow control Backpressure for half-duplex flow control Preamble generation and removal Automatic 32-bit CRC generation and checking Automatic payload padding and pad removal Loop-back modes One 48-bit perfect address 64 hash-filtered multicast addresses Pass all multicast Promiscuous mode Inverse filtering Pass all incoming with status report Disable reception of broadcast packets
Datasheet
Single chip Ethernet controller
Target Applications
Video distribution systems, multi-room PVR Cable, satellite, and IP set-top boxes Digital video recorders and DVD recorder/players High definition televisions Digital media clients/servers and home gateways Video-over IP Solutions, IP PBX & video phones Wireless routers & access points High-end audio distribution systems
Flexible address filtering modes
Key Benefits
Non-PCI Ethernet controller for the highest performance applications
— Highest performing non-PCI Ethernet controller — 32-bit interface with fast bus cycle times — Burst-mode read support
Integrated 10/100 Ethernet PHY
— Supports HP Auto-MDIX — Auto-negotiation — Supports energy-detect power down
High-Performance host bus interface
— — — — — — — — — Simple, SRAM-like interface 32 or 16-bit data bus 16Kbyte FIFO with flexible TX/RX allocation One configurable host interrupt Low-profile, green, lead-free 100-pin TQFP package Integrated 1.8V regulator General Purpose Timer Optional EEPROM interface Support for 3 status LEDs multiplexed with Programmable GPIO signals
Eliminates dropped packets
— Internal buffer memory can store over 200 packets — Automatic PAUSE and back-pressure flow control
Minimizes CPU overhead
— Supports Slave-DMA — Interrupt Pin with Programmable Hold-off timer
Miscellaneous features
Reduces system cost and increases design flexibility SRAM-like interface easily interfaces to most embedded CPU’s or SoC’s
Single 3.3V Power Supply with 5V tolerant I/O -40 to 85°C
* Third-party brands and names are the property of their respective owners.
SMSC LAN9218I
DATASHEET
Revision 1.5 (07-18-06)
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
ORDER NUMBERS:
LAN9218I-MT FOR GREEN, LEAD-FREE, 100-PIN, TQFP PACKAGE WITH E3 FINISH (MATTE TIN) LAN9218I-MT-E2 FOR GREEN, LEAD-FREE, 100-PIN, TQFP PACKAGE WITH E2 FINISH (TIN-COPPER)
80 ARKAY DRIVE, HAUPPAUGE, NY 11788 (631) 435-6000, FAX (631) 273-3123 Copyright © 2006 SMSC or its subsidiaries. All rights reserved. Circuit diagrams and other information relating to SMSC products are included as a means of illustrating typical applications. Consequently, complete information sufficient for construction purposes is not necessarily given. Although the information has been checked and is believed to be accurate, no responsibility is assumed for inaccuracies. SMSC reserves the right to make changes to specifications and product descriptions at any time without notice. Contact your local SMSC sales office to obtain the latest specifications before placing your product order. The provision of this information does not convey to the purchaser of the described semiconductor devices any licenses under any patent rights or other intellectual property rights of SMSC or others. All sales are expressly conditional on your agreement to the terms and conditions of the most recently dated version of SMSC's standard Terms of Sale Agreement dated before the date of your order (the "Terms of Sale Agreement"). The product may contain design defects or errors known as anomalies which may cause the product's functions to deviate from published specifications. Anomaly sheets are available upon request. SMSC products are not designed, intended, authorized or warranted for use in any life support or other application where product failure could cause or contribute to personal injury or severe property damage. Any and all such uses without prior written approval of an Officer of SMSC and further testing and/or modification will be fully at the risk of the customer. Copies of this document or other SMSC literature, as well as the Terms of Sale Agreement, may be obtained by visiting SMSC’s website at http://www.smsc.com. SMSC is a registered trademark of Standard Microsystems Corporation (“SMSC”). Product names and company names are the trademarks of their respective holders. SMSC DISCLAIMS AND EXCLUDES ANY AND ALL WARRANTIES, INCLUDING WITHOUT LIMITATION ANY AND ALL IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, TITLE, AND AGAINST INFRINGEMENT AND THE LIKE, AND ANY AND ALL WARRANTIES ARISING FROM ANY COURSE OF DEALING OR USAGE OF TRADE. IN NO EVENT SHALL SMSC BE LIABLE FOR ANY DIRECT, INCIDENTAL, INDIRECT, SPECIAL, PUNITIVE, OR CONSEQUENTIAL DAMAGES; OR FOR LOST DATA, PROFITS, SAVINGS OR REVENUES OF ANY KIND; REGARDLESS OF THE FORM OF ACTION, WHETHER BASED ON CONTRACT; TORT; NEGLIGENCE OF SMSC OR OTHERS; STRICT LIABILITY; BREACH OF WARRANTY; OR OTHERWISE; WHETHER OR NOT ANY REMEDY OF BUYER IS HELD TO HAVE FAILED OF ITS ESSENTIAL PURPOSE, AND WHETHER OR NOT SMSC HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES.
Revision 1.5 (07-18-06)
DATASHEET
2
SMSC LAN9218I
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
Table of Contents
Chapter 1
1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 1.10 1.11
General Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
10 11 11 11 12 12 12 12 12 12 13
Compatibility with First-generation LAN9118 Family Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . Internal Block Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10/100 Ethernet PHY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10/100 Ethernet MAC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive and Transmit FIFOs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Interrupt Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GPIO Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Serial EEPROM Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Management Controls . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Purpose Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Host Bus Interface (SRAM Interface) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Chapter 2 Pin Description and Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
2.1 Buffer Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Chapter 3 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
3.1 3.2 10/100 Ethernet MAC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Flow Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.1 Full-Duplex Flow Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.2 Half-Duplex Flow Control (Backpressure) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.3 Virtual Local Area Network (VLAN) Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Address Filtering Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Filtering Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.4.1 Perfect Filtering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.4.2 Hash Only Filtering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wake-up Frame Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.5.1 Magic Packet Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Host Bus Operations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.6.1 32-bit vs. 16-bit Host Bus Width Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.6.2 16-bit Bus Writes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.6.3 16-bit Bus Reads . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Big and Little Endian Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Word Swap Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Purpose Timer (GP Timer) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . EEPROM Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.10.1 MAC Address Auto-Load . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.10.2 EEPROM Host Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.11.1 System Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.11.2 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.11.3 Internal PHY Power-Down modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Detailed Reset Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.12.1 Power-On Reset (POR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.12.2 Hardware Reset Input (nRESET) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.12.3 Resume Reset Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.12.4 Soft Reset (SRST) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.12.5 PHY Reset Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TX Data Path Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.13.1 TX Buffer Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.13.2 TX Command Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3
3.3 3.4 3.5 3.6
3.7 3.8 3.9 3.10 3.11
3.12
3.13
21 22 22 22 22 23 24 24 24 25 27 27 27 28 28 28 28 29 29 29 30 36 36 36 38 39 40 40 40 40 40 41 42 43
SMSC LAN9218I
DATASHEET
Revision 1.5 (07-18-06)
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
3.14
3.13.3 TX Data Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.13.4 TX Status Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.13.5 Calculating Actual TX Data FIFO Usage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.13.6 Transmit Examples . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.13.7 TX Data FIFO Underrun . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.13.8 Transmitter Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.13.9 Stopping and Starting the Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RX Data Path Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.14.1 RX Slave PIO Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.14.2 RX Packet Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.14.3 RX Status Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.14.4 Stopping and Starting the Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.14.5 Receiver Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
45 46 47 47 50 50 50 50 51 53 54 55 55
Chapter 4 Internal Ethernet PHY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
4.1 4.2 Top Level Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100Base-TX Transmit. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.1 4B/5B Encoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.2 Scrambling. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.3 NRZI and MLT3 Encoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.4 100M Transmit Driver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.5 100M Phase Lock Loop (PLL) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100Base-TX Receive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.1 100M Receive Input. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.2 Equalizer, Baseline Wander Correction and Clock and Data Recovery . . . . . . . . . . . . . 4.3.3 NRZI and MLT-3 Decoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.4 Descrambling. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.5 Alignment. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.6 5B/4B Decoding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10Base-T Transmit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.1 10M Transmit Data across the internal MII bus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.2 Manchester Encoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.3 10M Transmit Drivers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10Base-T Receive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.1 10M Receive Input and Squelch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.2 Manchester Decoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.3 Jabber Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Auto-negotiation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Parallel Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.7.1 Re-starting Auto-negotiation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.7.2 Disabling Auto-negotiation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.7.3 Half vs. Full-Duplex . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HP Auto-MDIX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 56 56 58 58 58 58 59 59 59 59 60 60 60 60 60 60 61 61 61 61 61 61 63 63 63 63 63
4.3
4.4
4.5
4.6 4.7
4.8
Chapter 5 Register Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
5.1 5.2 5.3 Register Nomenclature and Access Attributes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RX and TX FIFO Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.1 RX FIFO Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.2 TX FIFO Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . System Control and Status Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.3.1 ID_REV—Chip ID and Revision . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.3.2 IRQ_CFG—Interrupt Configuration Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.3.3 INT_STS—Interrupt Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.3.4 INT_EN—Interrupt Enable Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4
66 66 66 66 67 68 68 70 72
Revision 1.5 (07-18-06)
DATASHEET
SMSC LAN9218I
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
5.4
5.5
5.3.5 BYTE_TEST—Byte Order Test Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 5.3.6 FIFO_INT—FIFO Level Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 5.3.7 RX_CFG—Receive Configuration Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74 5.3.8 TX_CFG—Transmit Configuration Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75 5.3.9 HW_CFG—Hardware Configuration Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76 5.3.10 RX_DP_CTRL—Receive Datapath Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . 79 5.3.11 RX_FIFO_INF—Receive FIFO Information Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 5.3.12 TX_FIFO_INF—Transmit FIFO Information Register . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 5.3.13 PMT_CTRL— Power Management Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . 81 5.3.14 GPIO_CFG—General Purpose IO Configuration Register . . . . . . . . . . . . . . . . . . . . . . . 83 5.3.15 GPT_CFG-General Purpose Timer Configuration Register . . . . . . . . . . . . . . . . . . . . . . 84 5.3.16 GPT_CNT-General Purpose Timer Current Count Register . . . . . . . . . . . . . . . . . . . . . . 85 5.3.17 WORD SWAP—Word Swap Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 5.3.18 FREE_RUN—Free-Run 25MHz Counter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 5.3.19 RX_DROP– Receiver Dropped Frames Counter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 5.3.20 MAC_CSR_CMD – MAC CSR Synchronizer Command Register . . . . . . . . . . . . . . . . . 87 5.3.21 MAC_CSR_DATA – MAC CSR Synchronizer Data Register . . . . . . . . . . . . . . . . . . . . . 87 5.3.22 AFC_CFG – Automatic Flow Control Configuration Register . . . . . . . . . . . . . . . . . . . . . 88 5.3.23 E2P_CMD – EEPROM Command Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90 5.3.24 E2P_DATA – EEPROM Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 92 MAC Control and Status Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 5.4.1 MAC_CR—MAC Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 5.4.2 ADDRH—MAC Address High Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 5.4.3 ADDRL—MAC Address Low Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 5.4.4 HASHH—Multicast Hash Table High Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98 5.4.5 HASHL—Multicast Hash Table Low Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98 5.4.6 MII_ACC—MII Access Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 5.4.7 MII_DATA—MII Data Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 5.4.8 FLOW—Flow Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 5.4.9 VLAN1—VLAN1 Tag Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 5.4.10 VLAN2—VLAN2 Tag Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 5.4.11 WUFF—Wake-up Frame Filter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 5.4.12 WUCSR—Wake-up Control and Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 PHY Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 5.5.1 Basic Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 5.5.2 Basic Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 5.5.3 PHY Identifier 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 5.5.4 PHY Identifier 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 5.5.5 Auto-negotiation Advertisement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 5.5.6 Auto-negotiation Link Partner Ability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107 5.5.7 Auto-negotiation Expansion. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108 5.5.8 Mode Control/Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108 5.5.9 Special Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109 5.5.10 Special Control/Status Indications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110 5.5.11 Interrupt Source Flag . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 5.5.12 Interrupt Mask . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 5.5.13 PHY Special Control/Status. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
Chapter 6 Timing Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
6.1 6.2 6.3 6.4 Host Interface Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.1.1 Special Restrictions on Back-to-Back Write/Read Cycles . . . . . . . . . . . . . . . . . . . . . . . 6.1.2 Special Restrictions on Back-to-Back Read Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . PIO Reads . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PIO Burst Reads. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RX Data FIFO Direct PIO Reads . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113 113 115 116 117 118
SMSC LAN9218I
DATASHEET
5
Revision 1.5 (07-18-06)
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
6.5 6.6 6.7 6.8 6.9
RX Data FIFO Direct PIO Burst Reads. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PIO Writes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TX Data FIFO Direct PIO Writes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reset Timing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . EEPROM Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
119 120 122 123 124
Chapter 7 Operational Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125
7.1 7.2 7.3 7.4 7.5 Absolute Maximum Ratings*. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Consumption (Device Only). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Consumption (Device and System Components) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DC Electrical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Clock Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125 125 126 127 129
Chapter 8 Package Outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130
Revision 1.5 (07-18-06)
DATASHEET
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SMSC LAN9218I
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
List of Figures
Figure 1.1 Figure 1.2 Figure 2.1 Figure 3.1 Figure 3.2 Figure 3.3 Figure 3.4 Figure 3.5 Figure 3.6 Figure 3.7 Figure 3.8 Figure 3.9 Figure 3.10 Figure 3.11 Figure 3.12 Figure 3.13 Figure 3.14 Figure 3.15 Figure 3.16 Figure 3.17 Figure 4.1 Figure 4.2 Figure 4.3 Figure 5.1 Figure 5.2 Figure 6.1 Figure 6.2 Figure 6.3 Figure 6.4 Figure 6.5 Figure 6.6 Figure 6.7 Figure 8.1 System Block Diagram. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Internal Block Diagram. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Pin Configuration (Top View) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 VLAN Frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 EEPROM Access Flow Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 EEPROM ERASE Cycle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 EEPROM ERAL Cycle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 EEPROM EWDS Cycle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 EEPROM EWEN Cycle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 EEPROM READ Cycle. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 EEPROM WRITE Cycle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 EEPROM WRAL Cycle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 PME and PME_INT Signal Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 Simplified Host TX Flow Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 TX Buffer Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 TX Example 1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48 TX Example 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49 Host Receive Routine Using Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 Host Receive Routine with Polling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 RX Packet Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 100Base-TX Data Path . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 Receive Data Path . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 Direct cable connection vs. Cross-over cable connection.. . . . . . . . . . . . . . . . . . . . . . . . . . . 64 Memory Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65 Example ADDRL, ADDRH and EEPROM Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 PIO Read Cycle Timing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116 PIO Burst Read Cycle Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 RX Data FIFO Direct PIO Read Cycle Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118 RX Data FIFO Direct PIO Burst Read Cycle Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 PIO Write Cycle Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120 TX Data FIFO Direct PIO Write Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122 EEPROM Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124 100 Pin TQFP Package Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130
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Revision 1.5 (07-18-06)
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
List of Tables
Table 2.1 Host Bus Interface Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Table 2.2 Default Ethernet Settings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Table 2.3 LAN Interface Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Table 2.4 Serial EEPROM Interface Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Table 2.5 System and Power Signals (continued). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Table 2.6 Buffer Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Table 3.1 Address Filtering Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Table 3.2 Wake-Up Frame Filter Register Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Table 3.3 Filter i Byte Mask Bit Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Table 3.4 Filter i Command Bit Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Table 3.5 Filter i Offset Bit Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Table 3.6 Filter i CRC-16 Bit Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Table 3.7 Word Swap Control (16-bit mode only) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 Table 3.8 Required EECLK Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Table 3.9 Power Management States . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 Table 3.10 PHY Reset Sources and Effected Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 Table 3.11 TX Command 'A' Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44 Table 3.12 TX Command 'B' Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 Table 3.13 TX DATA Start Offset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 Table 4.1 4B/5B Code Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 Table 5.1 Direct Address Register Map. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67 Table 5.2 RX Alignment Bit Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74 Table 5.3 Valid TX/RX FIFO Allocations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 Table 5.4 EEPROM Enable Bit Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84 Table 5.5 Backpressure Duration Bit Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89 Table 5.6 MAC CSR Register Map. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 Table 5.7 ADDRL, ADDRH and EEPROM Byte Ordering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 Table 5.8 LAN9218I PHY Control and Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 Table 5.9 MODE Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109 Table 6.1 Read After Write Timing Rules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113 Table 6.2 Read After Read Timing Rules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115 Table 6.3 PIO Read Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116 Table 6.4 PIO Burst Read Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 Table 6.5 RX Data FIFO Direct PIO Read Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118 Table 6.6 RX Data FIFO Direct PIO Burst Read Cycle Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 Table 6.7 PIO Write Cycle Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120 Table 6.8 TX Data FIFO Direct PIO Write Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122 Table 6.9 Reset Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123 Table 6.10 EEPROM Timing Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124 Table 7.1 Power Consumption Device Only . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125 Table 7.2 Power Consumption Device and System Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 Table 7.3 Supply Current Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127 Table 7.4 I/O Buffer Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127 Table 7.5 100BASE-TX Transceiver Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128 Table 7.6 10BASE-T Transceiver Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129 Table 7.7 Crystal Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129 Table 8.1 100 Pin TQFP Package Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130
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SMSC LAN9218I
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
Chapter 1 General Description
The LAN9218I is a full-featured, single-chip 10/100 Ethernet controller designed for embedded applications where performance, flexibility, ease of integration and system cost control are required. The LAN9218I has been specifically architected to provide the highest performance possible for any given architecture. The LAN9218I is fully IEEE 802.3 10BASE-T and 802.3u 100BASE-TX compliant, and supports HP Auto-MDIX. The LAN9218I includes an integrated Ethernet MAC and PHY with a high-performance SRAM-like slave interface. The simple, yet highly functional host bus interface provides a glue-less connection to most common 16-bit and 32-bit microprocessors and microcontrollers . The LAN9218I includes large transmit and receive data FIFOs with a high-speed host bus interface to accommodate high bandwidth, high latency applications. In addition, the LAN9218I memory buffer architecture allows the most efficient use of memory resources by optimizing packet granularity. Applications The LAN9218I is well suited for many high performance embedded applications, including: High-end cable, satellite and IP set-top boxes Video distribution systems Multi-room PVR (Personal Video Recorder) Digital video recorders High-definition televisions Digital media clients/servers Home gateways The LAN9218I also supports features which reduce or eliminate packet loss. Its internal 16-KByte SRAM can hold over 200 received packets. If the receive FIFO gets too full, the LAN9218I can automatically generate flow control packets to the remote node, or assert back-pressure on the remote node by generating network collisions. The LAN9218I supports numerous power management and wakeup features. The LAN9218I can be placed in a reduced power mode and can be programmed to issue an external wake signal via several methods, including “Magic Packet”, “Wake on LAN” and “Link Status Change”. This signal is ideal for triggering system power-up using remote Ethernet wakeup events. The device can be removed from the low power state via a host processor command.
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.
System Memory
System Memory System Peripherals
Microprocessor/ Microcontroller
Magnetics
System Bus
Ethernet
LAN9218I
LEDS/GPIO
25MHz XTAL
EEPROM (Optional)
Figure 1.1 System Block Diagram
The SMSC LAN9218I integrated 10/100 MAC/PHY controller is a peripheral chip that performs the function of translating parallel data from a host controller into Ethernet packets. The LAN9218I Ethernet MAC/PHY controller is designed and optimized to function in an embedded environment. All communication is performed with programmed I/O transactions using the simple SRAM-like host interface bus. The diagram shown above, describes a typical system configuration of the LAN9218I in a typical embedded environment. The LAN9218I is a general purpose, platform independent, Ethernet controller. The LAN9218I consists of four major functional blocks. The four blocks are: 10/100 Ethernet PHY 10/100 Ethernet MAC RX/TX FIFOs Host Bus Interface (HBI)
1.1
Compatibility with First-generation LAN9118 Family Devices
The LAN9218I is driver-, register-, and footprint-compatible with previous generation LAN9118 Family devices. Drivers written for these products will work with the LAN9218I. However, in order to support HP Auto-MDIX, other components such as the magnetics and the passive components around the magnetics need to change, and supporting these changes does require a minor PCB change. A reference design for the LAN9218I will be available on SMSC’s website.
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High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
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1.2
Internal Block Overview
This section provides an overview of each of these functional blocks as shown in Figure 1.2, "Internal Block Diagram".
25MHz +3.3V EEPROM (Optional)
PME Wakup Indicator
Power Management
3.3V to 1.8V Regulator
PLL
EEPROM Controller
Host Bus Interface (HBI)
2kB to 14kB Configurable TX FIFO TX Status FIFO
SRAM I/F
PIO Controller
RX Status FIFO
IRQ FIFO_SEL
Interrupt Controller GP Timer
10/100 Ethernet MAC
MIL - RX Elastic Buffer - 128 bytes MIL - TX Elastic Buffer - 2K bytes
10/100 Ethernet PHY
LAN
2kB to 14kB Configurable RX FIFO
Figure 1.2 Internal Block Diagram
1.3
10/100 Ethernet PHY
The LAN9218I integrates an IEEE 802.3 physical layer for twisted pair Ethernet applications. The PHY can be configured for either 100 Mbps (100Base-TX) or 10 Mbps (10Base-T) Ethernet operation in either full or half duplex configurations. The PHY block supports HP Auto-MDIX and auto-negotiation. Minimal external components are required for the utilization of the Integrated PHY.
1.4
10/100 Ethernet MAC
The transmit and receive data paths are separate within the MAC allowing the highest performance especially in full duplex mode. The data paths connect to the PIO interface Function via separate busses to increase performance. Payload data as well as transmit and receive status is passed on these busses. A third internal bus is used to access the MAC’s Control and Status Registers (CSR’s). This bus is accessible from the host through the PIO interface function. On the backend, the MAC interfaces with the internal 10/100 PHY through a the MII (Media Independent Interface) port internal to the LAN9218I. The MAC CSR's also provides a mechanism for accessing the PHY’s internal registers through the internal SMI (Serial Management Interface) bus.
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The MAC Interface Layer (MIL), within the MAC, contains a 2K Byte transmit and a 128 Byte receive FIFO which is separate from the TX and RX FIFOs. The FIFOs within the MAC are not directly accessible from the host interface. The differentiation between the TX/RX FIFO memory buffers and the MAC buffers is that when the transmit or receive packets are in the MAC buffers, the host no longer can control or access the TX or RX data. The MAC buffers (both TX and RX) are in effect the working buffers of the Ethernet MAC logic. In the case of reception, the data must be moved first to the RX FIFOs for the host to access the data.
1.5
Receive and Transmit FIFOs
The Receive and Transmit FIFOs allow increased packet buffer storage to the MAC. The FIFOs are a conduit between the host interface and the MAC through which all transmitted and received data and status information is passed. Deep FIFOs allow a high degree of latency tolerance relative to the various transport and OS software stacks thus reducing or minimizing overrun conditions. Like the MAC, the FIFOs have separate receive and transmit data paths. In addition, the RX and TX FIFOs are configurable in size, allowing increased flexibility.
1.6
Interrupt Controller
The LAN9218I supports a single programmable interrupt. The programmable nature of this interrupt allows the user the ability to optimize performance dependent upon the application requirement. Both the polarity and buffer type of the interrupt pin are configurable for the external interrupt processing. The interrupt line can be configured as an open-drain output to facilitate the sharing of interrupts with other devices. In addition, a programmable interrupt de-assertion interval is provided.
1.7
GPIO Interface
A 3-bit GPIO and 2-bit GPO (Multiplexed on the EEPROM and LED Pins) interface is included in the LAN9218I. It is accessible through the host bus interface via the CSRs. The GPIO signals can function as inputs, push-pull outputs and open drain outputs. The GPIO’s (GPO’s are not configurable) can also be configured to trigger interrupts with programmable polarity.
1.8
Serial EEPROM Interface
A serial EEPROM interface is included in the LAN9218I. The serial EEPROM is optional and can be programmed with the LAN9218I MAC address. The LAN9218I can optionally load the MAC address automatically after power-on.
1.9
Power Management Controls
The LAN9218I supports comprehensive array of power management modes to allow use in power sensitive applications. Wake on LAN, Link Status Change and Magic Packet detection are supported by the LAN9218I. An external PME (Power Management Event) interrupt is provided to indicate detection of a wakeup event.
1.10
General Purpose Timer
The general-purpose timer has no dedicated function within the LAN9218I and may be programmed to issue a timed interrupt.
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High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
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1.11
Host Bus Interface (SRAM Interface)
The host bus interface provides a FIFO interface for the transmit and receive data paths, as well as an interface for the LAN9218I Control and Status Registers (CSR’s). The host bus interface is the primary bus for connection to the embedded host system. This interface models an asynchronous SRAM. TX FIFO, RX FIFO, and CSR’s are accessed through this interface. Programmed I/O transactions are supported. The LAN9218I host bus interface supports 32-bit and 16-bit bus transfers; internally, all data paths are 32-bits wide. The LAN9218I can be interfaced to either Big-Endian or Little-Endian processors.
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Chapter 2 Pin Description and Configuration
SPEED_SEL
GND_CORE
VDD_CORE
AMDIX_EN
EECLK**
EEDIO**
GND_IO
GND_IO
VDD_IO
VDD_IO
EECS
PME
IRQ
NC
NC
D0
D1
D2
D3
D4
D5
D6
D7 53
D8 52
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
F IF O _S E L V S S _A (N o te 1) T P O (N o te 1) T P O + V S S _A V D D _A (N o te 1) T P I (N o te 1) T P I+ NC V D D _A V S S _A EXRES1 V S S _A V D D _A NC NC nRD nW R nCS nRESET G N D _IO V D D _IO G P IO 0/n L E D 1** G P IO 1/n L E D 2** G P IO 2/n L E D 3**
76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 1 2 3 4 5 6 7 8 9
51 50 49 48 47 46 45 44
D9
D 10 D 11 V D D _IO G N D _IO D 12 D 13 D 14 D 15 V D D _IO G N D _IO D 16 D 17 D 18 D 19 D 20 V D D _IO G N D _IO D 21 D 22 D 23 D 24 D 25 V D D _IO G N D _IO D 26
SMSC L A N 9218I
100 P IN T Q F P
43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 D27
XTAL2
XTAL1
A7
A6
A5
A4
A3
A2
A1
D31
D30
D29
VDD_CORE
RBIAS
GND_CORE
GND_IO
VREG
VDD_PLL
**D E N O T E S A M U L T IF U N C T O N P IN N O T E 1: W h en H P A u to -M D IX is ac tiv ated , th e T P O +/- p in s fu nc tion as TP I+/- a nd v ic e-ve rsa.
Figure 2.1 Pin Configuration (Top View)
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VSS_REF
VSS_PLL
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VDD_IO
ATEST
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SMSC LAN9218I
High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
Table 2.1 Host Bus Interface Signals BUFFER TYPE I/O8 (PD) # PINS 16
PIN NO. 21-26,2933,36-40 43-46,4953,56-59,6264 12-18 92 93
NAME Host Data High
SYMBOL D[31:16]
DESCRIPTION Bi-directional data port. Note that Pull-down’s are disabled in 32 bit mode. Bi-directional data port. Supports Big/Little Endian Byte ordering. 7-bit Address Port. Used to select Internal CSR’s and TX and RX FIFOs. Active low strobe to indicate a read cycle. Active low strobe to indicate a write cycle. This signal, qualified with nCS, is also used to wakeup the LAN9218I when it is in a reduced power state. Active low signal used to qualify read and write operations. This signal qualified with nWR is also used to wakeup the LAN9218I when it is in a reduced power state. Programmable Interrupt request. Programmable polarity, source and buffer types. No Connect Enables Auto-MDIX. Pull high to enable Auto-MDIX, pull low or leave unconnected to disable Auto-MDIX. This signal functions as a configuration input on power-up and is used to select the default Ethernet settings. Upon deassertion of reset, the value of the input is latched. This signal functions as shown in Table 2.2, "Default Ethernet Settings", below. When driven high all accesses to the LAN9218I are to the RX or TX Data FIFOs. In this mode, the A[7:3] upper address inputs are ignored.
Host DataLow
D[15:0]
I/O8
16
Host Address Read Strobe Write Strobe
A[7:1] nRD nWR
IS IS IS
7 1 1
94
Chip Select
nCS
IS
1
72
Interrupt Request Reserved AutoMDIX Enable 10/100 Selector
IRQ
O8/OD8
1
71,75,84,90, 91 73
Reserved AMDIX_EN I (PD)
5 1
74
SPEED_SEL
I (PU)
1
76
FIFO Select
FIFO_SEL
IS
1
Table 2.2 Default Ethernet Settings DEFAULT ETHERNET SETTINGS SPEED_SEL 0 1 SPEED 10Mbps 100Mbps DUPLEX Half-Duplex Half-Duplex AUTO NEG. Disabled Enabled
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Table 2.3 LAN Interface Signals PIN NO. 79 78 83 82 87 BUFFER TYPE AO AO AI AI AI NUM PINS 1 1 1 1 1
NAME TPO+ TPOTPI+ TPIPHY External Bias Resistor
SYMBOL TPO+ TPOTPI+ TPIEXRES1
DESCRIPTION Transmit Positive Output (normal) Receive Positive Input (reversed) Transmit Negative Output (normal) Receive Negative Input (reversed) Receive Positive Input (normal) Transmit Positive Input (reversed) Receive Negative Input (normal) Transmit Negative Output (reversed) Must be connected to ground through a 12.4K ohm 1% resistor.
Note: The pin names for the twisted pair pins shown above apply to a normal connection. If HP AutoMDIX is enabled and a reverse connection is detected, or a reverse connection is manually selected, the input pins become outputs, and vice-versa, as indicated in the descriptions. Table 2.4 Serial EEPROM Interface Signals PIN NO. 67 BUFFER TYPE I/O8 NUM PINS 1
NAME EEPROM Data, GPO3, TX_EN, TX_CLK, D32/nD16
SYMBOL EEDIO/GPO3/ TX_EN/TX_CLK
DESCRIPTION EEPROM Data: This bi-directional pin can be connected to a serial EEPROM DIO. This is optional. General Purpose Output 3: This pin can also function as a general purpose output, or it can be configured to monitor the TX_EN or TX_CLK signals on the internal MII port. When configured as a GPO signal, or as a TX_EN/TX_CLK monitor, the EECS pin is deasserted so as to never unintentionally access the serial EEPROM. This signal cannot function as a generalpurpose input. Data Bus Width Select: This signal also functions as a configuration input on power-up and is used to select the host bus data width. Upon deassertion of reset, the value of the input is latched. When high, a 32-bit data bus is utilized. When low, a 16bit interface is utilized.
(D32/nD16)
68
EEPROM Chip Select
EECS
O8
1
Serial EEPROM chip select.
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High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
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Table 2.4 Serial EEPROM Interface Signals PIN NO. 69 BUFFER TYPE O8 NUM PINS 1
NAME EEPROM Clock, GPO4 RX_DV, RX_CLK
SYMBOL EECLK/GPO4/ RX_DV/RX_CLK
DESCRIPTION EEPROM Clock: Serial EEPROM Clock pin. General Purpose Output 4: This pin can also function as a generalpurpose output, or it can be configured to monitor the RX_DV or RX_CLK signals on the internal MII port. When configured as a GPO signal, or as an RX_DV/RX_CLK monitor, the EECS pin is deasserted so as to never unintentionally access the serial EEPROM. This signal cannot function as a generalpurpose input.
Table 2.5 System and Power Signals (continued) PIN NO. 6 BUFFER TYPE lclk NUM PINS 1
NAME Crystal 1
SYMBOL XTAL1
DESCRIPTION External 25MHz Crystal Input. Can also be connected to singleended TTL oscillator. If this method is implemented, XTAL2 should be left unconnected. External 25MHz Crystal output.
5 95
Crystal 2 Reset
XTAL2 nRESET
Oclk IS (PU)
1 1
Active-low reset input. Resets all logic and registers within the LAN9218I. This signal is pulled high with a weak internal pull-up resistor. If nRESET is left unconnected, the LAN9218I will rely on its internal power-on reset circuitry
Note: The LAN9218I must always be read at least once after power-up, reset, or upon return from a power-saving state or write operations will not function. See Section 3.12, "Detailed Reset Description," on page 39 for additional information
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Table 2.5 System and Power Signals (continued) PIN NO. 70 BUFFER TYPE O8/OD8 NUM PINS 1
NAME Wakeup Indicator
SYMBOL PME
DESCRIPTION When programmed to do so, is asserted when the LAN9218I detects a wake event and is requesting the system to wake up from the associated sleep state. The polarity and buffer type of this signal is programmable. Note: Detection of a Power Management Event, and assertion of the PME signal will not wakeup the LAN9218I. The LAN9218I will only wake up when it detects a host write cycle (assertion of nCS and nWR). Although any write to the LAN9218I, regardless of the data written, will wakeup the device when it is in a power-saving mode, it is required that the BYTE_TEST register be used for this purpose.
100,99 ,98
General Purpose I/O data, nLED1 (Speed Indicator), nLED2 (Link & Activity Indicator),
GPIO[2:0]/ LED[3:1]
IS/O12/ OD12
3
nLED3 (FullDuplex Indicator).
General Purpose I/O data: These three general-purpose signals are fully programmable as either pushpull output, open-drain output or input by writing the GPIO_CFG configuration register in the CSR’s. They are also multiplexed as GP LED connections. GPIO signals are Schmitt-triggered inputs. When configured as LED outputs these signals are open-drain. nLED1 (Speed Indicator). This signal is driven low when the operating speed is 100Mbs, during auto-negotiation and when the cable is disconnected. This signal is driven high only during 10Mbs operation. nLED2 (Link & Activity Indicator). This signal is driven low (LED on) when the LAN9218I detects a valid link. This signal is pulsed high (LED off) for 80mS whenever transmit or receive activity is detected. This signal is then driven low again for a minimum of 80mS, after which time it will repeat the process if TX or RX activity is detected. Effectively, LED2 is activated solid for a link. When transmit or receive activity is sensed LED2 will flash as an activity indicator. nLED3 (Full-Duplex Indicator). This signal is driven low when the link is operating in full-duplex mode.
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High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
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Table 2.5 System and Power Signals (continued) PIN NO. BUFFER TYPE NUM PINS
NAME
SYMBOL
DESCRIPTION PLL Bias: Connect to an external 12.0K ohm 1.0% resistor to ground. Used for the PLL Bias circuit. This pin must be connected to VDD for normal operation. 3.3V input for internal voltage regulator +3.3V I/O logic power supply pins
10
RBIAS
RBIAS
AI
1
9
2 20,28, 35, 42,48, 55,61, 97 19,27, 34,41, 47,54, 60,96 81,85, 89 77,80, 86,88 3,65
Test Pin
Internal Regulator Power +3.3V I/O Power
ATEST
VREG VDD_IO
I
P P
1
1 8
I/O Ground
GND_IO
P
8
Ground for I/O pins
+3.3V Analog Power Analog Ground Core Voltage Decoupling
VDD_A VSS_A VDD_CORE
P P P
3 4 2
+3.3V Analog power supply pins. See Note 2.1 Ground for analog circuitry 1.8 V from internal core regulator. Both pins must be connected together externally and then tied to a 10uF 0.1-Ohm ESR capacitor, in parallel with a 0.01uF capacitor to Ground next to each pin. See Note 2.1 Ground for internal digital logic 1.8V Power from the internal PLL regulator. This external pin must be connected to a 10uF 0.1-Ohm ESR capacitor, in parallel with a 0.01uF capacitor to Ground. See Note 2.1 GND for the PLL Connected to 3.3v power and used as the reference voltage for the internal PLL Ground for internal PLL reference voltage
1,66 7
Core Ground PLL Power
GND_CORE VDD_PLL
P P
2 1
4 8
PLL Ground Reference Power
VSS_PLL VDD_REF
P P
1 1
11
Reference Ground Note 2.1
VSS_REF
P
1
Please refer to the SMSC application note AN 12.5x, entitled "Designing with the LAN9218 Family - Getting Started". It is also important to note that this application note applies to the whole SMSC LAN9118 family of Ethernet controllers. However, subtle differences may apply.
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2.1
Buffer Types
Table 2.6 Buffer Types TYPE I IS O12 OD12 IO8 OD8 O8 PU PD AI AO AIO ICLK OCLK Input pin Schmitt triggered Input Output with 12mA sink and 12mA source Open-drain output with 12mA sink I/O with 8mA symmetrical drive Open-drain output with 8mA sink Output 8mA symmetrical drive 30uA internal pull-up 30uA internal pull-down Analog input Analog output Analog bi-directional Crystal oscillator input pin Crystal oscillator output pin DESCRIPTION
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Chapter 3 Functional Description
3.1 10/100 Ethernet MAC
The Ethernet Media Access controller (MAC) incorporates the essential protocol requirements for operating an Ethernet/IEEE 802.3-compliant node and provides an interface between the host subsystem and the internal Ethernet PHY. The MAC can operate in either 100-Mbps or 10-Mbps mode. The MAC operates in both half-duplex and full-duplex modes. When operating in half-duplex mode, the MAC complies fully with Section 4 of ISO/IEC 8802-3 (ANSI/IEEE standard) and ANSI/IEEE 802.3 standards. When operating in full-duplex mode, the MAC complies with IEEE 802.3x full-duplex operation standard. The MAC provides programmable enhanced features designed to minimize host supervision, bus utilization, and pre- or post-message processing. These features include the ability to disable retries after a collision, dynamic FCS (Frame Check Sequence) generation on a frame-by-frame basis, automatic pad field insertion and deletion to enforce minimum frame size attributes, and automatic retransmission and detection of collision frames. The MAC can sustain transmission or reception of minimally-sized back-to-back packets at full line speed with an interpacket gap (IPG) of 9.6 microseconds for 10 Mbps and 0.96 microseconds for 100 Mbps. The primary attributes of the MAC Function are: Transmit and receive message data encapsulation Framing (frame boundary delimitation, frame synchronization) Error detection (physical medium transmission errors) Media access management Medium allocation (collision detection, except in full-duplex operation) Contention resolution (collision handling, except in full-duplex operation) Flow control during full-duplex mode Decoding of control frames (PAUSE command) and disabling the transmitter Generation of control frames Interface to the internal PHY. The transmit and receive data paths are separate within the LAN9218I from the MAC to host interface allowing the highest performance, especially in full duplex mode. Payload data as well as transmit and receive status are passed on these busses. A third internal bus is used to access the MAC’s “Control and Status Registers” (CSR’s). This bus is also accessible from the host. On the backend, the MAC interfaces with the 10/100 PHY through anMII (Media Independent Interface) port which is internal to the LAN9218I. The MAC CSR's also provide a mechanism for accessing the PHY’s internal registers through the internal SMI (Serial Management Interface) bus. The receive and transmit FIFOs allow increased packet buffer storage to the MAC. The FIFOs are a conduit between the host interface and the MAC through which all transmitted and received data and status information is passed. Deep FIFOs allow a high degree of latency tolerance relative to the various transport and OS software stacks reducing and minimizing overrun conditions. Like the MAC, the FIFOs have separate receive and transmit data paths. The LAN9218I can store up to 250 Ethernet packets utilizing FIFOs, totaling 16K bytes, with a packet granularity of 4 bytes. This memory is shared by the RX and TX blocks and is configurable in terms of allocation. This depth of buffer storage minimizes or eliminates receive overruns.
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3.2
Flow Control
The LAN9218I Ethernet MAC supports full-duplex flow control using the pause operation and control frame. It also supports half-duplex flow control using back pressure.
3.2.1
Full-Duplex Flow Control
The pause operation inhibits data transmission of data frames for a specified period of time. A Pause operation consists of a frame containing the globally assigned multicast address (01-80-C2-00-00-01), the PAUSE opcode, and a parameter indicating the quantum of slot time (512 bit times) to inhibit data transmissions. The PAUSE parameter may range from 0 to 65,535 slot times. The Ethernet MAC logic, on receiving a frame with the reserved multicast address and PAUSE opcode, inhibits data frame transmissions for the length of time indicated. If a Pause request is received while a transmission is in progress, then the pause will take effect after the transmission is complete. Control frames are received and processed by the MAC and are passed on. The MAC also transmits control frames (pause command) via both hardware and software control. The software driver requests the MAC to transmit a control frame and gives the value of the PAUSE time to be used in the control frame. The MAC Function constructs a control frame with the appropriate values set in all the different fields (as defined in the 802.3x specification) and transmits the frame to the MII interface. The transmission of the control frame is not affected by the current state of the Pause timer value that is set because of a recently received control frame.
3.2.2
Half-Duplex Flow Control (Backpressure)
In half-duplex mode, back pressure is used for flow control. Whenever the receive buffer/FIFO becomes full or crosses a certain threshold level, the MAC starts sending a Jam signal. The MAC transmit logic enters a state at the end of current transmission (if any), where it waits for the beginning of a received frame. Once a new frame starts, the MAC starts sending the Jam signal, which will result in a collision. After sensing the collision, the remote station will back off its transmission. The MAC continues sending the jam to make other stations defer transmission. The MAC only generates this collision-based back pressure when it receives a new frame, in order to avoid any late collisions.
3.2.3
Virtual Local Area Network (VLAN) Support
Virtual Local Area Networks or VLANs, as defined within the IEEE 802.3 standard, provide network administrators one means of grouping nodes within a larger network into broadcast domains. To implement a VLAN, four extra bytes are added to the basic Ethernet packet. As shown in Figure 3.1, "VLAN Frame", the four bytes are inserted after the Source Address Field and before the Type/Length field. The first two bytes of the VLAN tag identify the tag, and by convention are set to the value 0x8100. The last two bytes identify the specific VLAN associated with the packet; they also provide a priority field. The LAN9218I supports VLAN-tagged packets. The LAN9218I provides two registers which are used to identify VLAN-tagged packets. One register should normally be set to the conventional VLAN ID of 0x8100. The other register provides a way of identifying VLAN frames tagged with a proprietary (not 0x8100) identifier. If a packet arrives bearing either of these tags in the two bytes succeeding the Source Address field, the controller will recognize the packet as a VLAN-tagged packet. In this case, the controller increases the maximum allowed packet size from 1518 to 1522 bytes (normally the controller filters packets larger than 1518 bytes). This allows the packet to be received, and then processed by host software, or to be transmitted on the network.
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Figure 3.1 VLAN Frame
3.3
Address Filtering Functional Description
The Ethernet address fields of an Ethernet Packet, consists of two 6-byte fields: one for the destination address and one for the source address. The first bit of the destination address signifies whether it is a physical address or a multicast address. The LAN9218I address check logic filters the frame based on the Ethernet receive filter mode that has been enabled. Filter modes are specified based on the state of the control bits in Table 3.1, "Address Filtering Modes", which shows the various filtering modes used by the Ethernet MAC Function. These bits are defined in more detail in the “MAC Control Register”. Please refer to Section 5.4.1, "MAC_CR—MAC Control Register," on page 94 for more information on this register. If the frame fails the filter, the Ethernet MAC function does not receive the packet. The host has the option of accepting or ignoring the packet. Table 3.1 Address Filtering Modes
MCPAS 0 0
PRMS 0 0
INVFILT 0 0
HO 0 0
HPFILT 0 1
DESCRIPTION MAC address perfect filtering only for all addresses. MAC address perfect filtering for physical address and hash filtering for multicast addresses
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Table 3.1 Address Filtering Modes (continued) MCPAS 0 0 X 1 PRMS 0 0 1 0 INVFILT 0 1 0 0 HO 1 0 X 0 HPFILT 1 0 X X DESCRIPTION Hash Filtering for physical and multicast addresses Inverse Filtering Promiscuous Pass all multicast frames. Frames with physical addresses are perfect-filtered Pass all multicast frames. Frames with physical addresses are hashfiltered
1
0
0
1
1
3.4
3.4.1
Filtering Modes
Perfect Filtering
This filtering mode passes only incoming frames whose destination address field exactly matches the value programmed into the MAC Address High register and the MAC address low register. The MAC address is formed by the concatenation of the above two registers in the MAC CSR Function.
3.4.2
Hash Only Filtering
This type of filtering checks for incoming Receive packets with either multicast or physical destination addresses, and executes an imperfect address filtering against the hash table. During imperfect hash filtering, the destination address in the incoming frame is passed through the CRC logic and the upper six bits of the CRC register are used to index the contents of the hash table. The hash table is formed by merging the register’s multicast hash table high and multicast hash table low in the MAC CSR Function to form a 64-bit hash table. The most significant bit determines the register to be used (High/Low), while the other five bits determine the bit within the register. A value of 00000 selects Bit 0 of the multicast hash table low register and a value of 11111 selects Bit 31 of the multicast hash table high register.
3.4.2.1
Hash Perfect Filtering
In hash perfect filtering, if the received frame is a physical address, the LAN9218I Packet Filter block perfect-filters the incoming frame’s destination field with the value programmed into the MAC Address High register and the MAC Address Low register. If the incoming frame is a multicast frame, however, the LAN9218I packet filter function performs an imperfect address filtering against the hash table. The imperfect filtering against the hash table is the same imperfect filtering process described in the “Hash Only Filtering” section above.
3.4.2.2
Inverse Filtering
In inverse filtering, the Packet Filter Block accepts incoming frames with a destination address not matching the perfect address (i.e., the value programmed into the MAC Address High register and the MAC Address Low register in the CRC block and rejects frames with destination addresses matching the perfect address. For all filtering modes, when MCPAS is set, all multicast frames are accepted. When the PRMS bit is set, all frames are accepted regardless of their destination address. This includes all broadcast frames as well.
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3.5
Wake-up Frame Detection
Setting the Wake-Up Frame Enable bit (WUEN) in the “WUCSR—Wake-up Control and Status Register”, places the LAN9218I MAC in the wake-up frame detection mode. In this mode, normal data reception is disabled, and detection logic within the MAC examines receive data for the preprogrammed wake-up frame patterns. The LAN9218I can be programmed to notify the host of the wake-up frame detection with the assertion of the host interrupt (IRQ) or assertion of the power management event signal (PME). Upon detection, the Wake-Up Frame Received bit (WUFR) in the WUCSR is set. When the host clears the WUEN bit the LAN9218I will resume normal receive operation. Before putting the MAC into the wake-up frame detection state, the host must provide the detection logic with a list of sample frames and their corresponding byte masks. This information is written into the Wake-up Frame Filter register (WUFF). Please refer to Section 5.4.11, "WUFF—Wake-up Frame Filter," on page 102 for additional information on this register. The MAC supports four programmable filters that support many different receive packet patterns. If remote wake-up mode is enabled, the remote wake-up function receives all frames addressed to the MAC. It then checks each frame against the enabled filter and recognizes the frame as a remote wakeup frame if it passes the wakeup frame filter register’s address filtering and CRC value match. In order to determine which bytes of the frames should be checked by the CRC module, the MAC uses a programmable byte mask and a programmable pattern offset for each of the four supported filters. The pattern’s offset defines the location of the first byte that should be checked in the frame. Since the destination address is checked by the address filtering Function, the pattern offset is always greater than 12. The byte mask is a 31-bit field that specifies whether or not each of the 31 contiguous bytes within the frame, beginning in the pattern offset, should be checked. If bit j in the byte mask is set, the detection logic checks byte offset +j in the frame. In order to load the Wake-up Frame Filter register, the host LAN driver software must perform eight writes to the Wake-up Frame Filter register (WUFF). The Diagram shown in Table 3.2, "Wake-Up Frame Filter Register Structure" below, shows the wakeup frame filter register’s structure. Note 3.1 Note 3.2 Wake-up frame detection can be performed when the LAN9218I is in the D0 or D1 power states. In the D0 state, wake-up frame detection is enabled when the WUEN bit is set. Wake-up frame detection, as well as Magic Packet detection, is always enabled and cannot be disabled when the device enters the D1 state.
Table 3.2 Wake-Up Frame Filter Register Structure Filter 0 Byte Mask Filter 1 Byte Mask Filter 2 Byte Mask Filter 3 Byte Mask Reserved Filter 3 Command Reserved Filter 2 Command Reserved Filter 1 Command Reserved Filter 0 Command
Filter 3 Offset
Filter 2 Offset
Filter 1Offset
Filter 0 Offset Filter 0 CRC-16 Filter 2 CRC-16
Filter 1 CRC-16 Filter 3 CRC-16
The Filter i Byte Mask defines which incoming frame bytes Filter i will examine to determine whether or not this is a wake-up frame. Table 3.3, describes the byte mask’s bit fields.
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Table 3.3 Filter i Byte Mask Bit Definitions FILTER I BYTE MASK DESCRIPTION FIELD 31 30:0 DESCRIPTION Must be zero (0) Byte Mask: If bit j of the byte mask is set, the CRC machine processes byte number pattern - (offset + j) of the incoming frame. Otherwise, byte pattern - (offset + j) is ignored. The Filter i command register controls Filter i operation. Table 3.4 shows the Filter I command register. Table 3.4 Filter i Command Bit Definitions FILTER i COMMANDS FIELD 3 DESCRIPTION Address Type: Defines the destination address type of the pattern. When bit is set, the pattern applies only to multicast frames. When bit is cleared, the pattern applies only to unicast frames. RESERVED Enable Filter: When bit is set, Filter i is enabled, otherwise, Filter i is disabled. The Filter i Offset register defines the offset in the frame’s destination address field from which the frames are examined by Filter i. Table 3.5 describes the Filter i Offset bit fields. Table 3.5 Filter i Offset Bit Definitions FILTER I OFFSET DESCRIPTION FIELD 7:0 DESCRIPTION Pattern Offset: The offset of the first byte in the frame on which CRC is checked for wake-up frame recognition. The minimum value of this field must be 12 since there should be no CRC check for the destination address and the source address fields. The MAC checks the first offset byte of the frame for CRC and checks to determine whether the frame is a wake-up frame. Offset 0 is the first byte of the incoming frame's destination address. The Filter i CRC-16 register contains the CRC-16 result of the frame that should pass Filter i. Table 3.6 describes the Filter i CRC-16 bit fields. Table 3.6 Filter i CRC-16 Bit Definitions FILTER I CRC-16 DESCRIPTION FIELD 15:0 DESCRIPTION Pattern CRC-16: This field contains the 16-bit CRC value from the pattern and the byte mask programmed to the wake-up filter register Function. This value is compared against the CRC calculated on the incoming frame, and a match indicates the reception of a wakeup frame.
2:1 0
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3.5.1
Magic Packet Detection
Setting the Magic Packet Enable bit (MPEN) in the “WUCSR—Wake-up Control and Status Register”, places the LAN9218I MAC in the “Magic Packet” detection mode. In this mode, normal data reception is disabled, and detection logic within the MAC examines receive data for a Magic Packet. The LAN9218I can be programmed to notify the host of the “Magic Packet” detection with the assertion of the host interrupt (IRQ) or assertion of the power management event signal (PME). Upon detection, the Magic Packet Received bit (MPR) in the WUCSR is set. When the host clears the MPEN bit the LAN9218I will resume normal receive operation. Please refer to Section 5.4.12, "WUCSR—Wake-up Control and Status Register," on page 102 for additional information on this register In Magic Packet mode, the Power Management Logic constantly monitors each frame addressed to the node for a specific Magic Packet pattern. It checks only packets with the MAC’s address or a broadcast address to meet the Magic Packet requirement. The Power Management Logic checks each received frame for the pattern 48h FF_FF_FF_FF_FF_FF after the destination and source address field. Then the Function looks in the frame for 16 repetitions of the MAC address without any breaks or interruptions. In case of a break in the 16 address repetitions, the PMT Function scans for the 48'hFF_FF_FF_FF_FF_FF pattern again in the incoming frame. The 16 repetitions may be anywhere in the frame but must be preceded by the synchronization stream. The device will also accept a multicast frame, as long as it detects the 16 duplications of the MAC address. If the MAC address of a node is 00h 11h 22h 33h 44h 55h, then the MAC scans for the following data sequence in an Ethernet: Frame. Destination Address Source Address ……………FF FF FF FF FF FF 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 00 11 22 33 44 55 …CRC It should be noted that Magic Packet detection can be performed when LAN9218I is in the D0 or D1 power states. In the D0 state, “Magic Packet” detection is enabled when the MPEN bit is set. In the D1 state, Magic Packet detection, as well as wake-up frame detection, are automatically enabled when the device enters the D1 state.
3.6
3.6.1
Host Bus Operations
32-bit vs. 16-bit Host Bus Width Operation
The LAN9218I can be configured to communicate with the host bus via either a 32-bit or a 16-bit bus. An external strap is used to select between the two modes. 32-bit mode is the native environment for the LAN9218I. Ethernet controller and no special requirements exist for communication in this mode. However, when this part is used in the 16-bit mode, two writes or reads must be performed back to back to properly communicate. The bus width is set by strapping the EEDIO pin; this setting can be read from bit 2 of the “Hardware Configuration Register”. Please refer to Section 5.3.9, "HW_CFG—Hardware Configuration Register," on page 76 for additional information on this register.
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3.6.2
16-bit Bus Writes
The host processor is required to perform two contiguous 16-bit writes to complete a single DWORD transfer. This DWORD must begin and end on a DWORD address boundary (A[2] and higher, cannot change during a sixteen bit write). No ordering requirements exist. The processor can access either the low or high word first, as long as the next write is performed to the other word. If a write to the same word is performed, the LAN9218I disregards the transfer.
3.6.3
16-bit Bus Reads
The host processor is required to perform two consecutive 16-bit reads to complete a single DWORD transfer. This DWORD must begin and end on a DWORD address boundary (A[2] and higher, cannot change during a sixteen bit read). No ordering requirements exist. The processor can access either the low or high word first, as long as the next read is performed from the other word. If a read to the same word is performed, the data read is invalid and should be re-read. This is not a fatal error. The LAN9218I will reset its read counters and restart a new cycle on the next read. The Upper 16 data pins (D[31:16]) are not driven by the LAN9218I in 16-bit mode. These pins have internal pull-down’s and the signals are left in a high-impedance state.
3.7
Big and Little Endian Support
TheLAN9218I supports “Big-” or “Little-Endian” processors with either 16 or 32-bit busses. To support big-endian processors, the hardware designer must explicitly invert the layout of the byte lanes.
3.8
Word Swap Function
Internally the LAN9218I is 32-bits wide. The LAN9218I supports a Word Swap Function when its Host Bus Interface is configured to operate in 16-bit mode. This feature is controlled by the Word Swap Register, which is described in Section 5.3.17, "WORD SWAP—Word Swap Control," on page 85. This register affects how words on the data bus are written to or read from Controls and Status Registers and the Transmit and Receive Data FIFOs. Refer to Table 3.7, "Word Swap Control (16-bit mode only)" below for more details. Whenever the LAN9218I transmits data from the Transmit Data FIFO to the network, the low order word is always transmitted first, and when the LAN9218I receives data from the network to the Receive Data Fifo, the low-order word is always received first. This register only takes effect when the LAN9218I is configured to operate in 16-bit mode. In 32-bit mode, this register is ignored and the upper data bits, D[31:16], are always mapped to the high-order word, and the lower data bits, D[15:0] are always mapped to the low-order word. Table 3.7 Word Swap Control (16-bit mode only) ADDRESS A1 PIN BYTE ORDER D[15:8] D[7:0] DESCRIPTION
Default Mode - Word Swap Register equal to 0x00000000 or any value other than 0xFFFFFFFF A1 = 0 A1 = 1 Byte 1 Byte 3 Byte 0 Byte 2 When A1=0, D[15:0] is mapped to the low order words of CSRs and FIFOs. When A1=1, D[15:0] is mapped to the high-order words of CSRs and FIFOs. Since low-order words are always transmitted/received first, A1=0 data will always precede A1=1 data.
Word Swap Mode - Word Swap Register equal to 0xFFFFFFFF
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Table 3.7 Word Swap Control (continued) (16-bit mode only) ADDRESS A1 PIN A1 = 0 A1 = 1 BYTE ORDER D[15:8] Byte 3 Byte 1 D[7:0] Byte 2 Byte 0 DESCRIPTION When A1=0, D[15:0] is mapped to the high order words of CSRs and FIFOs. When A1=1, D[15:0] is mapped to the low order words of CSRs and FIFOs. In this case A1=1 data will always precede A1=0 data.
3.9
General Purpose Timer (GP Timer)
The General Purpose Timer is a programmable block that can be used to generate periodic host interrupts. The resolution of this timer is 100uS. The GP Timer loads the GPT_CNT Register with the value in the GPT_LOAD field and begins counting down when the TIMER_EN bit is set to a ‘1.’ On a reset, or when the TIMER_EN bit changes from set ‘1’ to cleared ‘0,’ the GPT_CNT field is initialized to FFFFh. The GPT_CNT register is also initialized to FFFFh on a reset. Software can write the pre-load value into the GPT_LOAD field at any time; e.g., before or after the TIMER_EN bit is asserted. The GPT Enable bit TIMER_EN is located in the GPT_CFG register. Once enabled, the GPT counts down either until it reaches 0000h or until a new pre-load value is written to the GPT_LOAD field. At 0000h, the counter wraps around to FFFFh, asserts the GPT interrupt status bit and the IRQ signal if the GPT_INT_EN bit is set, and continues counting. The GPT interrupt status bit is in the INT_STS Register. The GPT_INT hardware interrupt can only be set if the GPT_INT_EN bit is set. GPT_INT is a sticky bit (R/WC); i.e., once the GPT_INT bit is set, it can only be cleared by writing a ‘1’ to the bit.
3.10
EEPROM Interface
The LAN9218I can optionally load its MAC address from an external serial EEPROM. If a properly configured EEPROM is detected by the LAN9218I at power-up, hard reset or soft reset, the ADDRH and ADDRL registers will be loaded with the contents of the EEPROM. If a properly configured EEPROM is not detected, it is the responsibility of the host LAN Driver to set the IEEE addresses. The LAN9218I EEPROM controller also allows the host system to read, write and erase the contents of the Serial EEPROM. The EEPROM controller supports most “93C46” type EEPROMs configured for 128 x 8-bit operation.
3.10.1
MAC Address Auto-Load
On power-up, hard reset or soft reset, the EEPROM controller attempts to read the first byte of data from the EEPROM (address 00h). If the value A5h is read from the first address, then the EEPROM controller will assume that an external Serial EEPROM is present. The EEPROM controller will then access the next EEPROM byte and send it to the MAC Address register byte 0 (ADDRL[7:0]). This process will be repeated for the next five bytes of the MAC Address, thus fully programming the 48bit MAC address. Once all six bytes have been programmed, the “MAC Address Loaded” bit is set in the E2P_CMD register. A detailed explanation of the EEPROM byte ordering with respect to the MAC address is given in Section 5.4.3, "ADDRL—MAC Address Low Register," on page 97. If an 0xA5h is not read from the first address, the EEPROM controller will end initialization. It is then the responsibility of the host LAN driver software to set the IEEE address by writing to the MAC’s ADDRH and ADDRL registers. The host can initiate a reload of the MAC address from the EEPROM by issuing the RELOAD command via the E2P command (E2P_CMD) register. If the first byte read from the EEPROM is not
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A5h, it is assumed that the EEPROM is not present, or not programmed, and the MAC address reload will fail. The “MAC Address Loaded” bit indicates a successful reload of the MAC address.
3.10.2
EEPROM Host Operations
After the EEPROM controller has finished reading (or attempting to read) the MAC after power-on, hard reset or soft reset, the host is free to perform other EEPROM operations. EEPROM operations are performed using the E2P_CMD and E2P data (E2P_DATA) registers. Section 5.3.23, "E2P_CMD – EEPROM Command Register," on page 90 provides an explanation of the supported EEPROM operations. If the EEPROM operation is the “write location” (WRITE) or “write all” (WRAL) commands, the host must first write the desired data into the E2P_DATA register. The host must then issue the WRITE or WRAL command using the E2P_CMD register by setting the EPC_CMD field appropriately. If the operation is a WRITE, the EPC_ADDR field in E2P_CMD must also be set to the desired location. The command is executed when the host sets the EPC_BSY bit high. The completion of the operation is indicated when the EPC_BSY bit is cleared. If the EEPROM operation is the “read location” (READ) operation, the host must issue the READ command using the E2P_CMD with the EPC_ADDR set to the desired location. The command is executed when the host sets the EPC_BSY bit high. The completion of the operation is indicated when the EPC_BSY bit is cleared, at which time the data from the EEPROM may be read from the E2P_DATA register. Other EEPROM operations are performed by writing the appropriate command to the EPC_CMD register. The command is executed when the host sets the EPC_BSY bit high. The completion of the operation is indicated when the EPC_BSY bit is cleared. In all cases the host must wait for EPC_BSY to clear before modifying the E2P_CMD register. Note: The EEPROM device powers-up in the erase/write disabled state. To modify the contents of the EEPROM the host must first issue the EWEN command. If an operation is attempted, and an EEPROM device does not respond within 30mS, the LAN9218I will timeout, and the EPC timeout bit (EPC_TO) in the E2P_CMD register will be set. Figure 3.2, "EEPROM Access Flow Diagram" illustrates the host accesses required to perform an EEPROM Read or Write operation.
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EEPROM Write
EEPROM Read
Idle
Idle
Write Data Register
Write Command Register
Write Command Register
Read Command Register Busy Bit = 0
Busy Bit = 0
Read Command Register
Read Data Register
Figure 3.2 EEPROM Access Flow Diagram The host can disable the EEPROM interface through the GPIO_CFG register. When the interface is disabled, the EEDIO and ECLK signals can be used as general-purpose outputs, or they may be used to monitor internal MII signals.
3.10.2.1
Supported EEPROM Operations
The EEPROM controller supports the following EEPROM operations under host control via the E2P_CMD register. The operations are commonly supported by “93C46” EEPROM devices. A description and functional timing diagram is provided below for each operation. Please refer to the E2P_CMD register description in Section 5.3.23, "E2P_CMD – EEPROM Command Register," on page 90 for E2P_CMD field settings for each command. ERASE (Erase Location): If erase/write operations are enabled in the EEPROM, this command will erase the location selected by the EPC Address field (EPC_ADDR). The EPC_TO bit is set if the EEPROM does not respond within 30ms.
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tCSL
EECS EECLK EEDIO (OUTPUT) EEDIO (INPUT)
1
1
1
A6
A0
Figure 3.3 EEPROM ERASE Cycle
ERAL (Erase All): If erase/write operations are enabled in the EEPROM, this command will initiate a bulk erase of the entire EEPROM.The EPC_TO bit is set if the EEPROM does not respond within 30ms.
tCSL
EECS EECLK EEDIO (OUTPUT) EEDIO (INPUT)
1
0
0
1
0
Figure 3.4 EEPROM ERAL Cycle
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EWDS (Erase/Write Disable): After issued, the EEPROM will ignore erase and write commands. To re-enable erase/write operations issue the EWEN command.
tCSL
EECS EECLK EEDIO (OUTPUT)
1
0
0
0
0
EEDIO (INPUT)
Figure 3.5 EEPROM EWDS Cycle
EWEN (Erase/Write Enable): Enables the EEPROM for erase and write operations. The EEPROM will allow erase and write operations until the “Erase/Write Disable” command is sent, or until power is cycled. Note: The EEPROM device will power-up in the erase/write-disabled state. Any erase or write operations will fail until an Erase/Write Enable command is issued.
tCSL
EECS
EECLK EEDIO (OUTPUT) EEDIO (INPUT)
1
0
0
1
1
Figure 3.6 EEPROM EWEN Cycle
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READ (Read Location): This command will cause a read of the EEPROM location pointed to by EPC Address (EPC_ADDR). The result of the read is available in the E2P_DATA register.
tCSL
EECS EECLK EEDIO (OUTPUT) EEDIO (INPUT)
1
1
0
A6
A0
D7
D0
Figure 3.7 EEPROM READ Cycle
WRITE (Write Location): If erase/write operations are enabled in the EEPROM, this command will cause the contents of the E2P_DATA register to be written to the EEPROM location selected by the EPC Address field (EPC_ADDR). The EPC_TO bit is set if the EEPROM does not respond within 30ms.
tCSL
EECS EECLK EEDIO (OUTPUT) EEDIO (INPUT)
1
0
1
A6
A0
D7
D0
Figure 3.8 EEPROM WRITE Cycle
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WRAL (Write All): If erase/write operations are enabled in the EEPROM, this command will cause the contents of the E2P_DATA register to be written to every EEPROM memory location. The EPC_TO bit is set if the EEPROM does not respond within 30ms.
tCSL
EECS EECLK EEDIO (OUTPUT) EEDIO (INPUT)
1
0
0
0
1
D7
D0
Figure 3.9 EEPROM WRAL Cycle Table 3.8, "Required EECLK Cycles", shown below, shows the number of EECLK cycles required for each EEPROM operation. Table 3.8 Required EECLK Cycles OPERATION ERASE ERAL EWDS EWEN READ WRITE WRAL REQUIRED EECLK CYCLES 10 10 10 10 18 18 18
3.10.2.2
MAC Address Reload
The MAC address can be reloaded from the EEPROM via a host command to the E2P_CMD register. If a value of 0xA5h is not found in the first address of the EEPROM, the EEPROM is assumed to be un-programmed and MAC Address Reload operation will fail. The “MAC Address Loaded” bit indicates a successful load of the MAC address. The EPC_LOAD bit is set after a successful reload of the MAC address.
3.10.2.3
EEPROM Command and Data Registers
Refer to Section 5.3.23, "E2P_CMD – EEPROM Command Register," on page 90 and Section 5.3.24, "E2P_DATA – EEPROM Data Register," on page 92 for a detailed description of these registers. Supported EEPROM operations are described in these sections.
3.10.2.4
EEPROM Timing
Refer to Section 6.9, "EEPROM Timing," on page 124 for detailed EEPROM timing specifications.
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3.11
Power Management
The LAN9218I supports power-down modes to allow applications to minimize power consumption. The following sections describe these modes.
3.11.1
System Description
Power is reduced to various modules by disabling the clocks as outlined in Table 3.9, “Power Management States,” on page 37. All configuration data is saved when in either of the twolow power states. Register contents are not affected unless specifically indicated in the register description.
3.11.2
Functional Description
There is one normal operating power state, D0 and there are two power saving states: D1, and D2. Upon entry into either of the two power saving states, only the PMT_CTRL register is accessible for read operations. In either of the power saving states the READY bit in the PMT_CTRL register will be cleared. Reads of any other addresses are forbidden until the READY bit is set. All writes, with the exception of the wakeup write to BYTE_TEST, are also forbidden until the READY bit is set. Only when in the D0 (Normal) state, when the READY bit is set, can the rest of the device be accessed. Note 3.3 The LAN9218I must always be read at least once after power-up, reset, or upon return from a power-saving state, otherwise write operations will not function.
In system configurations where the PME signal is shared amongst multiple devices, the WUPS field within the PMT_CTRL register can be read to determine which LAN9218I device is driving the PME signal. When the LAN9218I is in a power saving state (D1 or D2), a write cycle to the BYTE_TEST register will return the LAN9218I to the D0 state. Table 7.2, “Power Consumption Device and System Components,” on page 126 and Table 7.2, “Power Consumption Device and System Components,” on page 126, shows the power consumption values for each power state. Note 3.4 When the LAN9218I is in a power saving state, a write of any data to the BYTE_TEST register will wake-up the device. DO NOT PERFORM WRITES TO OTHER ADDRRESSES while the READY bit in the PMT_CTRL register is cleared.
3.11.2.1
D1 Sleep
Power consumption is reduced in this state by disabling clocks to portions of the internal logic as shown in Table 3.9. In this mode the clock to the internal PHY and portions of the MAC are still operational. This state is entered when the host writes a '01' to the PM_MODE bits in the Power Management (PMT_CTRL) register. The READY bit in PMT_CTRL is cleared when entering the D1 state. Wake-up frame and Magic Packet detection are automatically enabled in the D1 state. If properly enabled via the WOL_EN and PME_EN bits, the LAN9218I will assert the PME hardware signal upon the detection of the wake-up frame or magic packet. The LAN9218I can also assert the host interrupt (IRQ) on detection of a wake-up frame or magic packet. Upon detection, the WUPS field in PMT_CTRL will be set to a 10b. Note 3.5 Note 3.6 The PME interrupt status bit (PME_INT) in the INT_STS register is set regardless of the setting of PME_EN. Wake-up frame and Magic Packet detection is automatically enabled when entering the D1 state. For wake-up frame detection, the wake-up frame filter must be programmed before entering the D1 state (see Section 3.5, "Wake-up Frame Detection," on page 25). If used, the host interrupt and PME signal must be enabled prior to entering the D1 state.
A write to the BYTE_TEST register, regardless of whether a wake-up frame or Magic Packet was detected, will return LAN9218I to the D0 state and will reset the PM_MODE field to the D0 state. As
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noted above, the host is required to check the READY bit and verify that it is set before attempting any other reads or writes of the device. Note 3.7 The host must do only read accesses prior to the ready bit being set.
Once the READY bit is set, the LAN9218I is ready to resume normal operation. At this time the WUPS field can be cleared.
3.11.2.2
D2 Sleep
In this state, as shown in Table 3.9, all clocks to the MAC and host bus are disabledand the PHY is placed in a reduced power state. To enter this state, the EDPWRDOWN bit in register 17 of the PHY (Mode Control/Status register) must be set. This places the PHY in the Energy Detect mode. The PM_MODE bits in the PMT_CTRL register must then be set to 10b. Upon setting the PM_MODE bits, the LAN9218I will enter the D2 sleep state. The READY bit in PMT_CTRL is cleared when entering the D2 state. Note 3.8 If carrier is present when this state is entered detection will occur immediately.
If properly enabled via the ED_EN and PME_EN bits, the LAN9218I will assert the PME hardware signal upon detection of a valid carrier. Upon detection, the WUPS field in PMT_CTRL will be set to a 01b. Note 3.9 The PME interrupt status bit on the INT_STS register (PME_INT) is set regardless of the setting of PME_EN.
A write to the BYTE_TEST register, regardless of whether a carrier was detected, will return the LAN9218I to the D0 state and will reset the PM_MODE field to the D0 state. As noted above, the host is required to check the READY bit and verify that it is set before attempting any other reads or writes of the device. Before the LAN9218I is fully awake from this state the EDPWRDOWN bit in register 17 of the PHY must be cleared in order to wake the PHY. Do not attempt to clear the EDPWRDOWN bit until the READY bit is set. After clearing the EDPWRDOWN bit the LAN9218I is ready to resume normal operation. At this time the WUPS field can be cleared. Table 3.9 Power Management States LAN9218I BLOCK PHY MAC Power Management MAC and Host Interface Internal Clock D0 (NORMAL OPERATION) Full ON Full ON Full ON Full ON D1 (WOL) Full ON RX Power Mgmt. Block On OFF Full ON D2 (ENERGY DETECT) Energy Detect Power-Down OFF OFF OFF
KEY CLOCK ON BLOCK DISABLED – CLOCK ON FULL OFF
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3.11.2.3
Power Management Event Indicators
Figure 3.10 is a simplified block diagram of the logic that controls the external PME, and internal pme_interrupt signals. The pme_interrupt signal is used to set the PME_INT status bit in the INT_STS register, which, if enabled, will generate a host interrupt upon detection of a power management event. The PME_INT status bit in INT_STS will remain set until the internal pme_interrupt signal is cleared by clearing the WUPS bits, or by clearing the corresponding WOL_EN or ED_EN bit. After clearing the internal pme_interrupt signal, the PME_INT status bit may be cleared by writing a ‘1’ to this bit in the INT_STS register. It should be noted that the LAN9218I can generate a host interrupt regardless of the state of the PME_EN bit, or the external PME signal. The external PME signal can be setup for pulsed, or static operation. When the PME_IND bit in the PMT_CTRL register is set to a ‘1’, the external PME signal will be driven active for 50ms upon detection of a wake-up event. When the PME_IND bit is cleared, the PME signal will be driven continuously upon detection of a wake-up event. The PME signal is deactivated by clearing the WUPS bits, or by clearing the corresponding WOL_EN or ED_EN bit. The PME signal can also be deactivated by clearing the PME_EN bit.
WUFR WOL_EN WUEN WUPS MPR
MPEN
ED_EN WUPS
phy_int
Other System Interrupts PME_INT
Denotes a level-triggered "sticky" status bit
PME_INT_EN IRQ_EN
IRQ
PME_EN PME_IND PME_POL PME_TYPE
50ms
LOGIC
PME
Figure 3.10 PME and PME_INT Signal Generation
3.11.3
Internal PHY Power-Down modes
There are 2 power-down modes for the internal Phy:
3.11.3.1
General Power-Down
This power-down is controlled by register 0, bit 11. In this mode the internal PHY, except the management interface, is powered-down and stays in that condition as long as Phy register bit 0.11 is HIGH. When bit 0.11 is cleared, the PHY powers up and is automatically reset. Please refer to Section 5.5.1, "Basic Control Register," on page 104 for additional information on this register.
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3.11.3.2
Energy Detect Power-Down
This power-down mode is activated by setting the Phy register bit 17.13 to 1. Please refer to Section 5.5.8, "Mode Control/Status," on page 108 for additional information on this register. In this mode when no energy is present on the line, the PHY is powered down, with the exception of the management interface, the SQUELCH circuit and the ENERGYON logic. The ENERGYON logic is used to detect the presence of valid energy from 100Base-TX, 10Base-T, or Auto-negotiation signals In this mode, when the ENERGYON signal is low, the PHY is powered-down, and nothing is transmitted. When energy is received - link pulses or packets - the ENERGYON signal goes high, and the PHY powers-up. It automatically resets itself into the state it had prior to power-down, and asserts the INT7.1 bit of the register defined in Section 5.5.11, "Interrupt Source Flag," on page 111. If the ENERGYON interrupt is enabled, this event will cause an interrupt to the host. The first and possibly the second packet to activate ENERGYON may be lost. When 17.13 is low, energy detect power-down is disabled.
3.12
Detailed Reset Description
The LAN9218I has five reset sources: Power-On Reset (POR) Hardware Reset Input Pin (nRESET) Soft Reset (SRST) PHY Soft Reset via PMT_CTRL bit 10 (PHY_RST) PHY Soft Reset via PHY Basic Control Register (PHY REG 0.15) Table 3.10 shows the effect of the various reset sources on the LAN9218I's circuitry. Table 3.10 PHY Reset Sources and Effected Circuitry EEPROM MAC ADDR. RELOAD Note 3.11 X X X X X
RESET SOURCE POR nRESET SRST PHY_RST PHY REG 0.15
PLL X X
HBI Note 3.12 X X X
NASR REGISTERS Note 3.12 X X
MIL X X X
MAC X X X
PHY Note 3.10 X X
CONFIG. STRAPS LATCHED X X
Note 3.10 After any PHY reset, the application must wait until the “Link Status” bit in the PHY’s “Basic Status Register” (PHY Reg. 1.2) is set before attempting to transmit or receive data. Note 3.11 After a POR, nRESET or SRST, the LAN9218I will automatically check for the presence of an external EEPROM. After any of these resets the application must verify that the EPC Busy Bit (E2P_CMD, bit 31) is cleared before attempting to access the EEPROM, or change the function of the GPO/GPIO signals, or before modifying the ADDRH or ADDRL registers in the MAC. Note 3.12 HBI - “Host Bus Interface”, NASR - Not affected by software reset
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3.12.1
Power-On Reset (POR)
A Power-On reset occurs whenever power is initially applied to the LAN9218I, or if power is removed and reapplied to the LAN9218I. A timer within the LAN9218I will assert the internal reset for approximately 22ms. The READY bit in the PMT_CTRL register can be read from the host interface and will read back a ‘0’ until the POR is complete. Upon completion of the POR, the READY bit in PMT_CTRL is set high, and the LAN9218I can be configured via its control registers.
APPLICATION NOTE: Under normal conditions, the READY bit in PMT_CTRL will be set (high -”1”) after an internal reset (22ms). If the software driver polls this bit and it is not set within 100ms, then an error condition occurred.
3.12.2
Hardware Reset Input (nRESET)
A hardware reset will occur when the nRESET input signal is driven low. The READY bit in the PMT_CTRL register can be read from the host interface, and will read back a ‘0’ until the hardware reset is complete. Upon completion of the hardware reset, the READY bit in PMT_CTRL is set high. After the “READY” bit is set, the LAN9218I can be configured via its control registers. The nRESET signal is pulled-high internally by the LAN9218I and can be left unconnected if unused. If used, nRESET must be driven low for a minimum period as defined in Section 6.8, "Reset Timing," on page 123.
APPLICATION NOTE: Under normal conditions, the READY bit in PMT_CTRL will be set (high -”1”) immediately. If the software driver polls this bit and it is not set within 100ms, then an error condition occurred.
3.12.3
Resume Reset Timing
After issuing a write to the BYTE_TEST register to wake the LAN9218I from a power-down state, the READY bit in PMT_CTRL will assert (set High) within 2ms.
APPLICATION NOTE: Under normal conditions, the READY bit in PMT_CTRL will be set (high -”1”) within 2 ms. If the software driver polls this bit and it is not set within 100ms, then an error condition occurred.
3.12.4
Soft Reset (SRST)
Soft reset is initiated by writing a ‘1’ to bit 0 of the HW_CFG register (SRST). This self-clearing bit will return to ‘0’ after approximately 2 μs, at which time the Soft Reset is complete. Soft reset does not clear control register bits marked as NASR.
APPLICATION NOTE: Under normal conditions, the READY bit in PMT_CTRL will be set (high -”1”) immediately, (within 2μs). If the software driver polls this bit and it is not set within 100ms, then an error condition occurred.
3.12.5
PHY Reset Timing
The following sections and tables specify the operation and time required for the internal PHY to become operational after various resets or when returning from the reduced power state.
3.12.5.1
PHY Soft Reset via PMT_CTRL bit 10 (PHY_RST)
The PHY soft reset is initiated by writing a ‘1’ to bit 10 of the PMT_CTRL register (PHY_RST). This self-clearing bit will return to ‘0’ after approximately 100 μs, at which time the PHY reset is complete.
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3.12.5.2
PHY Soft Reset via PHY Basic Control Register (PHY Reg. 0.15)
The PHY Reg. 0.15 Soft Reset is initiated by writing a ‘1’ to bit 15 of the PHY’s Basic Control Register. This self-clearing bit will return to ‘0’ at which time the PHY reset is complete.
3.13
TX Data Path Operation
Data is queued for transmission by writing it into the TX data FIFO. Each packet to be transmitted may be divided among multiple buffers. Each buffer starts with a two DWORD TX command (TX command ‘A’ and TX command ‘B’). The TX command instructs the LAN9218I on the handling of the associated buffer. Packet boundaries are delineated using control bits within the TX command. The host provides a 16-bit Packet Tag field in the TX command. The Packet Tag value is appended to the corresponding TX status DWORD. All Packet Tag fields must have the same value for all buffers in a given packet. If tags differ between buffers in the same packet the TXE error will be asserted. Any value may be chosen for a Packet Tag as long as all tags in the same Packet are identical. Packet Tags also provide a method of synchronization between transmitted packets and their associated status. Software can use unique Packet Tags to assist with validating matching status completions. Note 3.13 The use of packet tags is not required by the hardware. This is a software LAN driver only application example for use of this field. A Packet Length field in the TX command specifies the number of bytes in the associated packet. All Packet Length fields must have the same value for all buffers in a given packet. Hardware compares the Packet Length field and the actual amount of data received by the Ethernet controller. If the actual packet length count does not match the Packet Length field as defined in the TX command, the Transmitter Error (TXE) flag is asserted. The LAN9218I can be programmed to start payload transmission of a buffer on a byte boundary by setting the “Data Start Offset” field in the TX command. The “Data Start Offset” field points to the actual start of the payload data within the first 8 DWORDs of the buffer. Data before the “Data Start Offset” pointer will be ignored. When a packet is split into multiple buffers, each successive buffer may begin on any arbitrary byte. The LAN9218I can be programmed to strip padding from the end of a transmit packet in the event that the end of the packet does not align with the host burst boundary. This feature is necessary when the LAN9218I is operating in a system that always performs multi-word bursts. In such cases the LAN9218I must guarantee that it can accept data in multiples of the Burst length regardless of the actual packet length. When configured to do so, the LAN9218I will accept extra data at the end of the packet and will remove the extra padding before transmitting the packet. The LAN9218I automatically removes data up to the boundary specified in the Buffer End Alignment field specified in each TX command. The host can instruct the LAN9218I to issue an interrupt when the buffer has been fully loaded into the TX FIFO contained in the LAN9218I and transmitted. This feature is enabled through the TX command ‘Interrupt on Completion’ field. Upon completion of transmission, irrespective of success or failure, the status of the transmission is written to the TX status FIFO. TX status is available to the host and may be read using PIO operations. An interrupt can be optionally enabled by the host to indicate the availability of a programmable number TX status DWORDS. Before writing the TX command and payload data to the TX FIFO, the host must check the available TX FIFO space by performing a PIO read of the TX_FIFO_INF register. The host must ensure that it does not overfill the TX FIFO or the TX Error (TXE) flag will be asserted. The host proceeds to write the TX command by first writing TX command ‘A’, then TX command ‘B’. After writing the command, the host can then move the payload data into the TX FIFO. TX status DWORD’s are stored in the TX status FIFO to be read by the host at a later time upon completion of the data transmission onto the wire.
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init
Idle
TX Status Available Read TX Status (optional)
Check available FIFO space
Write TX Command
Write Start Padding (optional) Last Buffer in Packet Write Buffer Not Last Buffer
Figure 3.11 Simplified Host TX Flow Diagram
3.13.1
TX Buffer Format
TX buffers exist in the host’s memory in a given format. The host writes a TX command word into the TX data buffer before moving the Ethernet packet data. The TX command A and command B are 32bit values that are used by the LAN9218I in the handling and processing of the associated Ethernet packet data buffer. Buffer alignment, segmentation and other packet processing parameters are included in the command structure. The following diagram illustrates the buffer format.
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Host Write 31 Order 1st 2nd 3rd
0
TX Command 'A' TX Command 'B'
Optional offset DWORD0
. . .
Optional offset DWORDn
Offset + Data DWORD0 . . . . . Last Data & PAD
Optional Pad DWORD0
. . . Last
Optional Pad DWORDn
Figure 3.12 TX Buffer Format
Figure 3.12, "TX Buffer Format", shows the TX Buffer as it is written into the LAN9218I. It should be noted that not all of the data shown in this diagram is actually stored in the TX data FIFO. This must be taken into account when calculating the actual TX data FIFO usage. Please refer to Section 3.13.5, "Calculating Actual TX Data FIFO Usage," on page 47 for a detailed explanation on calculating the actual TX data FIFO usage.
3.13.2
TX Command Format
The TX command instructs the TX FIFO controller on handling the subsequent buffer. The command precedes the data to be transmitted. The TX command is divided into two, 32-bit words; TX command ‘A’ and TX command ‘B’. There is a 16-bit packet tag in the TX command ‘B’ command word. Packet tags may, if host software desires, be unique for each packet (i.e., an incrementing count). The value of the tag will be returned in the RX status word for the associated packet. The Packet tag can be used by host software to uniquely identify each status word as it is returned to the host. Both TX command ‘A’ and TX command ‘B’ are required for each buffer in a given packet. TX command ‘B’ must be identical for every buffer in a given packet. If the TX command ‘B’ words do not match, the Ethernet controller will assert the Transmitter Error (TXE) flag.
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TX COMMAND ‘A’ Table 3.11 TX Command 'A' Format BITS 31 30:26 25:24 DESCRIPTION Interrupt on Completion. When set, the TXDONE flag will be asserted when the current buffer has been fully loaded into the TX FIFO. This flag may be optionally mapped to a host interrupt. Reserved. These bits are reserved. Always write zeros to this field to guarantee future compatibility. Buffer End Alignment. This field specifies the alignment that must be maintained on the last data transfer of a buffer. The host will add extra DWORDs of data up to the alignment specified in the table below. The LAN9218I will remove the extra DWORDs. This mechanism can be used to maintain cache line alignment on host processors.
[25] 0 0 1 1
[24] 0 1 0 1
End Alignment 4-byte alignment 16-byte alignment 32-byte alignment Reserved
23:21 20:16 15:14 13 12 11 10:0
Reserved. These bits are reserved. Always write zeros to this field to guarantee future compatibility Data Start Offset (bytes). This field specifies the offset of the first byte of TX data. The offset value can be anywhere from 0 bytes to 31 a Byte offset. Reserved. These bits are reserved. Always write zeros to this field to guarantee future compatibility First Segment. When set, this bit indicates that the associated buffer is the first segment of the packet. Last Segment. When set, this bit indicates that the associated buffer is the last segment of the packet Reserved. These bits are reserved. Always write zeros to this field to guarantee future compatibility. Buffer Size (bytes). This field indicates the number of bytes contained in the buffer following this command. This value, along with the Buffer End Alignment field, is read and checked by the LAN9218I and used to determine how many extra DWORD’s were added to the end of the Buffer. A running count is also maintained in the LAN9218I of the cumulative buffer sizes for a given packet. This cumulative value is compared against the Packet Length field in the TX command ‘B’ word and if they do not correlate, the TXE flag is set. Note: The buffer size specified does not include the buffer end alignment padding or data start offset added to a buffer.
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TX COMMAND ‘B’ Table 3.12 TX Command 'B' Format BITS 31:16 DESCRIPTION Packet Tag. The host should write a unique packet identifier to this field. This identifier is added to the corresponding TX status word and can be used by the host to correlate TX status words with their corresponding packets. Note: 15:14 13 12 The use of packet tags is not required by the hardware. This field can be used by the LAN software driver for any application. Packet Tags is one application example.
Reserved. These bits are reserved. Always write zeros to this field to guarantee future compatibility. Add CRC Disable. When set, the automatic addition of the CRC is disabled. Disable Ethernet Frame Padding. When set, this bit prevents the automatic addition of padding to an Ethernet frame of less than 64 bytes. The CRC field is also added despite the state of the Add CRC Disable field. Reserved. These bits are reserved. Always write zeros to this field to guarantee future compatibility. Packet Length (bytes). This field indicates the total number of bytes in the current packet. This length does not include the offset or padding. If the Packet Length field does not match the actual number of bytes in the packet the Transmitter Error (TXE) flag will be set.
11 10:0
3.13.3
TX Data Format
The TX data section begins at the third DWORD in the TX buffer (after TX command ‘A’ and TX command ‘B’). The location of the first byte of valid buffer data to be transmitted is specified in the “Data Start Offset” field of the TX command ‘A’ word. Table 3.13, "TX DATA Start Offset", shows the correlation between the setting of the LSB’s in the “Data Start Offset” field and the byte location of the first valid data byte. Additionally, transmit buffer data can be offset by up to 7 additional DWORDS as indicated by the upper three MSB’s (5:2) in the “Data Start Offset” field. Table 3.13 TX DATA Start Offset
Data Start Offset [1:0]: First TX Data Byte:
11 D[31:24]
10 D[23:16]
01 D[15:8]
00 D[7:0]
TX data is contiguous until the end of the buffer. The buffer may end on a byte boundary. Unused bytes at the end of the packet will not be sent to the MIL for transmission. The Buffer End Alignment field in TX command ‘A’ specifies the alignment that must be maintained for the associated buffer. End alignment may be specified as 4-, 16-, or 32-byte. The host processor is responsible for adding the additional data to the end of the buffer. The hardware will automatically remove this extra data.
3.13.3.1
TX Buffer Fragmentation Rules
Transmit buffers must adhere to the following rules: Each buffer can start and end on any arbitrary byte alignment The first buffer of any transmit packet can be any length Middle buffers (i.e., those with First Segment = Last Segment = 0) must be greater than, or equal to 4 bytes in length The final buffer of any transmit packet can be any length
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Additionally, The LAN9218I has specific rules regarding the use of transmit buffers when in Store-andForward mode (i.e., HW_CFG[SF] = 1). When this mode is enabled, the total space consumed in the TX FIFO (MIL) must be limited to no more than 2KB - 3 DWORDs (2,036 bytes total). Any transmit packet that is so highly fragmented that it takes more space than this must be un-fragmented (by copying to a Driver-supplied buffer) before the transmit packet can be sent to the LAN9218I. One approach to determine whether a packet is too fragmented is to calculate the actual amount of space that it will consume, and check it against 2,036 bytes. Another approach is to check the number of buffers against a worst-case limit of 86 (see explanation below).
3.13.3.2
Calculating Worst-Case TX FIFO (MIL) Usage
The actual space consumed by a buffer consists only of any partial DWORD offsets in the first/last DWORD of the buffer, plus all of the whole DWORDs in between. Any whole DWORD offsets and/or alignments are stripped off before the buffer even gets into the TX data FIFO, and TX command words are stripped off before the buffer is written to the TX FIFO, so none of those DWORDs count as space consumed. The worst-case overhead for a TX buffer is 6 bytes, which assumes that it started on the high byte of a DWORD and ended on the low byte of a DWORD. A TX packet consisting of 86 such fragments would have an overhead of 516 bytes (6 * 86) which, when added to a 1514-byte max-size transmit packet (1516 bytes, rounded up to the next whole DWORD), would give a total space consumption of 2,032 bytes, leaving 4 bytes to spare; this is the basis for the "86 fragment" rule mentioned above.
3.13.4
TX Status Format
TX status is passed to the host CPU through a separate FIFO mechanism. A status word is returned for each packet transmitted. Data transmission is suspended if the TX status FIFO becomes full. Data transmission will resume when the host reads the TX status and there is room in the FIFO for more “TX Status” data. The host can optionally choose to not read the TX status. The host can optionally ignore the TX status by setting the “TX Status Discard Allow Overrun Enable” (TXSAO) bit in the TX Configuration Register (TX_CFG). If this option is chosen TX status will not be written to the FIFO. Setting this bit high allows the transmitter to continue operation with a full TX status FIFO. In this mode the status information is still available in the TX status FIFO, and TX status interrupts still function. In the case of an overrun, the TXSUSED counter will stay at zero and no further TX status will be written to the TX status FIFO until the host frees space by reading TX status. If TXSAO is enabled, a TXE error will not be generated if the TX status FIFO overruns. In this mode the host is responsible for re-synchronizing TX status in the case of an overrun.
BITS 31:16 15 14:12 11 10 9 8
DESCRIPTION Packet TAG. Unique identifier written by the host into the Packet Tag field of the TX command ‘B’ word. This field can be used by the host to correlate TX status words with the associated TX packets. Error Status (ES). ). When set, this bit indicates that the Ethernet controller has reported an error. This bit is the logical OR of bits 11, 10, 9, 8, 2, 1 in this status word. Reserved. These bits are reserved. Always write zeros to this field to guarantee future compatibility. Loss of Carrier. When set, this bit indicates the loss of carrier during transmission. No Carrier. When set, this bit indicates that the carrier signal from the transceiver was not present during transmission. Late Collision. When set, indicates that the packet transmission was aborted after the collision window of 64 bytes. Excessive Collisions. When set, this bit indicates that the transmission was aborted after 16 collisions while attempting to transmit the current packet.
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BITS 7 6:3 2
DESCRIPTION Reserved. This bit is reserved. Always write zeros to this field to guarantee future compatibility. Collision Count. This counter indicates the number of collisions that occurred before the packet was transmitted. It is not valid when excessive collisions (bit 8) is also set. Excessive Deferral. If the deferred bit is set in the control register, the setting of the excessive deferral bit indicates that the transmission has ended because of a deferral of over 24288 bit times during transmission. Underrun Error. When set, this bit indicates that the transmitter aborted the associated frame because of an underrun condition of the TX data FIFO. TX Underrun will cause the assertion of the TXE error flag. Deferred. When set, this bit indicates that the current packet transmission was deferred.
1
0
3.13.5
Calculating Actual TX Data FIFO Usage
The following rules are used to calculate the actual TX data FIFO space consumed by a TX Packet: TX command 'A' is stored in the TX data FIFO for every TX buffer TX command 'B' is written into the TX data FIFO when the First Segment (FS) bit is set in TX command 'A' Any DWORD-long data added as part of the “Data Start Offset” is removed from each buffer before the data is written to the TX data FIFO. Any data that is less than 1 DWORD is passed to the TX data FIFO. Payload from each buffer within a Packet is written into the TX data FIFO. Any DWORD-long data added as part of the End Padding is removed from each buffer before the data is written to the TX data FIFO. Any end padding that is less than 1 DWORD is passed to the TX data FIFO
3.13.6
3.13.6.1
Transmit Examples
TX Example 1
In this example a single, 111-Byte Ethernet packet will be transmitted. This packet is divided into three buffers. The three buffers are as follows: Buffer 0: 7-Byte “Data Start Offset” 79-Bytes of payload data 16-Byte “Buffer End Alignment” Buffer 1: 0-Byte “Data Start Offset” 15-Bytes of payload data 16-Byte “Buffer End Alignment” Buffer 2: 10-Byte “Data Start Offset” 17-Bytes of payload data 16-Byte “Buffer End Alignment”
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Figure 3.13, "TX Example 1" illustrates the TX command structure for this example, and also shows how data is passed to the TX data FIFO.
Data W ritten to the Ethernet Controller
31 TX Com m and 'A' Buff er End Alignment = 1 Data Start Of fset = 7 First Segment = 1 Last Segment = 0 Buff er Size = 79 TX Com m and 'B' Packet Length = 111 0
TX Command 'A' TX Command 'B' 7-Byte Data Start Offset
Data Passed to the TX Data FIFO
TX Command 'A' TX Command 'B'
79-Byte Payload 79-Byte Payload
Pad DW ORD 1
10-Byte End Padding TX Command 'A'
31 TX Com m and 'A' Buff er End Alignment = 1 Data Start Of fset = 0 First Segment = 0 Last Segment = 0 Buff er Size = 15 TX Com m and 'B' Packet Length = 111 0
TX Command 'A' TX Command 'B'
15-Byte Payload
TX Command 'A' 15-Byte Payload 1B 17-Byte Payload
31 0
TX Com m and 'A' Buff er End Alignment = 1 Data Start Of fset = 10 First Segment = 0 Last Segment = 1 Buff er Size = 17 TX Com m and 'B' Packet Length = 111
10-Byte TX Command 'A' End OffsetPadding TX Command 'B' 10-Byte Data Start Offset
NOTE: Extra bytes betw een buff ers are not transmitted
17-Byte Payload Data
5-Byte End Padding
Figure 3.13 TX Example 1
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3.13.6.2
TX Example 2
In this example, a single 183-Byte Ethernet packet will be transmitted. This packet is in a single buffer as follows: 2-Byte “Data Start Offset” 183-Bytes of payload data 4-Byte “Buffer End Alignment” Figure 3.14, "TX Example 2" illustrates the TX command structure for this example, and also shows how data is passed to the TX data FIFO. Note that the packet resides in a single TX Buffer, therefore both the FS and LS bits are set in TX command ‘A’.
Data Written to the Ethernet Controller
TX Command 'A' Buffer End Alignment = 0 Data Start Offset = 6 First Segment = 1 Last Segment = 1 Buffer Size =183 TX Command 'B' Packet Length = 183 31 0
Data Passed to the TX Data FIFO
TX Command 'A' TX Command 'B'
TX Command 'A' TX Command 'B' 6-Byte Data Start Offset
183-Byte Payload Data
183-Byte Payload Data
3B End Padding
NOTE: Extra bytes between buffers are not transmitted
Figure 3.14 TX Example 2
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3.13.7
TX Data FIFO Underrun
If the MIL is not operating in store and forward mode, and the host is unable supply data at the Ethernet line rate, the TX data FIFO can underrun. If a TX underrun occurs, any further data written to the TX data FIFO for the offending frame (the frame being transmitted during the underrun) will automatically be discarded and no further data for that frame will be transmitted. TX data FIFO underrun is not an error condition, and data transmission will resume with the next valid TX command. In the case of a TX data FIFO underrun, the (TDFU) flag is set and can be used to generate a host interrupt. A TX data FIFO underrun is also indicated in the TX status word for the underrun frame. In the case of a TX underrun, the host is still required to write the remainder of the current TX packet to the LAN9218I. Any remaining data from the underrun frame that is written to the LAN9218I will backup in the TX data FIFO (no more data is read until the next TX SOF [start of frame]). As the data backs up in the TX data FIFO, it will be visible in the TX_FIFO_INF register. In typical Driver usage, software will write the entire transmit packet to the LAN9218I and check INT_STS and see (from TDFU) that the underrun has occurred. Eventually, the driver will recognize the underrun. A '1' must then be written to the TXD_DUMP bit in the TX_CFG to flush the remaining data in the TX data FIFO (note that TX_ON may be kept on while flushing the remaining TX data FIFO contents). Once the leftover data from the underrun frame is purged, the LAN9218I is ready to send new transmit packets. It is advisable to clear the TDFU bit prior to transmitting any more data (assuming that SF=0) so that subsequent underruns can be detected, but this is not required by the hardware.
3.13.8
Transmitter Errors
If the Transmitter Error (TXE) flag is asserted for any reason, the transmitter will continue operation. TX Error (TXE) will be asserted under the following conditions: If the actual packet length count does not match the Packet Length field as defined in the TX command. Both TX command ‘A’ and TX command ‘B’ are required for each buffer in a given packet. TX command ‘B’ must be identical for every buffer in a given packet. If the TX command ‘B’ words do not match, the Ethernet controller will assert the Transmitter Error (TXE) flag. Host overrun of the TX data FIFO. Overrun of the TX status FIFO (unless TXSAO is enabled)
3.13.9
Stopping and Starting the Transmitter
To halt the transmitter, the host must set the TX_STOP bit in the TX_CFG register. The transmitter will finish sending the current frame (if there is a frame transmission in progress). When the transmitter has received the TX status for this frame, it will clear the TX_STOP and TX_ON bits, and will pulse the TXSTOP_INT. Once stopped, the host can optionally clear the TX status and TX data FIFOs. The host must re-enable the transmitter by setting the TX_ON bit. If the there are frames pending in the TX data FIFO (i.e., TX data FIFO was not purged), the transmission will resume with this data.
3.14
RX Data Path Operation
When an Ethernet Packet is received, the MIL first begins to transfer the RX data. This data is loaded into the RX data FIFO. The RX data FIFO pointers are updated as data is written into the FIFO. The last transfer from the MIL is the RX status word. The LAN9218I implements a separate FIFO for the RX status words. The total available RX data and status queued in the RX FIFO can be read from the RX_FIFO_INF register. The host may read any number of available RX status words before reading the RX data FIFO.
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The host must use caution when reading the RX data and status. The host must never read more data than what is available in the FIFOs. If this is attempted an underrun condition will occur. If this error occurs, the Ethernet controller will assert the Receiver Error (RXE) interrupt. If an underrun condition occurs, a soft reset is required to regain host synchronization. A configurable beginning offset is supported in the LAN9218I. The RX data Offset field in the RX_CFG register controls the number of bytes that the beginning of the RX data buffer is shifted. The host can set an offset from 0-31 bytes. The offset may be changed in between RX packets, but it must not be changed during an RX packet read. The LAN9218I can be programmed to add padding at the end of a receive packet in the event that the end of the packet does not align with the host burst boundary. This feature is necessary when the LAN9218I is operating in a system that always performs multi-DWORD bursts. In such cases the LAN9218I must guarantee that it can transfer data in multiples of the Burst length regardless of the actual packet length. When configured to do so, the LAN9218I will add extra data at the end of the packet to allow the host to perform the necessary number of reads so that the Burst length is not cut short. Once a packet has been padded by the H/W, it is the responsibility of the host to interrogate the Packet length field in the RX status and determine how much padding to discard at the end of the Packet. It is possible to read multiple packets out of the RX data FIFO in one continuous stream. It should be noted that the programmed Offset and Padding will be added to each individual packet in the stream, since packet boundaries are maintained.
3.14.1
RX Slave PIO Operation
Using PIO mode, the host can either implement a polling or interrupt scheme to empty the received packet out of the RX data FIFO. The host will remain in the idle state until it receives an indication (interrupt or polling) that data is available in the RX data FIFO. The host will then read the RX status FIFO to get the packet status, which will contain the packet length and any other status information. The host should perform the proper number of reads, as indicated by the packet length plus the start offset and the amount of optional padding added to the end of the frame, from the RX data FIFO.
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init
Idle
RX Interrupt
Read RX Status DWORD
Not Last Packet Last Packet Read RX Packet
Figure 3.15 Host Receive Routine Using Interrupts
init
Read RX_FIFO_ INf Valid Status DWORD Read RX Status DWORD
Not Last Packet Last Packet Read RX Packet
Figure 3.16 Host Receive Routine with Polling
3.14.1.1
Receive Data FIFO Fast Forward
The RX data path implements an automatic data discard function. Using the RX data FIFO Fast Forward bit (RX_FFWD) in the RX_DP_CTRL register, the host can instruct the LAN9218I to skip the packet at the head of the RX data FIFO. The RX data FIFO pointers are automatically incremented to the beginning of the next RX packet.
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When performing a fast-forward, there must be at least 4 DWORDs of data in the RX data FIFO for the packet being discarded. For less than 4 DWORDs do not use RX_FFWD. In this case data must be read from the RX data FIFO and discarded using standard PIO read operations. After initiating a fast-forward operation, do not perform any reads of the RX data FIFO until the RX_FFWD bit is cleared. Other resources can be accessed during this time (i.e., any registers and/or the other three FIFOs). Also note that the RX_FFWD will only fast-forward the RX data FIFO, not the RX status FIFO. After an RX fast-forward operation the RX status must still be read from the RX status FIFO. The receiver does not have to be stopped to perform a fast-forward operation.
3.14.1.2
Force Receiver Discard (Receiver Dump)
In addition to the Receive data Fast Forward feature, LAN9218I also implements a receiver "dump" feature. This feature allows the host processor to flush the entire contents of the RX data and RX status FIFOs. When activated, the read and write pointers for the RX data and status FIFOs will be returned to their reset state. To perform a receiver dump, the LAN9218I receiver must be halted. Once the receiver stop completion is confirmed, the RX_DUMP bit can be set in the RX_CFG register. The RX_DUMP bit is cleared when the dump is complete. For more information on stopping the receiver, please refer to Section 3.14.4, "Stopping and Starting the Receiver," on page 55. For more information on the RX_DUMP bit, please refer to Section 5.3.7, "RX_CFG—Receive Configuration Register," on page 74.
3.14.2
RX Packet Format
The RX status words can be read from the RX status FIFO port, while the RX data packets can be read from the RX data FIFO. RX data packets are formatted in a specific manner before the host can read them. It is assumed that the host has previously read the associated status word from the RX status FIFO, to ascertain the data size and any error conditions.
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Host Read Order 1st 2nd
31
0
Optional offset DWORD0
. .
Optional offset DWORDn
ofs + First Data DWORD . . . . Last Data DWORD
Optional Pad DWORD0
. . Last
Optional Pad DWORDn
Figure 3.17 RX Packet Format
3.14.3
RX Status Format
BITS 31 30 29:16 15 14 13 12 11 Reserved. This bit is reserved. Reads 0.
DESCRIPTION
Filtering Fail. When set, this bit indicates that the associated frame failed the address recognizing filtering. Packet Length. The size, in bytes, of the corresponding received frame. Error Status (ES). When set this bit indicates that the MIL has reported an error. This bit is the Internal logical “or” of bits 11,7,6 and 1. Reserved. These bits are reserved. Reads 0. Broadcast Frame. When set, this bit indicates that the received frame has a Broadcast address. Length Error (LE). When set, this bit indicates that the actual length does not match with the length/type field of the received frame. Runt Frame. When set, this bit indicates that frame was prematurely terminated before the collision window (64 bytes). Runt frames are passed on to the host only if the Pass Bad Frames bit MAC_CR Bit [16] is set. Multicast Frame. When set, this bit indicates that the received frame has a Multicast address.
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BITS 9:8 7
DESCRIPTION Reserved. These bits are reserved. Reads 0. Frame Too Long. When set, this bit indicates that the frame length exceeds the maximum Ethernet specification of 1518 bytes. This is only a frame too long indication and will not cause the frame reception to be truncated. Collision Seen. When set, this bit indicates that the frame has seen a collision after the collision window. This indicates that a late collision has occurred. Frame Type. When set, this bit indicates that the frame is an Ethernet-type frame (Length/Type field in the frame is greater than 1500). When reset, it indicates the incoming frame was an 802.3 type frame. This bit is not set for Runt frames less than 14 bytes. Receive Watchdog time-out. When set, this bit indicates that the incoming frame is greater than 2048 bytes through 2560 bytes, therefore expiring the Receive Watchdog Timer. MII Error. When set, this bit indicates that a receive error (RX_ER asserted) was detected during frame reception. Dribbling Bit. When set, this bit indicates that the frame contained a non-integer multiple of 8 bits. This error is reported only if the number of dribbling bits in the last byte is 4 in the MII operating mode, or at least 3 in the 10 Mbps operating mode. This bit will not be set when the collision seen bit[6] is set. If set and the CRC error bit is [1] reset, then the packet is considered to be valid. CRC Error. When set, this bit indicates that a CRC error was detected. This bit is also set when the RX_ER pin is asserted during the reception of a frame even though the CRC may be correct. This bit is not valid if the received frame is a Runt frame, or a late collision was detected or when the Watchdog Time-out occurs. Reserved. These bits are reserved. Reads 0
6 5
4 3 2
1
0
3.14.4
Stopping and Starting the Receiver
To stop the receiver, the host must clear the RXEN bit in the MAC Control Register. When the receiver is halted, the RXSTOP_INT will be pulsed. Once stopped, the host can optionally clear the RX status and RX data FIFOs. The host must re-enable the receiver by setting the RXEN bit.
3.14.5
Receiver Errors
If the Receiver Error (RXE) flag is asserted for any reason, the receiver will continue operation. RX Error (RXE) will be asserted under the following conditions: A host underrun of RX data FIFO A host underrun of the RX status FIFO An overrun of the RX status FIFO It is the duty of the host to identify and resolve any error conditions.
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Chapter 4 Internal Ethernet PHY
4.1 Top Level Functional Description
Functionally, the internal PHY can be divided into the following sections: 100Base-TX transmit and receive 10Base-T transmit and receive Internal MII interface to the Ethernet Media Access Controller Auto-negotiation to automatically determine the best speed and duplex possible Management Control to read status registers and write control registers
TX_CLK
100M PLL
MAC
Internal MII 25 MHz by 4 bits
MII
25MHz by 4 bits
4B/5B Encoder
25MHz by 5 bits
Scrambler and PISO
125 Mbps Serial
NRZI Converter
NRZI
MLT-3 Converter
MLT-3 MLT-3
Tx Driver
MLT-3
Magnetics
RJ45
MLT-3
CAT-5
Figure 4.1 100Base-TX Data Path
4.2
4.2.1
100Base-TX Transmit
The data path of the 100Base-TX is shown in Figure 4.1. Each major block is explained below.
4B/5B Encoding
The transmit data passes from the MII block to the 4B/5B encoder. This block encodes the data from 4-bit nibbles to 5-bit symbols (known as “code-groups”) according to Table 4.1. Each 4-bit data-nibble is mapped to 16 of the 32 possible code-groups. The remaining 16 code-groups are either used for control information or are not valid. The first 16 code-groups are referred to by the hexadecimal values of their corresponding data nibbles, 0 through F. The remaining code-groups are given letter designations with slashes on either side. For example, an IDLE code-group is /I/, a transmit error code-group is /H/, etc. The encoding process may be bypassed by clearing bit 6 of register 31. When the encoding is bypassed the 5th transmit data bit is equivalent to TX_ER.
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Table 4.1 4B/5B Code Table CODE GROUP 11110 01001 10100 10101 01010 01011 01110 01111 10010 10011 10110 10111 11010 11011 11100 11101 11111 11000 10001 01101 RECEIVER INTERPRETATION 0 1 2 3 4 5 6 7 8 9 A B C D E F IDLE First nibble of SSD, translated to “0101” following IDLE, else RX_ER Second nibble of SSD, translated to “0101” following J, else RX_ER First nibble of ESD, causes de-assertion of CRS if followed by /R/, else assertion of RX_ER Second nibble of ESD, causes deassertion of CRS if following /T/, else assertion of RX_ER Transmit Error Symbol INVALID, RX_ER if during RX_DV INVALID, RX_ER if during RX_DV INVALID, RX_ER if during RX_DV INVALID, RX_ER if during RX_DV INVALID, RX_ER if during RX_DV INVALID, RX_ER if during RX_DV INVALID, RX_ER if during RX_DV
57
SYM 0 1 2 3 4 5 6 7 8 9 A B C D E F I J K T
TRANSMITTER INTERPRETATION DATA 0 1 2 3 4 5 6 7 8 9 A B C D E F 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 DATA
0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111
Sent after /T/R until TX_EN Sent for rising TX_EN Sent for rising TX_EN Sent for falling TX_EN
00111
R
Sent for falling TX_EN
00100 00110 11001 00000 00001 00010 00011 00101
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H V V V V V V V
Sent for rising TX_ER INVALID INVALID INVALID INVALID INVALID INVALID INVALID
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Table 4.1 4B/5B Code Table (continued) CODE GROUP 01000 01100 10000 RECEIVER INTERPRETATION INVALID, RX_ER if during RX_DV INVALID, RX_ER if during RX_DV INVALID, RX_ER if during RX_DV INVALID INVALID INVALID TRANSMITTER INTERPRETATION
SYM V V V
4.2.2
Scrambling
Repeated data patterns (especially the IDLE code-group) can have power spectral densities with large narrow-band peaks. Scrambling the data helps eliminate these peaks and spread the signal power more uniformly over the entire channel bandwidth. This uniform spectral density is required by FCC regulations to prevent excessive EMI from being radiated by the physical wiring. The scrambler also performs the Parallel In Serial Out conversion (PISO) of the data.
4.2.3
NRZI and MLT3 Encoding
The scrambler block passes the 5-bit wide parallel data to the NRZI converter where it becomes a serial 125MHz NRZI data stream. The NRZI is encoded to MLT-3. MLT3 is a tri-level code where a change in the logic level represents a code bit “1” and the logic output remaining at the same level represents a code bit “0”.
4.2.4
100M Transmit Driver
The MLT3 data is then passed to the analog transmitter, which launches the differential MLT-3 signal, on outputs TXP and TXN, to the twisted pair media via a 1:1 ratio isolation transformer. The 10BaseT and 100Base-TX signals pass through the same transformer so that common “magnetics” can be used for both. The transmitter drives into the 100Ω impedance of the CAT-5 cable. Cable termination and impedance matching require external components.
4.2.5
100M Phase Lock Loop (PLL)
The 100M PLL locks onto reference clock and generates the 125MHz clock used to drive the 125 MHz logic and the 100Base-Tx Transmitter.
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RX_CLK
100M PLL
MAC
Internal MII 25MHz by 4 bits
MII
25MHz by 4 bits 125 Mbps Serial
4B/5B Decoder
25MHz by 5 bits
Descrambler and SIPO
NRZI Converter
NRZI
MLT-3 Converter
MLT-3
DSP: Timing recovery, Equalizer and BLW Correction
A/D Converter
MLT-3
Magnetics
MLT-3
RJ45
MLT-3
CAT-5
6 bit Data
Figure 4.2 Receive Data Path
4.3
4.3.1
100Base-TX Receive
The receive data path is shown in Figure 4.2. Detailed descriptions are given below.
100M Receive Input
The MLT-3 from the cable is fed into the PHY (on inputs RXP and RXN) via a 1:1 ratio transformer. The ADC samples the incoming differential signal at a rate of 125M samples per second. Using a 64level quanitizer it generates 6 digital bits to represent each sample. The DSP adjusts the gain of the ADC according to the observed signal levels such that the full dynamic range of the ADC can be used.
4.3.2
Equalizer, Baseline Wander Correction and Clock and Data Recovery
The 6 bits from the ADC are fed into the DSP block. The equalizer in the DSP section compensates for phase and amplitude distortion caused by the physical channel consisting of magnetics, connectors, and CAT- 5 cable. The equalizer can restore the signal for any good-quality CAT-5 cable between 1m and 150m. If the DC content of the signal is such that the low-frequency components fall below the low frequency pole of the isolation transformer, then the droop characteristics of the transformer will become significant and Baseline Wander (BLW) on the received signal will result. To prevent corruption of the received data, the PHY corrects for BLW and can receive the ANSI X3.263-1995 FDDI TP-PMD defined “killer packet” with no bit errors. The 100M PLL generates multiple phases of the 125MHz clock. A multiplexer, controlled by the timing unit of the DSP, selects the optimum phase for sampling the data. This is used as the received recovered clock. This clock is used to extract the serial data from the received signal.
4.3.3
NRZI and MLT-3 Decoding
The DSP generates the MLT-3 recovered levels that are fed to the MLT-3 converter. The MLT-3 is then converted to an NRZI data stream.
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4.3.4
Descrambling
The descrambler performs an inverse function to the scrambler in the transmitter and also performs the Serial In Parallel Out (SIPO) conversion of the data. During reception of IDLE (/I/) symbols. the descrambler synchronizes its descrambler key to the incoming stream. Once synchronization is achieved, the descrambler locks on this key and is able to descramble incoming data. Special logic in the descrambler ensures synchronization with the remote PHY by searching for IDLE symbols within a window of 4000 bytes (40us). This window ensures that a maximum packet size of 1514 bytes, allowed by the IEEE 802.3 standard, can be received with no interference. If no IDLEsymbols are detected within this time-period, receive operation is aborted and the descrambler re-starts the synchronization process. The descrambler can be bypassed by setting bit 0 of register 31.
4.3.5
Alignment
The de-scrambled signal is then aligned into 5-bit code-groups by recognizing the /J/K/ Start-of-Stream Delimiter (SSD) pair at the start of a packet. Once the code-word alignment is determined, it is stored and utilized until the next start of frame.
4.3.6
5B/4B Decoding
The 5-bit code-groups are translated into 4-bit data nibbles according to the 4B/5B table. The SSD, /J/K/, is translated to “0101 0101” as the first 2 nibbles of the MAC preamble. Reception of the SSD causes the PHY to assert the internal RX_DV signal, indicating that valid data is available on the Internal RXD bus. Successive valid code-groups are translated to data nibbles. Reception of either the End of Stream Delimiter (ESD) consisting of the /T/R/ symbols, or at least two /I/ symbols causes the PHY to de-assert the internal carrier sense and RX_DV. These symbols are not translated into data.
4.4
10Base-T Transmit
Data to be transmitted comes from the MAC layer controller. The 10Base-T transmitter receives 4-bit nibbles from the MII at a rate of 2.5MHz and converts them to a 10Mbps serial data stream. The data stream is then Manchester-encoded and sent to the analog transmitter, which drives a signal onto the twisted pair via the external magnetics. The 10M transmitter uses the following blocks: MII (digital) TX 10M (digital) 10M Transmitter (analog) 10M PLL (analog)
4.4.1
10M Transmit Data across the internal MII bus
The MAC controller drives the transmit data onto the internal TXD BUS. When the controller has driven TX_EN high to indicate valid data, the data is latched by the MII block on the rising edge of TX_CLK. The data is in the form of 4-bit wide 2.5MHz data.
4.4.2
Manchester Encoding
The 4-bit wide data is sent to the TX10M block. The nibbles are converted to a 10Mbps serial NRZI data stream. The 10M PLL locks onto the external clock or internal oscillator and produces a 20MHz
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clock. This is used to Manchester encode the NRZ data stream. When no data is being transmitted (TX_EN is low), the TX10M block outputs Normal Link Pulses (NLPs) to maintain communications with the remote link partner.
4.4.3
10M Transmit Drivers
The Manchester encoded data is sent to the analog transmitter where it is shaped and filtered before being driven out as a differential signal across the TXP and TXN outputs.
4.5
10Base-T Receive
The 10Base-T receiver gets the Manchester- encoded analog signal from the cable via the magnetics. It recovers the receive clock from the signal and uses this clock to recover the NRZI data stream. This 10M serial data is converted to 4-bit data nibbles which are passed to the controller across the MII at a rate of 2.5MHz. This 10M receiver uses the following blocks: Filter and SQUELCH (analog) 10M PLL (analog) RX 10M (digital) MII (digital)
4.5.1
10M Receive Input and Squelch
The Manchester signal from the cable is fed into the PHY (on inputs RXP and RXN) via 1:1 ratio magnetics. It is first filtered to reduce any out-of-band noise. It then passes through a SQUELCH circuit. The SQUELCH is a set of amplitude and timing comparators that normally reject differential voltage levels below 300mV and detect and recognize differential voltages above 585mV.
4.5.2
Manchester Decoding
The output of the SQUELCH goes to the RX10M block where it is validated as Manchester encoded data. The polarity of the signal is also checked. If the polarity is reversed (local RXP is connected to RXN of the remote partner and vice versa), then this is identified and corrected. The reversed condition is indicated by the flag “XPOL“, bit 4 in register 27. The 10M PLL is locked onto the received Manchester signal and from this, generates the received 20MHz clock. Using this clock, the Manchester encoded data is extracted and converted to a 10MHz NRZI data stream. It is then converted from serial to 4-bit wide parallel data. The RX10M block also detects valid 10Base-T IDLE signals - Normal Link Pulses (NLPs) - to maintain the link.
4.5.3
Jabber Detection
Jabber is a condition in which a station transmits for a period of time longer than the maximum permissible packet length, usually due to a fault condition, that results in holding the TX_EN input for a long period. Special logic is used to detect the jabber state and abort the transmission to the line, within 45ms. Once TX_EN is deasserted, the logic resets the jabber condition.
4.6
Auto-negotiation
The purpose of the Auto-negotiation function is to automatically configure the PHY to the optimum link parameters based on the capabilities of its link partner. Auto-negotiation is a mechanism for exchanging configuration information between two link-partners and automatically selecting the highest performance mode of operation supported by both sides. Auto-negotiation is fully defined in clause 28 of the IEEE 802.3 specification.
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Once auto-negotiation has completed, information about the resolved link can be passed back to the controller via the internal Serial Management Interface (SMI). The results of the negotiation process are reflected in the Speed Indication bits in register 31, as well as the Link Partner Ability Register (Register 5). The auto-negotiation protocol is a purely physical layer activity and proceeds independently of the MAC controller. The advertised capabilities of the PHY are stored in register 4 of the SMI registers. The default advertised by the PHY is determined by user-defined on-chip signal options. The following blocks are activated during an Auto-negotiation session: Auto-negotiation (digital) 100M ADC (analog) 100M PLL (analog) 100M equalizer/BLW/clock recovery (DSP) 10M SQUELCH (analog) 10M PLL (analog) 10M Transmitter (analog) When enabled, auto-negotiation is started by the occurrence of one of the following events: Hardware reset Software reset Power-down reset Link status down Setting register 0, bit 9 high (auto-negotiation restart) On detection of one of these events, the PHY begins auto-negotiation by transmitting bursts of Fast Link Pulses (FLP). These are bursts of link pulses from the 10M transmitter. They are shaped as Normal Link Pulses and can pass uncorrupted down CAT-3 or CAT-5 cable. A Fast Link Pulse Burst consists of up to 33 pulses. The 17 odd-numbered pulses, which are always present, frame the FLP burst. The 16 even-numbered pulses, which may be present or absent, contain the data word being transmitted. Presence of a data pulse represents a “1”, while absence represents a “0”. The data transmitted by an FLP burst is known as a “Link Code Word.” These are defined fully in IEEE 802.3 clause 28. In summary, the PHY advertises 802.3 compliance in its selector field (the first 5 bits of the Link Code Word). It advertises its technology ability according to the bits set in register 4 of the SMI registers. There are 4 possible matches of the technology abilities. In the order of priority these are: 100M full-duplex (Highest priority) 100M half-duplex 10M full-duplex 10M half-duplex If the full capabilities of the PHY are advertised (100M, full-duplex), and if the link partner is capable of 10M and 100M, then auto-negotiation selects 100M as the highest performance mode. If the link partner is capable of half and full-duplex modes, then auto-negotiation selects full-duplex as the highest performance operation. Once a capability match has been determined, the link code words are repeated with the acknowledge bit set. Any difference in the main content of the link code words at this time will cause auto-negotiation to re-start. Auto-negotiation will also re-start if not all of the required FLP bursts are received.
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Writing register 4 bits [8:5] allows software control of the capabilities advertised by the PHY. Writing register 4 does not automatically re-start auto-negotiation. Register 0, bit 9 must be set before the new abilities will be advertised. Auto-negotiation can also be disabled via software by clearing register 0, bit 12. The LAN9218I does not support “Next Page" capability.
4.7
Parallel Detection
If the LAN9218I is connected to a device lacking the ability to auto-negotiate (i.e. no FLPs are detected), it is able to determine the speed of the link based on either 100M MLT-3 symbols or 10M Normal Link Pulses. In this case the link is presumed to be half-duplex per the IEEE standard. This ability is known as “Parallel Detection. This feature ensures inter operability with legacy link partners. If a link is formed via parallel detection, then bit 0 in register 6 is cleared to indicate that the Link Partner is not capable of auto-negotiation. The Ethernet MAC has access to this information via the management interface. If a fault occurs during parallel detection, bit 4 of register 6 is set. Register 5 is used to store the Link Partner Ability information, which is coded in the received FLPs. If the Link Partner is not auto-negotiation capable, then register 5 is updated after completion of parallel detection to reflect the speed capability of the Link Partner.
4.7.1
Re-starting Auto-negotiation
Auto-negotiation can be re-started at any time by setting register 0, bit 9. Auto-negotiation will also restart if the link is broken at any time. A broken link is caused by signal loss. This may occur because of a cable break, or because of an interruption in the signal transmitted by the Link Partner. Autonegotiation resumes in an attempt to determine the new link configuration. If the management entity re-starts Auto-negotiation by writing to bit 9 of the control register, the LAN9218I will respond by stopping all transmission/receiving operations. Once the break_link_timer is done, in the Auto-negotiation state-machine (approximately 1200ms) the auto-negotiation will re-start. The Link Partner will have also dropped the link due to lack of a received signal, so it too will resume auto-negotiation.
4.7.2
Disabling Auto-negotiation
Auto-negotiation can be disabled by setting register 0, bit 12 to zero. The device will then force its speed of operation to reflect the information in register 0, bit 13 (speed) and register 0, bit 8 (duplex). The speed and duplex bits in register 0 should be ignored when auto-negotiation is enabled.
4.7.3
Half vs. Full-Duplex
Half-duplex operation relies on the CSMA/CD (Carrier Sense Multiple Access / Collision Detect) protocol to handle network traffic and collisions. In this mode, the carrier sense signal, CRS, responds to both transmit and receive activity. In this mode, If data is received while the PHY is transmitting, a collision results. In full-duplex mode, the PHY is able to transmit and receive data simultaneously. In this mode, CRS responds only to receive activity. The CSMA/CD protocol does not apply and collision detection is disabled.
4.8
HP Auto-MDIX
HP Auto-MDIX facilitates the use of CAT-3 (10 Base-T) or CAT-5 (100 Base-T) media UTP interconnect cable without consideration of interface wiring scheme. If a user plugs in either a direct connect LAN cable, or a cross-over patch cable, as shown in Figure 4.3, the SMSC LAN9218I Auto-MDIX PHY is capable of configuring the TPO and TPI twisted pair pins for correct transceiver operation.
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The internal logic of the device detects the TX and RX pins of the connecting device. Since the RX and TX line pairs are interchangeable, special PCB design considerations are needed to accommodate the symmetrical magnetics and termination of an Auto-MDIX design. The Auto-MDIX function can be disabled through an internal register 27.15, or the external control pins AMDIX_EN. When disabled the TX and RX pins can be configured with the Channel Select (CH_SELECT) pin as desired.
The figure below shows the signal names at the RJ-45 connector, The mapping of these signals to the pins on the LAN9218I is as follows: TXP = TPO+ TXN = TPORXP = TPI+ RXN = TPI-
Figure 4.3 Direct cable connection vs. Cross-over cable connection.
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Chapter 5 Register Description
The following section describes all LAN9218I registers and data ports.
FCh
RESERVED
B4h B0h ACh A8h A4h A0h
EEPROM Port
MAC CSRPort
50h 4Ch 48h 44h 40h 3Ch
TX Status TX Status RX Status RX Status
FIFO PEEK FIFO Port FIFO PEEK FIFO Port
TX Data FIFO Alias Ports 24h 20h 1Ch
TX Data FIFO Port
RX Data FIFO Alias Ports 04h Base + 00h
RX Data FIFO Port
Figure 5.1 Memory Map
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5.1
SYMBOL RO WO R/W R/WC RC LL LH SC NASR Reserved Bits Reserved Registers Default States
Register Nomenclature and Access Attributes
DESCRIPTION Read Only: If a register is read only, writes to this register have no effect. Write Only: If a register is write only, reads always return 0. Read/Write: A register with this attribute can be read and written Read/Write Clear: A register bit with this attribute can be read and written. However, a write of a 1 clears (sets to 0) the corresponding bit and a write of a 0 has no effect. Read to Clear: A register bit with this attribute is cleared when read. Latch Low: Clear on read of register Latch High: Clear on read of register Self-Clearing Not Affected by Software Reset Certain bits within registers are listed as “Reserved”. Unless stated otherwise, these bits must be written with zeros for future compatibility. The values of these bits are not guaranteed when read. Certain configuration registers within the LAN9218I are listed as “Reserved”. These registers are not guaranteed to return any particular value when read. These registers must not be written to or modified by system failure; doing so could result in failure of the device and system. At Reset - System reset, Software Reset, or POR - internal registers are set to their default states. The default states provide a minimum level of functionality needed to successfully bring up a system, but do not necessarily provide desired or optimal configuration of the device. It is the responsibility of the system initialization software to properly determine the operating parameters and optional system features that are applicable, and to program the LAN9218I registers accordingly.
5.2
RX and TX FIFO Ports
The LAN9218I contains four host-accessible FIFOs: RX Status, RX Data, TX Status, and TX Data FIFOs. The sizes Data FIFOs and the RX Status FIFO are configurable through the CSRs.
5.2.1
RX FIFO Ports
The RX Data Path contains two Read-Only FIFOs: RX Status and RX Data. The RX Status FIFO has two ports at different address locations. The RX Status FIFO Port causes the top of the RX Status FIFO to be “popped”, and is destructive. The RX Status FIFO PEEK Port allows the top of the RX Status FIFO to be read without “popping” it. The RX Data FIFO has a single port; reading data from this port always causes the top of the RX Data FIFO to be “popped”. This port is aliased to 8 DWORD (in 32-bit mode) or 16 DWORD locations (in 16-bit mode). The host may access the top of the RX Data FIFO through any of these locations.
5.2.2
TX FIFO Ports
The TX Data Path consists of two FIFOs, TX Status and RX Data. The TX Status FIFO also has two ports at different locations. When the TX Status FIFO Port is read, the top of the TX Status FIFO is popped. When the TX Status FIFO PEEK Port is read, the top of the TX Status FIFO is not popped. The TX data FIFO is Write Only. It is aliased to 8 DWORD (in 32-bit mode) or 16 DWORD locations (in 16-bit mode). The host may access the top of the TX Data FIFO through any of these locations.
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5.3
System Control and Status Registers
Table 5.1, "Direct Address Register Map", lists the registers that are directly addressable by the host bus. Table 5.1 Direct Address Register Map CONTROL AND STATUS REGISTERS
BASE ADDRESS + OFFSET 50h 54h 58h 5Ch 60h 64h 68h 6Ch 70h 74h 78h 7Ch 80h 84h 88h 8Ch 90h 94h 98h 9Ch A0h A4h A8h ACh B0h B4h B8h - FCh
SMSC LAN9218I
SYMBOL ID_REV IRQ_CFG INT_STS INT_EN RESERVED BYTE_TEST FIFO_INT RX_CFG TX_CFG HW_CFG RX_DP_CTL RX_FIFO_INF TX_FIFO_INF PMT_CTRL GPIO_CFG GPT_CFG GPT_CNT RESERVED WORD-SWAP FREE_RUN RX_DROP MAC_CSR_CMD MAC_CSR_DATA AFC_CFG E2P_CMD E2P_DATA RESERVED
REGISTER NAME Chip ID and Revision. Main Interrupt Configuration Interrupt Status Interrupt Enable Register Reserved for future use Read-only byte order testing register FIFO Level Interrupts Receive Configuration Transmit Configuration Hardware Configuration RX Datapath Control Receive FIFO Information Transmit FIFO Information Power Management Control General Purpose IO Configuration General Purpose Timer Configuration General Purpose Timer Count Reserved for future use WORD SWAP Register Free Run Counter RX Dropped Frames Counter MAC CSR Synchronizer Command (MAC CSR’s are indexed through this register) MAC CSR Synchronizer Data Automatic Flow Control Configuration EEPROM Command EEPROM Data Reserved for future use
67
DEFAULT See Page 68. 00000000h 00000000h 00000000h 87654321h 48000000h 00000000h 00000000h 00000800h 00000000h 00000000h 00001200h 00000000h 00000000h 0000FFFFh 0000FFFFh 00000000h 00000000h 00000000h 00000000h 00000000h 00000000h 00000000h Revision 1.5 (07-18-06)
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5.3.1
ID_REV—Chip ID and Revision
Offset: 50h Size: 32 bits
This register contains the ID and Revision fields for this design.
BITS 31-16 15-0
DESCRIPTION Chip ID. This read-only field identifies this design Chip Revision
TYPE RO RO
DEFAULT 118Ah 0000h
5.3.2
IRQ_CFG—Interrupt Configuration Register
Offset: 54h Size: 32 bits
This register configures and indicates the state of the IRQ signal. BITS 31:24 DESCRIPTION Interrupt Deassertion Interval (INT_DEAS). This field determines the Interrupt Request Deassertion Interval in multiples of 10 microseconds. Setting this field to zero causes the device to disable the INT_DEAS Interval, reset the interval counter, and issue any pending interrupts. If a new, non-zero value is written to this field, any subsequent interrupts will obey the new setting. Note: 23-15 14 This field does not apply to the PME interrupt. RO TYPE R/W DEFAULT 0
Reserved Interrupt Deassertion Interval Clear (INT_DEAS_CLR). Writing a one to this register clears the de-assertion counter in the IRQ Controller, thus causing a new de-assertion interval to begin (regardless of whether or not the IRQ Controller is currently in an active de-assertion interval). Interrupt Deassertion Status (INT_DEAS_STS). When set, this bit indicates that interrupts are currently in a deassertion interval, and will not be delivered to the IRQ pin. When this bit is clear, interrupts are not currently in a deassertion interval, and will be delivered to the IRQ pin. Master Interrupt (IRQ_INT). This read-only bit indicates the state of the internal IRQ line, regardless of the setting of the IRQ_EN bit, or the state of the interrupt de-assertion function. When this bit is high, one of the enabled interrupts is currently active. Reserved IRQ Enable (IRQ_EN) – This bit controls the final interrupt output to the IRQ pin. When clear, the IRQ output is disabled and permanently deasserted. This bit has no effect on any internal interrupt status bits. Reserved IRQ Polarity (IRQ_POL) – When cleared, enables the IRQ line to function as an active low output. When set, the IRQ output is active high. When IRQ is configured as an open-drain output this field is ignored, and the interrupt output is always active low.
13
SC
0
12
RO
0
11-9 8
RO R/W
0
7-5 4
RO R/W NASR
0
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BITS 3-1 0 Reserved
DESCRIPTION
TYPE RO R/W NASR
DEFAULT 0
IRQ Buffer Type (IRQ_TYPE) – When cleared, enables IRQ to function as an open-drain buffer for use in a Wired-Or Interrupt configuration. When set, the IRQ output is a Push-Pull driver. When configured as an open-drain output the IRQ_POL field is ignored, and the interrupt output is always active low.
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5.3.3
INT_STS—Interrupt Status Register
Offset: 58h Size: 32 bits
This register contains the current status of the generated interrupts. Writing a 1 to the corresponding bits acknowledges and clears the interrupt. BITS 31 30-26 25 24 23 DESCRIPTION Software Interrupt (SW_INT). This interrupt is generated when the SW_INT_EN bit is set high. Writing a one clears this interrupt. Reserved TX Stopped (TXSTOP_INT). This interrupt is issued when STOP_TX bit in TX_CFG is set, and the transmitter is halted. RX Stopped (RXSTOP_INT). This interrupt is issued when the receiver is halted. RX Dropped Frame Counter Halfway (RXDFH_INT). This interrupt is issued when the RX Dropped Frames Counter counts past its halfway point (7FFFFFFFh to 80000000h). Reserved TX IOC Interrupt (TX_IOC). When a buffer with the IOC flag set has finished being loaded into the TX FIFO, this interrupt is generated. RX DMA Interrupt (RXD_INT). This interrupt is issued when the amount of data programmed in the RX DMA Count (RX_DMA_CNT) field of the RX_CFG register has been transferred out of the RX FIFO. GP Timer (GPT_INT). This interrupt is issued when the General Purpose timer wraps past zero to FFFFh. PHY (PHY_INT). Indicates a PHY Interrupt event. Power Management Event Interrupt (PME_INT). This interrupt is issued when a Power Management Event is detected as configured in the PMT_CTRL register. This interrupt functions independent of the PME signal, and will still function if the PME signal is disabled. Writing a '1' clears this bit regardless of the state of the PME hardware signal. Notes: Detection of a Power Management Event, and assertion of the PME signal will not wakeup the LAN9218I. The LAN9218I will only wake up when it detects a host write cycle of any data to the BYTE_TEST register. The Interrupt Deassertion interval does not apply to the PME interrupt. FIFO overflows. TYPE R/WC RO R/WC R/WC R/WC DEFAULT 0 0 0 0
22 21 20
RO R/WC R/WC
0 0 0
19 18 17
R/WC RO R/WC
0 0 0
16 15 14
TX Status FIFO Overflow (TXSO). Generated when the TX Status Receive Watchdog Time-out (RWT). Interrupt is generated when a
packet larger than 2048 bytes has been received.
R/WC R/WC R/WC
0 0 0
Receiver Error (RXE). Indicates that the receiver has encountered an
error. Please refer to Section 3.14.5, "Receiver Errors," on page 55 for a description of the conditions that will cause an RXE.
13
Transmitter Error (TXE). When generated, indicates that the
transmitter has encountered an error. Please refer to Section 3.13.8, "Transmitter Errors," on page 50, for a description of the conditions that will cause a TXE.
R/WC
0
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BITS 12 11 10 9 8 7 6 5 4 3 2-0 Reserved
DESCRIPTION
TYPE RO R/WC R/WC R/WC R/WC R/WC R/WC R/WC R/WC R/WC R/WC
DEFAULT 0 0 0 0 0 0 0 0 0 000
TX Data FIFO Underrun Interrupt (TDFU). Generated when the TX data FIFO underruns. TX Data FIFO Overrun Interrupt (TDFO). Generated when the TX data FIFO is full, and another write is attempted. TX Data FIFO Available Interrupt (TDFA). Generated when the TX data FIFO available space is greater than the programmed level. TX Status FIFO Full Interrupt (TSFF). Generated when the TX Status FIFO is full. TX Status FIFO Level Interrupt (TSFL). Generated when the TX Status FIFO reaches the programmed level. RX Dropped Frame Interrupt (RXDF_INT). This interrupt is issued whenever a receive frame is dropped. RX Data FIFO Level Interrupt (RDFL). Generated when the RX FIFO reaches the programmed level. RX Status FIFO Full Interrupt (RSFF). Generated when the RX Status FIFO is full. RX Status FIFO Level Interrupt (RSFL). Generated when the RX Status FIFO reaches the programmed level. GPIO [2:0] (GPIOx_INT). Interrupts are generated from the GPIO’s. These interrupts are configured through the GPIO_CFG register.
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5.3.4
INT_EN—Interrupt Enable Register
Offset: 5Ch Size: 32 bits
This register contains the interrupt masks for IRQ. Writing 1 to any of the bits enables the corresponding interrupt as a source for IRQ. Bits in the INT_STS register will still reflect the status of the interrupt source regardless of whether the source is enabled as an interrupt in this register. BITS 31 30:26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2-0 DESCRIPTION Software Interrupt (SW_INT_EN) Reserved TX Stopped Interrupt Enable (TXSTOP_INT_EN) RX Stopped Interrupt Enable (RXSTOP_INT_EN) RX Dropped Frame Counter Halfway Interrupt Enable (RXDFH_INT_EN). Reserved TX IOC Interrupt Enable (TIOC_INT_EN) RX DMA Interrupt (RXD_INT). GP Timer (GPT_INT_EN) PHY (PHY_INT_EN) Power Management Event Interrupt Enable (PME_INT_EN) TX Status FIFO Overflow (TXSO_EN) Receive Watchdog Time-out Interrupt (RWT_INT_EN) Receiver Error Interrupt (RXE_INT_EN) Transmitter Error Interrupt (TXE_INT_EN) Reserved TX Data FIFO Underrun Interrupt (TDFU_INT_EN) TX Data FIFO Overrun Interrupt (TDFO_INT_EN) TX Data FIFO Available Interrupt (TDFA_INT_EN) TX Status FIFO Full Interrupt (TSFF_INT_EN) TX Status FIFO Level Interrupt (TSFL_INT_EN) RX Dropped Frame Interrupt Enable (RXDF_INT_EN) RX Data FIFO Level Interrupt (RDFL_INT_EN) RX Status FIFO Full Interrupt (RSFF_INT_EN) RX Status FIFO Level Interrupt (RSFL_INT_EN) GPIO [2:0] (GPIOx_INT_EN). TYPE R/W RO R/W R/W R/W RO R/W R/W R/W R/W R/W R/W R/W R/W R/W RO R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W DEFAULT 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 000
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5.3.5
BYTE_TEST—Byte Order Test Register
Offset: 64h Size: 32 bits
This register can be used to determine the byte ordering of the current configuration
BITS 31:0 Byte Test
DESCRIPTION
TYPE RO
DEFAULT 87654321h
5.3.6
FIFO_INT—FIFO Level Interrupts
Offset: 68h Size: 32 bits
This register configures the limits where the FIFO Controllers will generate system interrupts.
BITS 31-24
DESCRIPTION TX Data Available Level. The value in this field sets the level, in number of 64 Byte blocks, at which the TX FIFO Available interrupt (TFDA) will be generated. When the TX data FIFO free space is greater than this value a TX FIFO Available interrupt (TDFA) will be generated. TX Status Level. The value in this field sets the level, in number of DWORDs, at which the TX Status FIFO Level interrupt (TSFL) will be generated. When the TX Status FIFO used space is greater than this value an TX Status FIFO Level interrupt (TSFL) will be generated. RX Space Available Level. The value in this field sets the level, in number of 64 Byte blocks, at which the RX data FIFO Level interrupt (RDFL) will be generated. When the RX data FIFO free space is less than this value an RX data FIFO Level interrupt (RDFL) will be generated. RX Status Level. The value in this field sets the level, in number of DWORDs, at which the RX Status FIFO Level interrupt (RSFL) will be generated. When the RX Status FIFO used space is greater than this value an RX Status FIFO Level interrupt (RSFL) will be generated.
TYPE R/W
DEFAULT 48h
23-16
R/W
00h
15-8
R/W
00h
7-0
R/W
00h
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5.3.7
RX_CFG—Receive Configuration Register
Offset: 6Ch Size: 32 bits
This register controls the LAN9218I receive engine. BITS 31:30 DESCRIPTION RX End Alignment. This field specifies the alignment that must be maintained on the last data transfer of a buffer. The LAN9218I will add extra DWORDs of data up to the alignment specified in the table below. The host is responsible for removing these extra DWORDs. This mechanism can be used to maintain cache line alignment on host processors. Please refer to Table 5.2 for bit definitions Note: The desired RX End Alignment must be set before reading a packet. The RX end alignment can be changed between reading receive packets, but must not be changed if the packet is partially read. RO R/W 000h TYPE R/W DEFAULT 00b
29-28 27-16
Reserved RX DMA Count (RX_DMA_CNT). This 12-bit field indicates the amount of data, in DWORDS, to be transferred out of the RX data FIFO before asserting the RXD_INT. After being set, this field is decremented for each DWORD of data that is read from the RX data FIFO. This field can be overwritten with a new value before it reaches zero. Force RX Discard (RX_DUMP). This self-clearing bit clears the RX data and status FIFOs of all pending data. When a ‘1’ is written, the RX data and status pointers are cleared to zero. Note: Please refer to section “Force Receiver Discard (Receiver Dump)” on page 53 for a detailed description regarding the use of RX_DUMP.
15
SC
0
14-13 12-8
Reserved RX Data Offset (RXDOFF). This field controls the offset value, in bytes, that is added to the beginning of an RX data packet. The start of the valid data will be shifted by the number of bytes specified in this field. An offset of 0-31 bytes is a valid number of offset bytes. Note: The two LSBs of this field (D[9:8]) must not be modified while the RX is running. The receiver must be halted, and all data purged before these two bits can be modified. The upper three bits (DWORD offset) may be modified while the receiver is running. Modifications to the upper bits will take affect on the next DWORD read.
RO R/W
00000
7-0
Reserved Table 5.2 RX Alignment Bit Definitions [31] 0 0 1 1 [30] 0 1 0 1 End Alignment 4-byte alignment 16-byte alignment 32-byte alignment Reserved
RO
-
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5.3.8
TX_CFG—Transmit Configuration Register
Offset: 70h Size: 32 bits
This register controls the transmit functions on the LAN9218I Ethernet Controller.
BITS 31-16 15 Reserved.
DESCRIPTION
TYPE RO SC
DEFAULT 0
Force TX Status Discard (TXS_DUMP). This self-clearing bit clears the TX status FIFO of all pending status DWORD’s. When a ‘1’ is written, the TX status pointers are cleared to zero. Force TX Data Discard (TXD_DUMP). This self-clearing bit clears the TX data FIFO of all pending data. When a ‘1’ is written, the TX data pointers are cleared to zero. Reserved TX Status Allow Overrun (TXSAO). When this bit is cleared, data transmission is suspended if the TX Status FIFO becomes full. Setting this bit high allows the transmitter to continue operation with a full TX Status FIFO. Note: This bit does not affect the operation of the TX Status FIFO Full interrupt.
14
SC
0
13-3 2
RO R/W
0
1
Transmitter Enable (TX_ON). When this bit is set (1), the transmitter is enabled. Any data in the TX FIFO will be sent. This bit is cleared automatically when STOP_TX is set and the transmitter is halted. Stop Transmitter (STOP_TX). When this bit is set (1), the transmitter will finish the current frame, and will then stop transmitting. When the transmitter has stopped this bit will clear. All writes to this bit are ignored while this bit is high.
R/W
0
0
SC
0
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Datasheet
5.3.9
HW_CFG—Hardware Configuration Register
Offset: 74h Size: 32 bits
BITS 31-25 24 Reserved
DESCRIPTION
TYPE RO RO
DEFAULT AMDIX Strap Pin
AMDIX_EN Strap State. This read-only bit reflects the state of the AMDIX_EN strap pin (pin 73). This pin can be overridden by PHY Registers 27.15 and 27.13 Reserved Transmit Threshold Mode (TTM). This bit is used to control the transmit threshold the MIL uses as shown in the two tables in the TR field of this register. This bit is ignored when the SF bit is set (1). This bit should be set to '1' when operating in 10Mbps mode, and cleared to '0' when operating in 100Mbps mode if the SF bit cleared.
23-22 21
RO R/W 0
20
Store and Forward (SF). When set, this bit instructs the MIL to store a frame of transmit data in the MIL buffer before forwarding to its final destination. If this bit is set, the MIL buffers the entire frame before transmitting. TTM and TR (see bits 21,13, and 12) are treated as Don’t Cares once the SF mode is selected. If this bit is reset, the MAC initiates transmission before it receives the entire frame from the HBI (Host Bus Interface). TTM and TR (see bit 21,13, and 12) determine when the MIL initiates the transmission. If the host cannot keep up with the MAC transmitting the Ethernet Packet, there is a risk of an Underrun Error.
R/W
0
16-19
TX FIFO Size (TX_FIF_SZ). Sets the size of the TX FIFOs in 1KB values to a maximum of 14KB. The TX Status FIFO consumes 512 bytes of the space allocated by TX_FIF_SIZ, and the TX data FIFO consumes the remaining space specified by TX_FIF_SZ. The minimum size of the TX FIFOs is 2KB (TX data and status combined). The TX data FIFO is used for both TX data and TX commands. The RX status and data FIFOs consume the remaining space, which is equal to 16KB – TX_FIF_SIZ. See section 5.3.9.1 Allowable settings for Configurable FIFO Memory Allocationon page 78 for more information.
R/W
5h
15-14
Reserved
RO
-
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Datasheet
BITS 13-12
DESCRIPTION Threshold Control Bits (TR). These control the transmit threshold values the MIL should use. These bits are used when the SF bit is reset. The host can program the Transmit threshold by setting these bits. The intent is to allow the MIL to transfer data to the final destination only after the threshold value is met. In 10Mbps mode (TTM = 1) the threshold is set as follows:
TYPE R/W
DEFAULT 00
[13] 0
[12]
Threshold (DWORDS)
0 1 0 1
012h 018h 020h 028h
0 1 1
In 100Mbps mode (TTM = 0) the threshold is set by as follows:
[13] 0
[12]
Threshold (DWORDS)
0 1 0 1
020h 040h 080h 100h
0 1 1
11-3 2
Reserved 32/16-bit Mode. When set, the LAN9218I is set for 32-bit operation. When clear, it is configured for 16-bit operation. This field is the value of the D32/nD16 strap. Soft Reset Time-out (SRST_TO). If a software reset is attempted when the internal PHY is not in the operational state (RX_CLK and TX_CLK running), the reset will not complete and the soft reset operation will time-out and this bit will be set to a ‘1’. The host processor must correct the problem and issue another soft reset. Soft Reset (SRST). Writing 1 generates a software initiated reset. This reset generates a full reset of the MAC CSR’s. The SCSR’s (system command and status registers) are reset except for any NASR bits. Soft reset also clears any TX or RX errors (TXE/RXE). This bit is self-clearing. Notes: Do not attempt a soft reset unless the internal PHY is fully awake and operational. After a PHY reset, or when returning from a reduced power state, the PHY must be given adequate time to return to the operational state before a soft reset can be issued. The internal RX_CLK and TX_CLK signals must be running for a proper software reset. Please refer to Section 6.8, "Reset Timing," on page 123 for details on PHY reset timing. The LAN9218I must always be read at least once after power-up, reset, or upon return from a power-saving state or write operations will not function.
RO RO
-
1
RO
0
0
SC
0
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Datasheet
5.3.9.1
Allowable settings for Configurable FIFO Memory Allocation
TX and RX FIFO space is configurable through the CSR - HW_CFG register defined above. The user must select the FIFO allocation by setting the TX FIFO Size (TX_FIF_SZ) field in the hardware configuration (HW_CFG) register. The TX_FIF_SZ field selects the total allocation for the TX data path, including the TX Status FIFO size. The TX Status FIFO size is fixed at 512 Bytes (128 TX Status DWORDs). The TX Status FIFO length is subtracted from the total TX FIFO size with the remainder being the TX data FIFO Size. Note that TX data FIFO space includes both commands and payload data. RX FIFO Size is the remainder of the unallocated FIFO space (16384 bytes – TX FIFO Size). The RX Status FIFO size is always equal to 1/16 of the RX FIFO Size. The RX Status FIFO length is subtracted from the total RX FIFO size with the remainder being the RX data FIFO Size. For example, if TX_FIF_SZ = 6 then: Total TX FIFO Size = 6144 Bytes (6KB) TX Status FIFO Size = 512 Bytes (Fixed) TX Data FIFO Size = 6144 – 512 = 5632 Bytes RX FIFO Size = 16384 – 6144 = 10240 Bytes (10KB) RX Status FIFO Size = 10240 / 16 = 640 Bytes (160 RX Status DWORDs) RX Data FIFO Size = 10240 – 640 = 9600 Bytes Table 5.3 shows every valid setting for the TX_FIF_SZ field. Note that settings not shown in this table are reserved and should not be used. Note: The RX data FIFO is considered full 4 DWORDs before the length that is specified in the HW_CFG register. Table 5.3 Valid TX/RX FIFO Allocations TX DATA FIFO SIZE (BYTES) 1536 2560 3584 4608 5632 6656 7680 8704 9728 10752 11776 12800 13824 TX STATUS FIFO SIZE (BYTES) 512 512 512 512 512 512 512 512 512 512 512 512 512 RX DATA FIFO SIZE (BYTES) 13440 12480 11520 10560 9600 8640 7680 6720 5760 4800 3840 2880 1920 RX STATUS FIFO SIZE (BYTES) 896 832 768 704 640 576 512 448 384 320 256 192 128
TX_FIF_SZ 2 3 4 5 6 7 8 9 10 11 12 13 14
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Datasheet
In addition to the host-accessible FIFOs, the MAC Interface Layer (MIL) contains an additional 2K bytes of TX, and 128 bytes of RX FIFO buffering. These sizes are fixed, and cannot be adjusted by the host. As space in the TX MIL (Mac Interface Layer) FIFO frees, data is moved into it from the TX data FIFO. Depending on the size of the frames to be transmitted, the MIL can hold up to two Ethernet frames. This is in addition to any TX data that may be queued in the TX data FIFO. Conversely, as data is received by the LAN9218I, it is moved from the MAC to the RX MIL FIFO, and then into the RX data FIFO. When the RX data FIFO fills up, data will continue to collect in the RX MIL FIFO. If the RX MIL FIFO fills up and overruns, subsequent RX frames will be lost until room is made in the RX data FIFO. For each frame of data that is lost, the RX Dropped Frames Counter (RX_DROP) is incremented. RX and TX MIL FIFO levels are not visible to the host processor. RX and TX MIL FIFOs operate independent of the TX data and RX data and status FIFOs. FIFO levels set for the RX and TX data and Status FIFOs do not take into consideration the MIL FIFOs.
5.3.10
RX_DP_CTRL—Receive Datapath Control Register
Offset: 78h Size: 32 bits
This register is used to discard unwanted receive frames.
BITS 31
DESCRIPTION RX Data FIFO Fast Forward (RX_FFWD): Writing a ‘1’ to this bit causes the RX data FIFO to fast-forward to the start of the next frame. This bit will remain high until the RX data FIFO fast-forward operation has completed. No reads should be issued to the RX data FIFO while this bit is high. Note: Please refer to section “Receive Data FIFO Fast Forward” on page 52 for detailed information regarding the use of RX_FFWD.
TYPE R/W
DEFAULT 0h
30-0
Reserved
RO
-
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High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
5.3.11
RX_FIFO_INF—Receive FIFO Information Register
Offset: 7Ch Size: 32 bits
This register contains the used space in the receive FIFOs of the LAN9218I Ethernet Controller.
BITS 31-24 23-16 15-0 Reserved
DESCRIPTION
TYPE RO RO RO
DEFAULT 00h 0000h
RX Status FIFO Used Space (RXSUSED). Indicates the amount of space in DWORDs, used in the RX Status FIFO. RX Data FIFO Used Space (RXDUSED).). Reads the amount of space in bytes, used in the RX data FIFO. For each receive frame, this field is incremented by the length of the receive data rounded up to the nearest DWORD (if the payload does not end on a DWORD boundary).
5.3.12
TX_FIFO_INF—Transmit FIFO Information Register
Offset: 80h Size: 32 bits
This register contains the free space in the transmit data FIFO and the used space in the transmit status FIFO in the LAN9218I.
BITS 31-24 23-16 15-0 Reserved
DESCRIPTION
TYPE RO RO RO
DEFAULT 00h 1200h
TX Status FIFO Used Space (TXSUSED). Indicates the amount of space in DWORDS used in the TX Status FIFO. TX Data FIFO Free Space (TDFREE). Reads the amount of space in bytes, available in the TX data FIFO. The application should never write more data than is available, as indicated by this value.
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80
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High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
5.3.13
PMT_CTRL— Power Management Control Register
Offset: 84h Size: 32 bits
This register controls the Power Management features. This register can be read while the LAN9218I is in a power saving mode.
Note: The LAN9218I must always be read at least once after power-up, reset, or upon return from a power-saving state or write operations will not function. BITS 31:14 13-12 RESERVED Power Management Mode (PM_MODE) – These bits set the LAN9218I into the appropriate Power Management mode. Special care must be taken when modifying these bits. Encoding: 00b – D0 (normal operation) 01b – D1 (wake-up frame and magic packet detection are enabled) 10b – D2 (can perform energy detect) 11b – RESERVED - Do not set in this mode Note: When the LAN9218I is in any of the reduced power modes, a write of any data to the BYTE_TEST register will wake-up the device. DO NOT PERFORM WRITES TO OTHER ADDRRESSES while the READY bit in this register is cleared. RO SC 0b DESCRIPTION TYPE RO SC DEFAULT 00b
11 10
RESERVED PHY Reset (PHY_RST) – Writing a ‘1’ to this bit resets the PHY. The internal logic automatically holds the PHY reset for a minimum of 100us. When the PHY is released from reset, this bit is automatically cleared. All writes to this bit are ignored while this bit is high. Wake-On-Lan Enable (WOL_EN) – When set, the PME signal (if enabled with PME_EN) will be asserted in accordance with the PME_IND bit upon a WOL event. When set, the PME_INT will also be asserted upon a WOL event, regardless of the setting of the PME_EN bit. Energy-Detect Enable (ED_EN) - When set, the PME signal (if enabled with PME_EN) will be asserted in accordance with the PME_IND bit upon an Energy-Detect event. When set, the PME_INT will also be asserted upon an Energy Detect event, regardless of the setting of the PME_EN bit. RESERVED PME Buffer Type (PME_TYPE) – When cleared, enables PME to function as an open-drain buffer for use in a Wired-Or configuration. When set, the PME output is a Push-Pull driver. When configured as an open-drain output the PME_POL field is ignored, and the output is always active low.
9
R/W
0b
8
R/W
0b
7 6
RO R/W NASR
0b
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Datasheet
BITS 5-4
DESCRIPTION WAKE-UP Status (WUPS) – This field indicates the cause of a wake-up event detection as follows 00b -- No wake-up event detected 01b -- Energy detected 10b -- Wake-up frame or magic packet detected 11b -- Indicates multiple events occurred WUPS bits are cleared by writing a ‘1’ to the appropriate bit. The device must return to the D0 state (READY bit set) before these bits can be cleared. Note: In order to clear this bit, it is required that all event sources be cleared as well. The event sources are described in Figure 3.10 PME and PME_INT Signal Generationon page 38.
TYPE R/WC
DEFAULT 00
3
PME indication (PME_IND). The PME signal can be configured as a pulsed output or a static signal, which is asserted upon detection of a wake-up event. When set, the PME signal will pulse active for 50mS upon detection of a wake-up event. When clear, the PME signal is driven continuously upon detection of a wakeup event. The PME signal can be deactivated by clearing the WUPS bits, or by clearing the appropriate enable (refer to Section 3.11.2.3, "Power Management Event Indicators," on page 38).
R/W
0b
2
PME Polarity (PME_POL). This bit controls the polarity of the PME signal. When set, the PME output is an active high signal. When reset, it is active low. When PME is configured as an open-drain output this field is ignored, and the output is always active low. PME Enable (PME_EN). When set, this bit enables the external PME signal. This bit does not affect the PME interrupt (PME_INT). Device Ready (READY). When set, this bit indicates that LAN9218I is ready to be accessed. This register can be read when LAN9218I is in any power management mode. Upon waking from any power management mode, including power-up, the host processor can interrogate this field as an indication when LAN9218I has stabilized and is fully alive. Reads and writes of any other address are invalid until this bit is set. Note: With the exception of HW_CFG and PMT_CTRL, read access to any internal resources is forbidden while the READY bit is cleared.
R/W NASR
0b
1 0
R/W RO
0b -
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High-Performance Single-Chip 10/100 Ethernet Controller with HP Auto-MDIX & Industrial Temperature Support
Datasheet
5.3.14
GPIO_CFG—General Purpose IO Configuration Register
Offset: 88h Size: 32 bits
This register configures the GPIO and LED functions. BITS 31 30:28 Reserved LED[3:1] enable (LEDx_EN). A ‘1’ sets the associated pin as an LED output. When cleared low, the pin functions as a GPIO signal. LED1/GPIO0 – bit 28 LED2/GPIO1 – bit 29 LED3/GPIO2 – bit 30 Reserved GPIO Interrupt Polarity 0-2 (GPIO_INT_POL). When set high, a high logic level on the corresponding GPIO pin will set the corresponding INT_STS register bit. When cleared low, a low logic level on the corresponding GPIO pin will set the corresponding INT_STS register bit. GPIO Interrupts must also be enabled in GPIOx_INT_EN in the INT_EN register. GPIO0 – bit 24 GPIO1 – bit 25 GPIO2 – bit 26 Note: 23 22:20 GPIO inputs must be active for greater than 40nS to be recognized as interrupt inputs. RO R/W 000 DESCRIPTION TYPE RO R/W DEFAULT 000
27 26:24
RO R/W
000
Reserved EEPROM Enable (EEPR_EN). The value of this field determines the function of the external EEDIO and EECLK: Please refer to Table 5.4 for the EEPROM Enable bit function definitions. Note: The host must not change the function of the EEDIO and EECLK pins when an EEPROM read or write cycle is in progress. Do not use reserved settings.
19 18:16
Reserved GPIO Buffer Type 0-2 (GPIOBUFn). When set, the output buffer for the corresponding GPIO signal is configured as a push/pull driver. When cleared, the corresponding GPIO set configured as an open-drain driver. GPIO0 – bit 16 GPIO1 – bit 17 GPIO2 – bit 18 Reserved GPIO Direction 0-2 (GPDIRn). When set, enables the corresponding GPIO as output. When cleared the GPIO is enabled as an input. GPIO0 – bit 8 GPIO1 – bit 9 GPIO2 – bit 10 Reserved GPO Data 3-4 (GPODn). The value written is reflected on GPOn. GPO3 – bit 3 GPO4 – bit 4
RO R/W
000
15:11 10:8
RO R/W
0000
7:5 4:3
RO R/W
00
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BITS 2:0
DESCRIPTION GPIO Data 0-2 (GPIODn). When enabled as an output, the value written is reflected on GPIOn. When read, GPIOn reflects the current state of the corresponding GPIO pin. GPIO0 – bit 0 GPIO1 – bit 1 GPIO2 – bit 2
TYPE R/W
DEFAULT 000
Table 5.4 EEPROM Enable Bit Definitions [22] 0 0 0 0 1 1 1 1 [21] 0 0 1 1 0 0 1 1 [20] 0 1 0 1 0 1 0 1 TX_EN TX_EN TX_CLK GPO3 Reserved GPO4 RX_DV RX_CLK EEDIO FUNCTION EEDIO GPO3 Reserved RX_DV EECLK FUNCTION EECLK GPO4
5.3.15
GPT_CFG-General Purpose Timer Configuration Register
Offset: 8Ch Size: 32 bits
This register configures the General Purpose timer. The GP Timer can be configured to generate host interrupts at intervals defined in this register.
BITS 31-30 29 Reserved
DESCRIPTION
TYPE RO R/W
DEFAULT 0
GP Timer Enable (TIMER_EN). When a one is written to this bit the GP Timer is put into the run state. When cleared, the GP Timer is halted. On the 1 to 0 transition of this bit the GPT_LOAD field will be preset to FFFFh. Reserved General Purpose Timer Pre-Load (GPT_LOAD). This value is pre-loaded into the GP-Timer.
28-16 15-0
RO R/W
FFFFh
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Datasheet
5.3.16
GPT_CNT-General Purpose Timer Current Count Register
Offset: 90h Size: 32 bits
This register reflects the current value of the GP Timer.
BITS 31-16 15-0 Reserved
DESCRIPTION
TYPE RO RO
DEFAULT FFFFh
General Purpose Timer Current Count (GPT_CNT). This 16-bit field reflects the current value of the GP Timer.
5.3.17
WORD SWAP—Word Swap Control
Offset: 98h Size: 32 bits
This register controls how words from the host data bus are mapped to the CSRs and Data FIFOs inside the LAN9218I. The LAN9218I always sends data from the Transmit Data FIFO to the network so that the low order word is sent first, and always receives data from the network to the Receive Data FIFO so that the low order word is received first.
BITS 31:0
DESCRIPTION Word Swap. This field only has significance if the device is operated in 16bit mode. In 32-bit mode, D[31:15] is always mapped to the high order word and D[15:0] is always mapped to the low order word. In 16-bit mode, if this field is set to 00000000h, or anything except 0xFFFFFFFFh, the LAN9218I maps words with address bit A[1]=1 to the high order words of the CSRs and Data FIFOs, and words with address bit A[1]=0 to the low order words of the CSRs and Data FIFOs. If this field is set to 0xFFFFFFFFh, the LAN9218I maps words with address bit A[1]=1 to the low order words of the CSRs and Data FIFOs, and words with address bit A[1]=0 to the high order words of the CSRs and Data FIFOs. Note: Please refer to Section 3.6.1, "32-bit vs. 16-bit Host Bus Width Operation" for additional information.
TYPE R/W NASR
DEFAULT 00000000h
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Datasheet
5.3.18
FREE_RUN—Free-Run 25MHz Counter
Offset: 9Ch Size: 32 bits
This register reflects the value of the free-running 25MHz counter.
BITS 31:0
DESCRIPTION Free Running SCLK Counter (FR_CNT): Note: This field reflects the value of a free-running 32-bit counter. At reset the counter starts at zero and is incremented for every 25MHz cycle. When the maximum count has been reached the counter will rollover. When read in 16-bit mode the count value is latched on the first read. The FREE_RUN counter can take up to 160nS to clear after a reset event. This counter will run regardless of the power management states D0, D1 or D2.
TYPE RO
DEFAULT -
Note:
5.3.19
RX_DROP– Receiver Dropped Frames Counter
Offset: A0h Size: 32 bits
This register indicates the number of receive frames that have been dropped.
BITS 31-0
DESCRIPTION RX Dropped Frame Counter (RX_DFC). This counter is incremented every time a receive frame is dropped. RX_DFC is cleared on any read of this register. An interrupt can be issued when this counter passes through its halfway point (7FFFFFFFh to 80000000h).
TYPE RC
DEFAULT 00000000h
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Datasheet
5.3.20
MAC_CSR_CMD – MAC CSR Synchronizer Command Register
Offset: A4h Size: 32 bits
This register is used to control the read and write operations with the MAC CSR’s
BITS 31
DESCRIPTION CSR Busy. When a 1 is written into this bit, the read or write operation is performed to the specified MAC CSR. This bit will remain set until the operation is complete. In the case of a read this means that the host can read valid data from the data register. The MAC_CSR_CMD and MAC_CSR_DATA registers should not be modified until this bit is cleared. R/nW. When set, this bit indicates that the host is requesting a read operation. When clear, the host is performing a write. Reserved. CSR Address. The 8-bit value in this field selects which MAC CSR will be accessed with the read or write operation.
TYPE SC
DEFAULT 0
30 29-8 7-0
R/W RO R/W
0 00h
5.3.21
MAC_CSR_DATA – MAC CSR Synchronizer Data Register
Offset: A8h Size: 32 bits
This register is used in conjunction with the MAC_CSR_CMD register to perform read and write operations with the MAC CSR’s
BITS 31-0
DESCRIPTION MAC CSR Data. Value read from or written to the MAC CSR’s.
TYPE R/W
DEFAULT 00000000h
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Datasheet
5.3.22
AFC_CFG – Automatic Flow Control Configuration Register
Offset: ACh Size: 32 bits
This register configures the mechanism that controls both the automatic, and software-initiated transmission of pause frames and back pressure. Note: The LAN9218I will not transmit pause frames or assert back pressure if the transmitter is disabled.
BITS 31:24 23:16 Reserved
DESCRIPTION
TYPE RO R/W
DEFAULT 00h
Automatic Flow Control High Level (AFC_HI). Specifies, in multiples of 64 bytes, the level at which flow control will trigger. When this limit is reached the chip will apply back pressure or will transmit a pause frame as programmed in bits [3:0] of this register. During full-duplex operation only a single pause frame is transmitted when this level is reached. The pause time transmitted in this frame is programmed in the FCPT field of the FLOW register in the MAC CSR space. During half-duplex operation each incoming frame that matches the criteria in bits [3:0] of this register will be jammed for the period set in the BACK_DUR field.
15:8
Automatic Flow Control Low Level (AFC_LO). Specifies, in multiples of 64 bytes, the level at which a pause frame is transmitted with a pause time setting of zero. When the amount of data in the RX data FIFO falls below this level the pause frame is transmitted. A pause time value of zero instructs the other transmitting device to immediately resume transmission. The zero time pause frame will only be transmitted if the RX data FIFO had reached the AFC_HI level and a pause frame was sent. A zero pause time frame is sent whenever automatic flow control in enabled in bits [3:0] of this register. Note: When automatic flow control is enabled the AFC_LO setting must always be less than the AFC_HI setting.
R/W
00h
7:4
Backpressure Duration (BACK_DUR). When the LAN9218I automatically asserts back pressure, it will be asserted for this period of time. This field has no function and is not used in full-duplex mode. Please refer to Table 5.5, describing Backpressure Duration bit mapping for more information. Flow Control on Multicast Frame (FCMULT). When this bit is set, the LAN9218I will assert back pressure when the AFC level is reached and a multicast frame is received. This field has no function in full-duplex mode. Flow Control on Broadcast Frame (FCBRD). When this bit is set, the LAN9218I will assert back pressure when the AFC level is reached and a broadcast frame is received. This field has no function in full-duplex mode. Flow Control on Address Decode (FCADD). When this bit is set, the LAN9218I will assert back pressure when the AFC level is reached and a frame addressed to the LAN9218I is received. This field has no function in full-duplex mode.
R/W
0h
3
R/W
0
2
R/W
0
1
R/W
0
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Datasheet
BITS 0
DESCRIPTION Flow Control on Any Frame (FCANY). When this bit is set, the LAN9218I will assert back pressure, or transmit a pause frame when the AFC level is reached and any frame is received. Setting this bit enables full-duplex flow control when the LAN9218I is operating in full-duplex mode. When this mode is enabled during half-duplex operation, the Flow Controller does not decode the MAC address and will send a pause frame upon receipt of a valid preamble (i.e., immediately at the beginning of the next frame after the RX data FIFO level is reached). When this mode is enabled during full-duplex operation, the Flow Controller will immediately instruct the MAC to send a pause frame when the RX data FIFO level is reached. The MAC will queue the pause frame transmission for the next available window. Setting this bit overrides bits [3:1] of this register.
TYPE R/W
DEFAULT 0
Table 5.5 Backpressure Duration Bit Mapping BACKPRESSURE DURATION [19:16] 0h 1h 2h 3h 4h 5h 6h 7h 8h 9h Ah Bh Ch Dh Eh Fh 100Mbs Mode 5uS 10uS 15uS 25uS 50uS 100uS 150uS 200uS 250uS 300uS 350uS 400uS 450uS 500uS 550uS 600uS 10Mbs Mode 7.2uS 12.2uS 17.2uS 27.2uS 52.2uS 102.2uS 152.2uS 202.2uS 252.2uS 302.2uS 352.2uS 402.2uS 452.2uS 502.2uS 552.2uS 602.2uS
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Datasheet
5.3.23
E2P_CMD – EEPROM Command Register
Offset: B0h Size: 32 bits
This register is used to control the read and write operations with the Serial EEPROM.
BITS 31
DESCRIPTION EPC Busy: When a 1 is written into this bit, the operation specified in the EPC command field is performed at the specified EEPROM address. This bit will remain set until the operation is complete. In the case of a read this means that the host can read valid data from the E2P data register. The E2P_CMD and E2P_DATA registers should not be modified until this bit is cleared. In the case where a write is attempted and an EEPROM is not present, the EPC Busy remains busy until the EPC Time-out occurs. At that time the busy bit is cleared. Note: EPC busy will be high immediately following power-up or reset. After the EEPROM controller has finished reading (or attempting to read) the MAC address from the EEPROM the EPC Busy bit is cleared.
TYPE SC
DEFAULT 0
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Datasheet
BITS 30-28
DESCRIPTION EPC command. This field is used to issue commands to the EEPROM controller. The EPC will execute commands when the EPC Busy bit is set. A new command must not be issued until the previous command completes. This field is encoded as follows:
TYPE R/W
DEFAULT 0
[30] 0
[29]
[28]
OPERATION
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
READ EWDS EWEN WRITE WRAL ERASE ERAL Reload
0 0 0 1 1 1 1
READ (Read Location): This command will cause a read of the EEPROM location pointed to by EPC Address. The result of the read is available in the E2P_DATA register. EWDS (Erase/Write Disable): After issued, the EEPROM will ignore erase and write commands. To re-enable erase/write operations issue the EWEN command. EWEN (Erase/Write Enable): Enables the EEPROM for erase and write operations. The EEPROM will allow erase and write operations until the Erase/Write Disable command is sent, or until power is cycled. Note: The EEPROM device will power-up in the erase/write-disabled state. Any erase or write operations will fail until an Erase/Write Enable command is issued.
WRITE (Write Location): If erase/write operations are enabled in the EEPROM, this command will cause the contents of the E2P_DATA register to be written to the EEPROM location selected by the EPC Address field. WRAL (Write All): If erase/write operations are enabled in the EEPROM, this command will cause the contents of the E2P_DATA register to be written to every EEPROM memory location. ERASE (Erase Location): If erase/write operations are enabled in the EEPROM, this command will erase the location selected by the EPC Address field. ERAL (Erase All): If erase/write operations are enabled in the EEPROM, this command will initiate a bulk erase of the entire EEPROM. RELOAD (MAC Address Reload): Instructs the EEPROM controller to reload the MAC address from the EEPROM. If a value of 0xA5 is not found in the first address of the EEPROM, the EEPROM is assumed to be unprogrammed and MAC Address Reload operation will fail. The “MAC Address Loaded” bit indicates a successful load of the MAC address. 27-10 Reserved. RO -
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BITS 9
DESCRIPTION
TYPE R/WC
DEFAULT 0
EPC Time-out. If an EEPROM operation is performed, and there is no
response from the EEPROM within 30mS, the EEPROM controller will timeout and return to its idle state. This bit is set when a time-out occurs indicating that the last operation was unsuccessful. Note: If the EEDIO signal pin is externally pulled-high, EPC commands will not time out if the EEPROM device is missing. In this case the EPC Busy bit will be cleared as soon as the command sequence is complete. It should also be noted that the ERASE, ERAL, WRITE and WRAL commands are the only EPC commands that will time-out if an EEPROM device is not present -and- the EEDIO signal is pulled low
8
MAC Address Loaded. When set, this bit indicates that a valid EEPROM
was found, and that the MAC address programming has completed normally. This bit is set after a successful load of the MAC address after power-up, or after a RELOAD command has completed
RO
-
7-0
EPC Address. The 8-bit value in this field is used by the EEPROM
R/W
00h
Controller to address the specific memory location in the Serial EEPROM. This is a Byte aligned address.
5.3.24
E2P_DATA – EEPROM Data Register
Offset: B4h Size: 32 bits
This register is used in conjunction with the E2P_CMD register to perform read and write operations with the Serial EEPROM.
BITS 31-8 7:0 Reserved.
DESCRIPTION
TYPE RO R/W
DEFAULT 00h
EEPROM Data. Value read from or written to the EEPROM.
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5.4
MAC Control and Status Registers
These registers are located in the MAC module and are accessed indirectly through the MAC-CSR synchronizer port. Table 5.6, "MAC CSR Register Map", shown below, lists the MAC registers that are accessible through the indexing method using the MAC_CSR_CMD and MAC_CSR_DATA registers (see sections MAC_CSR_CMD – MAC CSR Synchronizer Command Register and MAC_CSR_DATA – MAC CSR Synchronizer Data Register). Table 5.6 MAC CSR Register Map MAC CONTROL AND STATUS REGISTERS INDEX 1 2 3 4 5 6 7 8 9 A B C SYMBOL MAC_CR ADDRH ADDRL HASHH HASHL MII_ACC MII_DATA FLOW VLAN1 VLAN2 WUFF WUCSR REGISTER NAME MAC Control Register MAC Address High MAC Address Low Multicast Hash Table High Multicast Hash Table Low MII Access MII Data Flow Control VLAN1 Tag VLAN2 Tag Wake-up Frame Filter Wake-up Control and Status DEFAULT 00040000h 0000FFFFh FFFFFFFFh 00000000h 00000000h 00000000h 00000000h 00000000h 00000000h 00000000h 00000000h 00000000h
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5.4.1
MAC_CR—MAC Control Register
Offset: Default Value: 1 00040000h Attribute: Size: R/W 32 bits
This register establishes the RX and TX operation modes and controls for address filtering and packet filtering.
BITS 31
DESCRIPTION Receive All Mode (RXALL). When set, all incoming packets will be received and passed on to the address filtering Function for processing of the selected filtering mode on the received frame. Address filtering then occurs and is reported in Receive Status. When reset, only frames that pass Destination Address filtering will be sent to the Application. Reserved Disable Receive Own (RCVOWN). When set, the MAC disables the reception of frames when TXEN is asserted. The MAC blocks the transmitted frame on the receive path. When reset, the MAC receives all packets the PHY gives, including those transmitted by the MAC.This bit should be reset when the Full Duplex Mode bit is set. Reserved Loopback operation Mode (LOOPBK). Selects the loop back operation modes for the MAC. This is only for full duplex mode 1’b0: Normal: No feedback 1’b1: Internal: Through MII In internal loopback mode, the TX frame is received by the Internal MII interface, and sent back to the MAC without being sent to the PHY. Note: When enabling or disabling the loopback mode it can take up to 10μs for the mode change to occur. The transmitter and receiver must be stopped and disabled when modifying the LOOPBK bit. The transmitter or receiver should not be enabled within10μs of modifying the LOOPBK bit.
30-24 23
22 21
20
Full Duplex Mode (FDPX). When set, the MAC operates in Full-Duplex mode, in which it can transmit and receive simultaneously. In Full-Duplex mode, the heartbeat check is disabled and the heartbeat fail status should thus be ignored. Pass All Multicast (MCPAS). When set, indicates that all incoming frames with a Multicast destination address (first bit in the destination address field is 1) are received. Incoming frames with physical address (Individual Address/Unicast) destinations are filtered and received only if the address matches the MAC Address. Promiscuous Mode (PRMS). When set, indicates that any incoming frame is received regardless of its destination address. Inverse filtering (INVFILT). When set, the address check Function operates in Inverse filtering mode. This is valid only during Perfect filtering mode. Pass Bad Frames (PASSBAD). When set, all incoming frames that passed address filtering are received, including runt frames, collided frames or truncated frames caused by buffer underrun. Hash Only Filtering mode (HO). When set, the address check Function operates in the Imperfect Address Filtering mode both for physical and multicast addresses Reserved
19
18 17 16 15 14
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BITS 13
DESCRIPTION Hash/Perfect Filtering Mode (HPFILT). When reset (0), the LAN9218I will implement a perfect address filter on incoming frames according the address specified in the MAC address register. When set (1), the address check Function does imperfect address filtering of multicast incoming frames according to the hash table specified in the multicast hash table register. If the Hash Only Filtering mode (HO) bit is set (1), then the physical (IA) are imperfect filtered too. If the Hash Only Filtering mode (HO) bit is reset (0), then the IA addresses are perfect address filtered according to the MAC Address register
12
Late Collision Control (LCOLL). When set, enables retransmission of the collided frame even after the collision period (late collision). When reset, the MAC disables frame transmission on a late collision. In any case, the Late Collision status is appropriately updated in the Transmit Packet status. Disable Broadcast Frames (BCAST). When set, disables the reception of broadcast frames. When reset, forwards all broadcast frames to the application. Disable Retry (DISRTY). When set, the MAC attempts only one transmission. When a collision is seen on the bus, the MAC ignores the current frame and goes to the next frame and a retry error is reported in the Transmit status. When reset, the MAC attempts 16 transmissions before signaling a retry error. Reserved Automatic Pad Stripping (PADSTR). When set, the MAC strips the pad field on all incoming frames, if the length field is less than 46 bytes. The FCS field is also stripped, since it is computed at the transmitting station based on the data and pad field characters, and is invalid for a received frame that has had the pad characters stripped. Receive frames with a 46-byte or greater length field are passed to the Application unmodified (FCS is not stripped). When reset, the MAC passes all incoming frames to the host unmodified. BackOff Limit (BOLMT). The BOLMT bits allow the user to set its back-off limit in a relaxed or aggressive mode. According to IEEE 802.3, the MAC has to wait for a random number [r] of slottimes** after it detects a collision, where: (eq.1)0 < r < 2K The exponent K is dependent on how many times the current frame to be transmitted has been retried, as follows: (eq.2)K = min (n, 10) where n is the current number of retries. If a frame has been retried three times, then K = 3 and r= 8 slot-times maximum. If it has been retried 12 times, then K = 10, and r = 1024 slot-times maximum. An LFSR (linear feedback shift register) 20-bit counter emulates a 20bit random number generator, from which r is obtained. Once a collision is detected, the number of the current retry of the current frame is used to obtain K (eq.2). This value of K translates into the number of bits to use from the LFSR counter. If the value of K is 3, the MAC takes the value in the first three bits of the LFSR counter and uses it to count down to zero on every slot-time. This effectively causes the MAC to wait eight slot-times. To give the user more flexibility, the BOLMT value forces the number of bits to be used from the LFSR counter to a predetermined value as in the table below.
11 10
9 8
7-6
BOLMT Value 2’b00
# Bits Used from LFSR Counter
10 8 4 1
2’b01 2’b10 2’b11
Thus, if the value of K = 10, the MAC will look at the BOLMT if it is 00, then use the lower ten bits of the LFSR counter for the wait countdown. If the BOLMT is 10, then it will only use the value in the first four bits for the wait countdown, etc. **Slot-time = 512 bit times. (See IEEE 802.3 Spec., Secs. 4.2.3.25 and 4.4.2.1)
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BITS 5
DESCRIPTION Deferral Check (DFCHK). When set, enables the deferral check in the MAC. The MAC will abort the transmission attempt if it has deferred for more than 24,288 bit times. Deferral starts when the transmitter is ready to transmit, but is prevented from doing so because the CRS is active. Defer time is not cumulative. If the transmitter defers for 10,000 bit times, then transmits, collides, backs off, and then has to defer again after completion of back-off, the deferral timer resets to 0 and restarts. When reset, the deferral check is disabled in the MAC and the MAC defers indefinitely. Reserved Transmitter enable (TXEN). When set, the MAC’s transmitter is enabled and it will transmit frames from the buffer onto the cable. When reset, the MAC’s transmitter is disabled and will not transmit any frames. Receiver Enable (RXEN). When set (1), the MAC’s receiver is enabled and will receive frames from the internal PHY. When reset, the MAC’s receiver is disabled and will not receive any frames from the internal PHY. Reserved
4 3
2
1-0
5.4.2
ADDRH—MAC Address High Register
Offset: Default Value: 2 0000FFFFh Attribute: Size: R/W 32 bits
The MAC Address High register contains the upper 16-bits of the physical address of the MAC. The contents of this register are optionally loaded from the EEPROM at power-on through the EEPROM Controller if a programmed EEPROM is detected. The least significant byte of this register (bits [7:0]) is loaded from address 0x05 of the EEPROM. The second byte (bits [15:8]) is loaded from address 0x06 of the EEPROM. Please refer to Section 4.6 for more information on the EEPROM. Section 5.4.3 details the byte ordering of the ADDRL and ADDRH registers with respect to the reception of the Ethernet physical address.
BITS 31-16 15-0 Reserved
DESCRIPTION
Physical Address [47:32]. This field contains the upper 16-bits (47:32) of the Physical Address of the LAN9218I device. The content of this field is undefined until loaded from the EEPROM at poweron. The host can update the contents of this field after the initialization process has completed.
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5.4.3
ADDRL—MAC Address Low Register
Offset: Default Value: 3 FFFFFFFFh Attribute: Size: R/W 32 bits
The MAC Address Low register contains the lower 32 bits of the physical address of the MAC. The contents of this register are optionally loaded from the EEPROM at power-on through the EEPROM Controller if a programmed EEPROM is detected. The least significant byte of this register (bits [7:0]) is loaded from address 0x01 of the EEPROM. The most significant byte of this register is loaded from address 0x04 of the EEPROM. Please refer to Section 4.6 for more information on the EEPROM.
BITS 31-0
DESCRIPTION Physical Address [31:0]. This field contains the lower 32 bits (31:0) of the Physical Address of the LAN9218I device. The content of this field is undefined until loaded from the EEPROM at power-on. The host can update the contents of this field after the initialization process has completed. Table 5.7 below illustrates the byte ordering of the ADDRL and ADDRH registers with respect to the reception of the Ethernet physical address. Also shown is the correlation between the EEPROM addresses and ADDRL and ADDRH registers. Table 5.7 ADDRL, ADDRH and EEPROM Byte Ordering ORDER OF RECEPTION ON ETHERNET 1st 2nd 3rd 4th 5th 6th
EEPROM ADDRESS 0x01 0x02 0x03 0x04 0x05 0x06
ADDRN ADDRL[7:0] ADDRL[15:8] ADDRL[23:16] ADDRL[31:24] ADDRH[7:0] ADDRH[15:8]
As an example, if the desired Ethernet physical address is 12-34-56-78-9A-BC, the ADDRL and ADDRH registers would be programmed as shown in Figure 5.2. The values required to automatically load this configuration from the EEPROM are also shown.
31 xx 24 23 xx 16 15 0xBC 87 0x9A 0
0x06 0x05 0x04 0x03
0xBC 0x9A 0x78 0x56 0x34 0x12 0xA5 EEPROM
ADDRH 31 0x78 24 23 16 15 0x34 87 0x12 0
0x02 0x01 0x00
0x56
ADDRL
Figure 5.2 Example ADDRL, ADDRH and EEPROM Setup Note: By convention, the left most byte of the Ethernet address (in this example 0x12) is the most significant byte and is transmitted/received first.
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5.4.4
HASHH—Multicast Hash Table High Register
Offset: Default Value: 4 00000000h Attribute: Size: R/W 32 bits
The 64-bit Multicast table is used for group address filtering. For hash filtering, the contents of the destination address in the incoming frame is used to index the contents of the Hash table. The most significant bit determines the register to be used (Hi/Low), while the other five bits determine the bit within the register. A value of 00000 selects Bit 0 of the Multicast Hash Table Lo register and a value of 11111 selects the Bit 31 of the Multicast Hash Table Hi register. If the corresponding bit is 1, then the multicast frame is accepted. Otherwise, it is rejected. If the “Pass All Multicast” (MCPAS) bit is set (1), then all multicast frames are accepted regardless of the multicast hash values. The Multicast Hash Table Hi register contains the higher 32 bits of the hash table and the Multicast Hash Table Low register contains the lower 32 bits of the hash table.
BITS 31-0 Upper 32 bits of the 64-bit Hash Table
DESCRIPTION
5.4.5
HASHL—Multicast Hash Table Low Register
Offset: Default Value: 5 00000000h Attribute: Size: R/W 32 bits
This register defines the lower 32-bits of the Multicast Hash Table. Please refer to Table 5.4.4, "HASHH—Multicast Hash Table High Register" for further details.
BITS 31-0 Lower 32 bits of the 64-bit Hash Table
DESCRIPTION
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5.4.6
MII_ACC—MII Access Register
Offset: Default Value: 6 00000000h Attribute: Size: R/W 32 bits
This register is used to control the Management cycles to the PHY.
BITS 31-16 15-11 10-6 5-2 1 0 Reserved
DESCRIPTION
PHY Address: For every access to this register, this field must be set to 00001b. MII Register Index (MIIRINDA): These bits select the desired MII register in the PHY. Reserved MII Write (MIIWnR): Setting this bit tells the PHY that this will be a write operation using the MII data register. If this bit is not set, this will be a read operation, packing the data in the MII data register. MII Busy (MIIBZY): This bit must be polled to determine when the MII register access is complete. This bit must read a logical 0 before writing to this register and MII data register. The LAN driver software must set (1) this bit in order for the LAN9218I to read or write any of the MII PHY registers. During a MII register access, this bit will be set, signifying a read or write access is in progress. The MII data register must be kept valid until the MAC clears this bit during a PHY write operation. The MII data register is invalid until the MAC has cleared this bit during a PHY read operation.
5.4.7
MII_DATA—MII Data Register
Offset: Default Value: 7 00000000h Attribute: Size: R/W 32 bits
This register contains either the data to be written to the PHY register specified in the MII Access Register, or the read data from the PHY register whose index is specified in the MII Access Register.
BITS 31-16 15-0 Reserved
DESCRIPTION
MII Data. This contains the 16-bit value read from the PHY read operation or the 16-bit data value to be written to the PHY before an MII write operation.
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5.4.8
FLOW—Flow Control Register
Offset: Default Value: 8 00000000h Attribute: Size: R/W 32 bits
This register controls the generation and reception of the Control (Pause command) frames by the MAC’s flow control block. The control frame fields are selected as specified in the 802.3x Specification and the Pause-Time value from this register is used in the “Pause Time” field of the control frame. In full-duplex mode the FCBSY bit is set until the control frame is transferred onto the cable. In halfduplex mode FCBSY is set while back pressure is being asserted. The host has to make sure that the Busy bit is cleared before writing the register. The Pass Control Frame bit (FCPASS) does not affect the sending of the frames, including Control Frames, to the Application Interface. The Flow Control Enable (FCEN) bit enables the receive portion of the Flow Control block. This register is used in conjunction with the AFC_CFG register in the Slave CSRs to configure flow control. Software flow control is initiated using the AFC_CFG register. Note: The LAN9218I will not transmit pause frames or assert back pressure if the transmitter is disabled.
BITS 31-16 15-3 2
DESCRIPTION Pause Time (FCPT). This field indicates the value to be used in the PAUSE TIME field in the control frame. This field must be initialized before full-duplex automatic flow control is enabled. Reserved Pass Control Frames (FCPASS). When set, the MAC sets the Packet Filter bit in the Receive packet status to indicate to the Application that a valid Pause frame has been received. The Application must accept or discard a received frame based on the Packet Filter control bit. The MAC receives, decodes and performs the Pause function when a valid Pause frame is received in Full-Duplex mode and when flow control is enabled (FCE bit set). When reset, the MAC resets the Packet Filter bit in the Receive packet status. The MAC always passes the data of all frames it receives (including Flow Control frames) to the Application. Frames that do not pass Address filtering, as well as frames with errors, are passed to the Application. The Application must discard or retain the received frame’s data based on the received frame’s STATUS field. Filtering modes (Promiscuous mode, for example) take precedence over the FCPASS bit. Flow Control Enable (FCEN). When set, enables the MAC Flow Control function. The MAC decodes all incoming frames for control frames; if it receives a valid control frame (PAUSE command), it disables the transmitter for a specified time (Decoded pause time x slot time). When reset, the MAC flow control function is disabled; the MAC does not decode frames for control frames. Note: Flow Control is applicable when the MAC is set in Full Duplex Mode. In Half-Duplex mode, this bit enables the Backpressure function to control the flow of received frames to the MAC.
1
0
Flow Control Busy (FCBSY). This bit is set high whenever a pause frame or back pressure is being
transmitted. This bit should read logical 0 before writing to the Flow Control (FLOW) register. During a transfer of Control Frame, this bit continues to be set, signifying that a frame transmission is in progress. After the PAUSE control frame’s transmission is complete, the MAC resets to 0. Notes: When writing this register the FCBSY bit must always be zero. Applications must always write a zero to this bit
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5.4.9
VLAN1—VLAN1 Tag Register
Offset: Default Value: 9 00000000h Attribute: Size: R/W 32 bits
This register contains the VLAN tag field to identify VLAN1 frames. For VLAN frames the legal frame length is increased from 1518 bytes to 1522 bytes.
BITS 31-16 15-0 Reserved
DESCRIPTION
VLAN1 Tag Identifier (VTI1). This contains the VLAN Tag field to identify the VLAN1 frames. This field is compared with the 13th and 14th bytes of the incoming frames for VLAN1 frame detection. If used, this register must be set to 0x8100.
5.4.10
VLAN2—VLAN2 Tag Register
Offset: Default Value: A 00000000h Attribute: Size: R/W 32 bits
This register contains the VLAN tag field to identify VLAN2 frames. For VLAN frames the legal frame length is increased from 1518 bytes to 1522 bytes.
BITS 31-16 15-0 Reserved
DESCRIPTION
VLAN2 Tag Identifier (VTI2). This contains the VLAN Tag field to identify the VLAN2 frames. This field is compared with the 13th and 14th bytes of the incoming frames for VLAN2 frame detection.If used, this register must be set to 0x8100.
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5.4.11
WUFF—Wake-up Frame Filter
Offset: Default Value: B 00000000h Attribute: Size: WO 32 bits
This register is used to configure the wake up frame filter.
BITS 31-0
DESCRIPTION Wake-Up Frame Filter (WFF). Wake-Up Frame Filter (WFF). The Wake-up frame filter is configured through this register using an indexing mechanism. After power-on reset, hardware reset, or soft reset, the MAC loads the first value written to this location to the first DWORD in the Wake-up frame filter (filter 0 byte mask). The second value written to this location is loaded to the second DWORD in the wake-up frame filter (filter 1 byte mask) and so on. Once all eight DWORDs have been written, the internal pointer will once again point to the first entry and the filter entries can be modified in the same manner. Note: This is a write-only register.
5.4.12
WUCSR—Wake-up Control and Status Register
Offset: Default Value: C 00000000h Attribute: Size: R/W 32 bits
This register contains data pertaining to the MAC’s remote wake-up status and capabilities.
BITS 31-10 9 8-7 6 5 4-3 2 1 0 Reserved
DESCRIPTION
Global Unicast Enable (GUE). When set, the MAC wakes up from power-saving mode on receipt of a global unicast frame. A global unicast frame has the MAC Address [1:0] bit set to 0. Reserved Remote Wake-Up Frame Received (WUFR). The MAC, upon receiving a valid Remote Wake-up frame, sets this bit. Magic Packet Received (MPR). The MAC, upon receiving a valid Magic Packet, sets this bit. Reserved Wake-Up Frame enabled (WUEN). When set, Remote Wake-Up mode is enabled and the MAC is capable of detecting wake-up frames as programmed in the wake-up frame filter. Magic Packet Enable (MPEN). When set, Magic Packet Wake-up mode is enabled. Reserved
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5.5
PHY Registers
The PHY registers are not memory mapped. These registers are accessed indirectly through the MAC via the MII_ACC and MII_DATA registers. An index must be used to access individual PHY registers. PHY Register Indexes are shown in Table 5.8, "LAN9218I PHY Control and Status Register". Note: The NASR (Not Affected by Software Reset) designation is only applicable when bit 15 of the PHY Basic Control Register (Reset) is set. Table 5.8 LAN9218I PHY Control and Status Register PHY CONTROL AND STATUS REGISTERS INDEX (IN DECIMAL) 0 1 2 3 4 5 6 17 18 27 29 30 31 REGISTER NAME Basic Control Register Basic Status Register PHY Identifier 1 PHY Identifier 2
Auto-Negotiation Advertisement Register
Auto-Negotiation Link Partner Ability Register Auto-Negotiation Expansion Register Mode Control/Status Register Special Modes Register Special Control/Status Indications Interrupt Source Register Interrupt Mask Register PHY Special Control/Status Register
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5.5.1
Basic Control Register
Index (In Decimal): 0 Size: 16-bits
BITS 15 14 13 12 11
DESCRIPTION Reset. 1 = software reset. Bit is self-clearing. For best results, when setting this bit do not set other bits in this register. Loopback. 1 = loopback mode, 0 = normal operation Speed Select. 1 = 100Mbps, 0 = 10Mbps. Ignored if Auto Negotiation is enabled (0.12 = 1). Auto-Negotiation Enable. 1 = enable auto-negotiate process (overrides 0.13 and 0.8) 0 = disable auto-negotiate process. Power Down. 1 = General power down-mode, 0 = normal operation. Note: After this bit is cleared, the PHY may auto-negotiate with it's partner station. This process may take a few seconds to complete. Once auto-negotiation is complete, bit 5 of the PHY's Basic Status Register will be set.
TYPE RW/SC RW RW RW RW
DEFAULT 0 0 See Note 5.1 See Note 5.1 0
10 9 8 7 6-0
Reserved Restart Auto-Negotiate. 1 = restart auto-negotiate process 0 = normal operation. Bit is self-clearing. Duplex Mode. 1 = full duplex, 0 = half duplex. Ignored if Auto Negotiation is enabled (0.12 = 1). Collision Test. 1 = enable COL test, 0 = disable COL test Reserved Note 5.1
RO RW/SC RW RW RO
0 0 0 0 0
This default value of this bit is determined by Pin 74 "SPEED_SEL". Please refer to the pin description section for more details
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5.5.2
Basic Status Register
Index (In Decimal): 1 Size: 16-bits
BITS 15 14 13 12 11 10-6 5 4 3 2 1 0
DESCRIPTION 100Base-T4. 1 = T4 able, 0 = no T4 ability 100Base-TX Full Duplex. 1 = TX with full duplex, 0 = no TX full duplex ability. 100Base-TX Half Duplex. 1 = TX with half duplex, 0 = no TX half duplex ability. 10Base-T Full Duplex. 1 = 10Mbps with full duplex 0 = no 10Mbps with full duplex ability 10Base-T Half Duplex. 1 = 10Mbps with half duplex 0 = no 10Mbps with half duplex ability Reserved Auto-Negotiate Complete. 1 = auto-negotiate process completed 0 = autonegotiate process not completed Remote Fault. 1 = remote fault condition detected 0 = no remote fault Auto-Negotiate Ability. 1 = able to perform auto-negotiation function 0 = unable to perform auto-negotiation function Link Status. 1 = link is up, 0 = link is down Jabber Detect. 1 = jabber condition detected 0 = no jabber condition detected Extended Capabilities. 1 = supports extended capabilities registers 0 = does not support extended capabilities registers.
TYPE RO RO RO RO RO RO RO RO/LH RO RO/LL RO/LH RO
DEFAULT 0 1 1 1 1 0 0 0 1 0 0 1
5.5.3
PHY Identifier 1
Index (In Decimal): 2 Size: 16-bits
BITS 15-0
DESCRIPTION PHY ID Number. Assigned to the 3rd through 18th bits of the Organizationally Unique Identifier (OUI), respectively.
TYPE RO
DEFAULT 0x0007h
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5.5.4
PHY Identifier 2
Index (In Decimal): 3 Size: 16-bits
BITS 15-10 9-4 3-0
DESCRIPTION PHY ID Number b. Assigned to the 19th through 24th bits of the OUI. Model Number. Six-bit manufacturer’s model number. Revision Number. Four-bit manufacturer’s revision number.
TYPE RO RO RO
DEFAULT 0xC0C3h
5.5.5
Auto-negotiation Advertisement
Index (In Decimal): 4 Size: 16-bits
BITS 15 14 13 12 11-10
DESCRIPTION Next Page. 1 = next page capable, 0 = no next page ability. This device does not support next page ability. Reserved Remote Fault. 1 = remote fault detected, 0 = no remote fault Reserved Pause Operation. 00 No PAUSE 01 Symmetric PAUSE 10 Asymmetric PAUSE 11 Both Symmetric PAUSE and Asymmetric PAUSE 100Base-T4. 1 = T4 able, 0 = no T4 ability This device does not support 100Base-T4. 100Base-TX Full Duplex. 1 = TX with full duplex, 0 = no TX full duplex ability 100Base-TX. 1 = TX able, 0 = no TX ability 10Base-T Full Duplex. 1 = 10Mbps with full duplex 0 = no 10Mbps with full duplex ability 10Base-T. 1 = 10Mbps able, 0 = no 10Mbps ability Selector Field. [00001] = IEEE 802.3
TYPE RO RO R/W R/W R/W
DEFAULT 0 0 0 0 00
9 8 7 6
RO R/W R/W R/W
0 See Note 5.2 1 See Note 5.2 See Note 5.2 00001
5 4:0
R/W R/W
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Note 5.2
This default value of this bit is determined by Pin 74 "SPEED_SEL". Please refer to the pin description section for more details.
5.5.6
Auto-negotiation Link Partner Ability
Index (In Decimal): 5 Size: 16-bits
BITS 15 14
DESCRIPTION Next Page. 1 = next page capable, 0 = no next page ability. This device does not support next page ability. Acknowledge. 1 = link code word received from partner 0 = link code word not yet received Note: This bit will always read 0
TYPE RO RO
DEFAULT 0 0
13 12 11-10
Remote Fault. 1 = remote fault detected, 0 = no remote fault Reserved Pause Operation. 00 No PAUSE supported by partner station 01 Symmetric PAUSE supported by partner station 10 Asymmetric PAUSE supported by partner station 11 Both Symmetric PAUSE and Asymmetric PAUSE supported by partner station 100Base-T4. 1 = T4 able, 0 = no T4 ability 100Base-TX Full Duplex. 1 = TX with full duplex, 0 = no TX full duplex ability 100Base-TX. 1 = TX able, 0 = no TX ability 10Base-T Full Duplex. 1 = 10Mbps with full duplex 0 = no 10Mbps with full duplex ability 10Base-T. 1 = 10Mbps able, 0 = no 10Mbps ability Selector Field. [00001] = IEEE 802.3
RO RO RO
0 0 00
9 8 7 6
RO RO RO RO
0 0 0 0
5 4:0
RO RO
0 00001
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5.5.7
Auto-negotiation Expansion
Index (In Decimal): 6 Size: 16-bits
BITS 15:5 4 Reserved
DESCRIPTION
TYPE RO RO/LH
DEFAULT 0 0
Parallel Detection Fault. 1 = fault detected by parallel detection logic 0 = no fault detected by parallel detection logic Link Partner Next Page Able. 1 = link partner has next page ability 0 = link partner does not have next page ability Next Page Able. 1 = local device has next page ability 0 = local device does not have next page ability Page Received. 1 = new page received 0 = new page not yet received Link Partner Auto-Negotiation Able. 1 = link partner has auto-negotiation ability 0 = link partner does not have auto-negotiation ability
3
RO
0
2
RO
0
1
RO/LH
0
0
RO
0
5.5.8
Mode Control/Status
Index (In Decimal): 17 Size: 16-bits
BITS 15-14 13
DESCRIPTION Reserved. Write as 0; ignore on read. EDPWRDOWN. Enable the Energy Detect Power-Down mode: 0=Energy Detect Power-Down is disabled 1=Energy Detect Power-Down is enabled Reserved. Write as 0, ignore on read ENERGYON. Indicates whether energy is detected This bit goes to a “0” if no valid energy is detected within 256ms. Reset to “1” by hardware reset, unaffected by SW reset. Reserved. Write as “0”. Ignore on read.
TYPE RW RW
DEFAULT 0 0
12-2 1
RW RO
0 1
0
RW
0
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5.5.9
Special Modes
Index (In Decimal): 18 Size: 16-bits
ADDRESS 15-8 7:5 4:0 Reserved
DESCRIPTION
TYPE RW, NASR RW, NASR RW, NASR
DEFAULT
MODE: PHY Mode of operation. Refer to Table 5.9 for more details. PHYAD: PHY Address: The PHY Address is used for the SMI address.
See Table 5.9 00001b
Table 5.9 MODE Control DEFAULT REGISTER BIT VALUES MODE MODE DEFINITIONS REGISTER 0 [13,12,10,8] 000 001 010 011 100 10Base-T Half Duplex. Auto-negotiation disabled. 10Base-T Full Duplex. Auto-negotiation disabled. 100Base-TX Half Duplex. Auto-negotiation disabled. CRS is active during Transmit & Receive. 100Base-TX Full Duplex. Auto-negotiation disabled. CRS is active during Receive. 100ase-TX Half Duplex is advertised. Autonegotiation enabled. CRS is active during Transmit & Receive. Repeater mode. Auto-negotiation enabled. 100Base-TX Half Duplex is advertised. CRS is active during Receive. Reserved - Do not set the LAN9218I in this mode. All capable. Auto-negotiation enabled. 0000 0001 1000 1001 1100 REGISTER 4 [8,7,6,5] N/A N/A N/A N/A 0100
101
1100
0100
110 111
N/A X10X
N/A 1111
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5.5.10
Special Control/Status Indications
Index (In Decimal): 27 Size: 16-bits
ADDRESS 15
DESCRIPTION Override AMDIX Strap 0 - AMDIX_EN (pin 73) enables or disables HP Auto MDIX 1 - Override pin 73. PHY Register 27.14 and 27.13 determine MDIX function Auto-MDIX Enable: Only effective when 27.15=1, otherwise ignored. 0 = Disable Auto-MDIX. 27.13 determines normal or reversed connection. 1 = Enable Auto-MDIX. 27.13 must be set to 0. Auto-MDIX State. Only effective when 27.15=1, otherwise ignored. When 27.14 = 0 (manually set MDIX state): 0 = no crossover (TPO = output, TPI = input) 1 = crossover (TPO = input, TPI = output) When 27.14 = 1 (automatic MDIX) this bit must be set to 0. Do not use the combination 27.15=1, 27.14=1, 27.13=1. Reserved: Write as 0. Ignore on read. VCOOFF_LP: Forces the Receive PLL 10M to lock on the reference clock at all times: 0 - Receive PLL 10M can lock on reference or line as needed (normal operation) 1 - Receive PLL 10M is locked on the reference clock. In this mode 10M data packets cannot be received. Reserved: Write as 0. Ignore on read. XPOL: Polarity state of the 10Base-T: 0 - Normal polarity 1 - Reversed polarity Reserved: Read only - Writing to these bits have no effect.
MODE RW
DEFAULT 0
14
RW
0
13
RW
0
12:11 10
RW RW, NASR
0 0
9-5 4
RW RO
0 0
3:0
RO
1011b
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5.5.11
Interrupt Source Flag
Index (In Decimal): 29 Size: 16-bits
BITS 15-8 7 6 5 4 3 2 1 0 Reserved. Ignore on read.
DESCRIPTION
TYPE RO/LH RO/LH RO/LH RO/LH RO/LH RO/LH RO/LH RO/LH RO/LH
DEFAULT 0 0 0 0 0 0 0 0 0
INT7. 1= ENERGYON generated, 0= not source of interrupt INT6. 1= Auto-Negotiation complete, 0= not source of interrupt INT5. 1= Remote Fault Detected, 0= not source of interrupt INT4. 1= Link Down (link status negated), 0= not source of interrupt INT3. 1= Auto-Negotiation LP Acknowledge, 0= not source of interrupt INT2. 1= Parallel Detection Fault, 0= not source of interrupt INT1. 1= Auto-Negotiation Page Received, 0= not source of interrupt Reserved.
5.5.12
Interrupt Mask
Index (In Decimal): 30 Size: 16-bits
BITS 15-8 7-0
DESCRIPTION Reserved. Write as 0; ignore on read. Mask Bits. 1 = interrupt source is enabled 0 = interrupt source is masked
TYPE RO RW
DEFAULT 0 0
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5.5.13
PHY Special Control/Status
Index (In Decimal): 31 Size: 16-bits
BITS 15 - 13 12 Reserved.
DESCRIPTION
TYPE RO RO
DEFAULT 000b 0b
Autodone. Auto-negotiation done indication: 0 = Auto-negotiation is not done or disabled (or not active) 1 = Auto-negotiation is done Reserved. Write as 0000010b, ignore on Read. Speed Indication. HCDSPEED value: [001]=10Mbps half-duplex [101]=10Mbps full-duplex [010]=100Base-TX half-duplex [110]=100Base-TX full-duplex Reserved. Write as 0; ignore on Read Note 5.3
11-5 4-2
RW RO
0000010b See Note 5.3
1-0
RO
00b
See Table 2.2, “Default Ethernet Settings,” on page 15, for default settings.
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Chapter 6 Timing Diagrams
6.1 Host Interface Timing
The LAN9218I supports the following host cycles:
Read Cycles:
PIO Reads (nCS or nRD controlled) PIO Burst Reads (nCS or nRD controlled) RX Data FIFO Direct PIO Reads (nCS or nRD controlled) RX Data FIFO Direct PIO Burst Reads (nCS or nRD controlled)
Write Cycles:
PIO writes (nCS and nWR controlled) TX Data FIFO direct PIO writes (nCS or nWR controlled)
6.1.1
Special Restrictions on Back-to-Back Write/Read Cycles
It is important to note that there are specific restrictions on the timing of back-to-back write-read operations. These restrictions concern reading the control registers after any write cycle to the LAN9218I device. In many cases there is a required minimum delay between writing to the LAN9218I, and the subsequent side effect (change in the control register value). For example, when writing to the TX Data FIFO, it takes up to 135ns for the level indication to change in the TX_FIFO_INF register. In order to prevent the host from reading stale data after a write operation, minimum wait periods must be enforced. These periods are specified in Table 6.1, "Read After Write Timing Rules". The host processor is required to wait the specified period of time after any write to the LAN9218I before reading the resource specified in the table. These wait periods are for read operations that immediately follow any write cycle. Note that the required wait period is dependant upon the register being read after the write. Performing "dummy" reads of the BYTE_TEST register is a convenient way to guarantee that the minimum write-to-read timing restriction is met. Table 6.1 also shows the number of dummy reads that are required before reading the register indicated. The number of BYTE_TEST reads in this table is based on the minimum timing for Tcycle (45ns). For microprocessors with slower busses the number of reads may be reduced as long as the total time is equal to, or greater than the time specified in the table. Note that dummy reads of the BYTE_TEST register are not required as long as the minimum time period is met. Table 6.1 Read After Write Timing Rules MINIMUM WAIT TIME FOR READ FOLLOWING ANY WRITE CYCLE (IN NS) 0 135 90 45 0 45
113
REGISTER NAME ID_REV IRQ_CFG INT_STS INT_EN BYTE_TEST FIFO_INT
SMSC LAN9218I
NUMBER OF BYTE_TEST READS (ASSUMING TCYCLE OF 45NS) 0 3 2 1 0 1
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Table 6.1 Read After Write Timing Rules MINIMUM WAIT TIME FOR READ FOLLOWING ANY WRITE CYCLE (IN NS) 45 45 45 45 0 135 315 45 45 135 45 180 0 45 45 45 45 45 NUMBER OF BYTE_TEST READS (ASSUMING TCYCLE OF 45NS) 1 1 1 1 0 3 7 1 1 3 1 4 0 1 1 1 1 1
REGISTER NAME RX_CFG TX_CFG HW_CFG RX_DP_CTRL RX_FIFO_INF TX_FIFO_INF PMT_CTRL GPIO_CFG GPT_CFG GPT_CNT ENDIAN FREE_RUN RX_DROP MAC_CSR_CMD MAC_CSR_DATA AFC_CFG E2P_CMD E2P_DATA
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6.1.2
Special Restrictions on Back-to-Back Read Cycles
There are also restrictions on specific back-to-back read operations. These restrictions concern reading specific registers after reading resources that have side effects. In many cases there is a delay between reading the LAN9218I, and the subsequent indication of the expected change in the control register values. In order to prevent the host from reading stale data on back-to-back reads, minimum wait periods have been established. These periods are specified in Table 6.2, "Read After Read Timing Rules". The host processor is required to wait the specified period of time between read operations of specific combinations of resources. The wait period is dependant upon the combination of registers being read. Performing "dummy" reads of the BYTE_TEST register is a convenient way to guarantee that the minimum wait time restriction is met. Table 6.2 also shows the number of dummy reads that are required for back-to-back read operations. The number of BYTE_TEST reads in this table is based on the minimum timing for Tcycle . For microprocessors with slower busses the number of reads may be reduced as long as the total time is equal to, or greater than the time specified in the table. Dummy reads of the BYTE_TEST register are not required as long as the minimum time period is met. Table 6.2 Read After Read Timing Rules OR PERFORM THIS MANY READS OF BYTE_TEST… (ASSUMING Tcycle OF 45NS) 3 3 3 4
AFTER READING... RX Data FIFO RX Status FIFO TX Status FIFO RX_DROP
WAIT FOR THIS MANY NS… 135 135 135 180
BEFORE READING... RX_FIFO_INF RX_FIFO_INF TX_FIFO_INF RX_DROP
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6.2
PIO Reads
PIO reads can be used to access CSRs or RX Data and RX/TX status FIFOs. In this mode, counters in the CSRs are latched at the beginning of the read cycle. Read data is valid as indicated in the timing diagram. PIO reads can be performed using Chip Select (nCS) or Read Enable (nRD). Either or both of these control signals must go high between cycles for the period specified. PIO reads are supported for both 16- and 32-bit access. Timing for 16-bit and 32-bit PIO Read cycles is identical with the exception that D[31:16] are not driven during a 16-bit read. Note: Some registers have restrictions on the timing of back-to-back, write-read and read-read cycles.
A[7:1]
nCS, nRD
Data Bus
Figure 6.1 PIO Read Cycle Timing Note: The “Data Bus” width is 32 bits with optional support for 16-bit bus widths
Table 6.3 PIO Read Timing SYMBOL tcycle tcsl tcsh tcsdv tasu tah tdon tdoff tdoh DESCRIPTION Read Cycle Time nCS, nRD Assertion Time nCS, nRD Deassertion Time nCS, nRD Valid to Data Valid Address Setup to nCS, nRD Valid Address Hold Time Data Buffer Turn On Time Data Buffer Turn Off Time Data Output Hold Time 0 0 0 0 7 MIN 45 32 13 30 TYP MAX UNITS ns ns ns ns ns ns ns ns ns
Note: A PIO Read cycle begins when both nCS and nRD are asserted. The cycle ends when either or both nCS and nRD are deasserted. They may be asserted and deasserted in any order.
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6.3
PIO Burst Reads
In this mode, performance is improved by allowing up to 8 DWORD read cycles, or 16 WORD read cycles back-to-back. PIO Burst Reads can be performed using Chip Select (nCS) or Read Enable (nRD). Either or both of these control signals must go high between bursts for the period specified. Timing for 16-bit and 32-bit PIO Burst Mode Read cycles is identical, with the exception that D[31:16] are not driven during a 16-bit burst.
A[7:5]
A[4:1] nCS, nRD
Data Bus
Figure 6.2 PIO Burst Read Cycle Timing Note: The “Data Bus” width is 32 bits with optional support for 16-bit bus widths
Table 6.4 PIO Burst Read Timing SYMBOL tcsh tcsdv tacyc tasu tadv tah tdon tdoff tdoh DESCRIPTION nCS, nRD Deassertion Time nCS, nRD Valid to Data Valid Address Cycle Time Address Setup to nCS, nRD valid Address Stable to Data Valid Address Hold Time Data Buffer Turn On Time Data Buffer Turn Off Time Data Output Hold Time 0 0 0 7 45 0 40 ns ns ns ns ns MIN 13 30 TYP MAX UNITS ns ns
Note: A PIO Burst Read cycle begins when both nCS and nRD are asserted. The cycle ends when either or both nCS and nRD are deasserted. They may be asserted and deasserted in any order.
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6.4
RX Data FIFO Direct PIO Reads
In this mode the upper address inputs are not decoded, and any read of the LAN9218I will read the RX Data FIFO. This mode is enabled when FIFO_SEL is driven high during a read access. This is normally accomplished by connecting the FIFO_SEL signal to high-order address line. This mode is useful when the host processor must increment its address when accessing the LAN9218I . Timing is identical to a PIO read, and the FIFO_SEL signal has the same timing characteristics as the address lines. Timing for 16-bit and 32-bit Direct PIO Read cycles is identical with the exception that D[31:16] is not driven during a 16-bit read. Note that address lines A[2:1] are still used, and address bits A[7:3] are ignored.
FIFO_SEL A[2:1]
nCS, nRD
Data Bus
Figure 6.3 RX Data FIFO Direct PIO Read Cycle Timing Note: The “Data Bus” width is 32 bits with optional support for 16-bit bus widths Table 6.5 RX Data FIFO Direct PIO Read Timing SYMBOL tcycle tcsl tcsh tcsdv tasu tah tdon tdoff tdoh DESCRIPTION Read Cycle Time nCS, nRD Assertion Time nCS, nRD Deassertion Time nCS, nRD Valid to Data Valid Address, FIFO_SEL Setup to nCS, nRD Valid Address, FIFO_SEL Hold Time Data Buffer Turn On Time Data Buffer Turn Off Time Data Output Hold Time 0 0 0 0 7 MIN 45 32 13 30 TYP MAX UNITS ns ns ns ns ns ns ns ns ns
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Note: An RX Data FIFO Direct PIO Read cycle begins when both nCS and nRD are asserted. The cycle ends when either or both nCS and nRD are de-asserted. They may be asserted and deasserted in any order.
6.5
RX Data FIFO Direct PIO Burst Reads
In this mode the upper address inputs are not decoded, and any burst read of the LAN9218I will read the RX Data FIFO. This mode is enabled when FIFO_SEL is driven high during a read access. This is normally accomplished by connecting the FIFO_SEL signal to a high-order address line. This mode is useful when the host processor must increment its address when accessing the LAN9218I. Timing is identical to a PIO Burst Read, and the FIFO_SEL signal has the same timing characteristics as the address lines. In this mode, performance is improved by allowing an unlimited number of back-to-back DWORD or WORD read cycles. RX Data FIFO Direct PIO Burst Reads can be performed using Chip Select (nCS) or Read Enable (nRD). When either or both of these control signals go high, they must remain high for the period specified. Timing for 16-bit and 32-bit RX Data FIFO Direct PIO Burst Reads is identical with the exception that D[31:16] are not driven during a 16-bit burst. Note that address lines A[2:1] are still used, and address bits A[7:3] are ignored.
FIFO_SEL A[2:1] nCS, nRD Data Bus
Figure 6.4 RX Data FIFO Direct PIO Burst Read Cycle Timing Note: The “Data Bus” width is 32 bits with optional support for 16-bit bus widths. Table 6.6 RX Data FIFO Direct PIO Burst Read Cycle Timing SYMBOL tcsh tcsdv tacyc tasu tadv tah tdon
SMSC LAN9218I
DESCRIPTION nCS, nRD Deassertion Time nCS, nRD Valid to Data Valid Address Cycle Time Address, FIFO_SEL Setup to nCS, nRD Valid Address Stable to Data Valid Address, FIFO_SEL Hold Time Data Buffer Turn On Time
MIN 13
TYP
MAX
UNITS ns
30 45 0 40 0 0
ns
ns
ns ns
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Table 6.6 RX Data FIFO Direct PIO Burst Read Cycle Timing SYMBOL tdoff tdoh DESCRIPTION Data Buffer Turn Off Time Data Output Hold Time 0 MIN TYP MAX 7 UNITS ns ns
Note: An RX Data FIFO Direct PIO Burst Read cycle begins when both nCS and nRD are asserted. The cycle ends when either or both nCS and nRD are deasserted. They may be asserted and deasserted in any order.
6.6
PIO Writes
PIO writes are used for all LAN9218I write cycles. PIO writes can be performed using Chip Select (nCS) or Write Enable (nWR). Either or both of these control signals must go high between cycles for the period specified. PIO Writes are valid for 16- and 32-bit access. Timing for 16-bit and 32-bit PIO write cycles are identical with the exception that D[31:16] are ignored during a 16-bit write.
A[7:1]
nCS, nRD
Data Bus
Figure 6.5 PIO Write Cycle Timing Note: The “Data Bus” width is 32 bits with optional support for 16-bit bus widths. Table 6.7 PIO Write Cycle Timing SYMBOL tcycle tcsl tcsh tasu tah tdsu DESCRIPTION Write Cycle Time nCS, nWR Assertion Time nCS, nWR Deassertion Time Address Setup to nCS, nWR Assertion Address Hold Time Data Setup to nCS, nWR Deassertion
120
MIN
TYP
MAX
UNITS ns
32 13 0 0 7
ns ns ns ns ns
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Table 6.7 PIO Write Cycle Timing SYMBOL tdh DESCRIPTION Data Hold Time MIN 0 TYP MAX UNITS ns
Note: A PIO Write cycle begins when both nCS and nWR are asserted. The cycle ends when either or both nCS and nWR are deasserted. They may be asserted and deasserted in any order.
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6.7
TX Data FIFO Direct PIO Writes
In this mode the upper address inputs are not decoded, and any write to the LAN9218I will write the TX Data FIFO. This mode is enabled when FIFO_SEL is driven high during a write access. This is normally accomplished by connecting the FIFO_SEL signal to a high-order address line. This mode is useful when the host processor must increment its address when accessing the LAN9218I . Timing is identical to a PIO write, and the FIFO_SEL signal has the same timing characteristics as the address lines. Timing for 16-bit and 32-bit cycles is identical with the exception that D[31:16] is ignored during a 16bit write. Note that address lines A[2:1] are still used when the LAN9218I is operating in 32-bit and 16bit mode. Address bits A[7:3] are ignored.
FIFO_SEL A[2:1]
nCS, nRD
Data Bus
Figure 6.6 TX Data FIFO Direct PIO Write Timing Note: The “Data Bus” width is 32 bits with optional support for 16-bit bus widths. Table 6.8 TX Data FIFO Direct PIO Write Timing SYMBOL tcycle tcsl tcsh tasu tah tdsu tdh DESCRIPTION Write Cycle Time nCS, nWR Assertion Time nCS, nWR Deassertion Time Address, FIFO_SEL Setup to nCS, nWR Assertion Address, FIFO_SEL Hold Time Data Setup to nCS, nWR Deassertion Data Hold Time MIN 45 32 13 0 0 7 0 TYP MAX UNITS ns ns ns ns ns ns ns
Note: A TX Data FIFO Direct PIO Write cycle begins when both nCS and nWR are asserted. The cycle ends when either or both nCS and nWR are deasserted. They may be asserted and deasserted in any order.
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6.8
Reset Timing
T6.1 nRST T6.2 Configuration signals T6.4 Output drive T6.3
Table 6.9 Reset Timing PARAMETER T6.1 T6.2 T6.3 T6.4 DESCRIPTION Reset Pulse Width Configuration input setup to nRST rising Configuration input hold after nRST rising Output Drive after nRST rising MIN 200 200 10 16 TYP MAX UNITS us ns ns ns NOTES
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6.9
EEPROM Timing
The following specifies the EEPROM timing requirements for the LAN9218I
Figure 6.7 EEPROM Timing Table 6.10 EEPROM Timing Values SYMBOL tCKCYC tCKH tCKL tCSHCKH tCKLCSL tDVCKH tCKHDIS tDSCKH tDHCKH tCKLDIS tCSHDV tDHCSL tCSL DESCRIPTION EECLK Cycle time EECLK High time EECLK Low time EECS high before rising edge of EECLK EECLK falling edge to EECS low EEDIO valid before rising edge of EECLK (OUTPUT) EEDIO disable after rising edge EECLK (OUTPUT) EEDIO setup to rising edge of EECLK (INPUT) EEDIO hold after rising edge of EECLK (INPUT) EECLK low to data disable (OUTPUT) EEDIO valid after EECS high (VERIFY) EEDIO hold after EECS low (VERIFY) EECS low 0 1070 MIN 1110 550 550 1070 30 550 550 90 0 580 600 TYP MAX 1130 570 570 UNITS ns ns ns ns ns ns ns ns ns ns ns ns ns
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Chapter 7 Operational Characteristics
7.1 Absolute Maximum Ratings*
Supply Voltage ................................................................................................................... +3.3V +/- 10% Operating Temperature ...........................................................................................................-40 to 85°C Storage Temperature.........................................................................................................-65°C to 150°C Positive Voltage on any pin, with respect to Ground ........................................................................ 5.5V Negative Voltage on any pin, with respect to Ground ..................................................................... -0.3V Note: The maximum pin ratings do not apply to the following analog pins - ATEST, RBIAS, EXRES1, TPO +/-, TPI +/* Stresses exceeding those listed above could cause permanent damage to the device. This is a stress rating only and functional operation of the device at any other condition above those indicated in the operation sections of this specification is not implied. Note: When powering this device from laboratory or system power supplies, it is important that the absolute maximum ratings not be exceeded or device failure can result. Some power supplies exhibit voltage spikes on their outputs when AC power is switched on or off. In addition, voltage transients on the AC power line may appear on the DC output. If this possibility exists, it is suggested that a clamp circuit be used.
7.2
Power Consumption (Device Only)
This section provides typical power consumption values for the LAN9218I in various modes of operation. All of these values are preliminary. These measurements were taken under the following conditions: Temperature: ................................................................................................................................... +25°C Device VDD:................................................................................................................................... +3.30V Table 7.1 Power Consumption Device Only MODE Total Power - Typical (mW)
10BASE-T Operation D0, 10BASE-T /w traffic D0, Idle D1, Idle D2, Energy Detect Power Down D2, General Power Down 100BASE-TX Operation D0, 100BASE-TX /w traffic D0, Idle D1, Idle 402 439 301
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Table 7.1 Power Consumption Device Only (continued) MODE D2, Energy Detect Power Down (Cable disconnected) D2, General Power Down Note 7.1 Total Power - Typical (mW) 65 2
D0 = Normal Operation, D1 = WOL (Wake On LAN mode), D2= Low Power Energy Detect.
7.3
Power Consumption (Device and System Components)
This section provides typical power consumption values for a complete Ethernet interface based on the LAN9218I, including the power dissipated by the magnetics and other passive components. All of these values are preliminary. Please refer to AN 12.5x, entitled "Designing with the LAN9218 Family - Getting Started", that can be found on SMSC’s web site www.smsc.com, which details the magnetics and other components used. Note: The power measurements list below were taken under the following conditions: Temperature: ................................................................................................................................... +25°C Device VDD:................................................................................................................................... +3.30V Table 7.2 Power Consumption Device and System Components MODE Total Power - Typical (mW)
10BASE-T Operation D0, 10BASE-T /w traffic D0, Idle D1, Idle D2, Energy Detect Power Down D2, General Power Down 100BASE-TX Operation D0, 100BASE-TX /w traffic D0, Idle D1, Idle D2, Energy Detect Power Down D2, General Power Down
612 620 508 65 2
540 577 439 65 2
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7.4
DC Electrical Specifications
Table 7.3 below lists the worst case current consumption for each of the supplies of the LAN9218I. These figures are provided to assist system designers properly design the power supply; they cannot be used to determine typical power consumption of the device. All of these values are preliminary. Note: The current measurements listed below were taken under the following conditions: Temperature: ...........................................................................................................................-40 to 85°C Device VDD:....................................................................................................................+3.30 V +/- 10% Table 7.3 Supply Current Characteristics SUPPLY NAME VREG VDD_IO VDD_A VDD_REF
PARAMETER Internal Regulator Supply Current +3.3V I/O Supply Current +3.3V Analog Supply Current Reference Supply Current Note 7.2
MIN
TYP
MAX 69 13 40 31
UNITS mA mA mA mA
NOTES
Above figures do not include the supply current for the magnetics. Based on the recommended implementation, the maximum supply current needed for the magnetics is 108mA. Table 7.4 I/O Buffer Characteristics
PARAMETER I Type Input Buffer Low Input Level High Input Level IS Type Input Buffer Negative-Going Threshold Positive-Going Threshold Schmitt Trigger Hysteresis (VIHT - VILT) O12 Type Buffer Low Output Level High Output Level OD12 Type Buffer Low Output Level
SYMBOL
MIN
TYP
MAX
UNITS
NOTES
VILI VIHI
-0.3 2.0
0.8 5.5
V V
VILT VIHT VHYS
1.05 1.3 198
1.26 1.53 264
1.47 1.71 300
V V mV
Schmitt Trigger Schmitt Trigger
VOL VOH VDD - 0.4
0.4
V V
IOL = 12mA IOH = -12mA
VOL
0.4
V
IOL = 12mA
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Table 7.4 I/O Buffer Characteristics (continued) PARAMETER IO8 Type Buffer Low Input Level High Input Level Low Output Level High Output Level OD8 Type Buffer Low Output Level O8 Type Buffer Low Output Level High Output Level ICLK Input Buffer Low Input Level High Input Level VILCK VIHCK 1.4 0.5 V V VOL VOH VDD - 0.4 0.4 V V IOL = 8mA IOH = -8mA VOL 0.4 V IOL = 8mA VILI VIHI VOL VOH VDD - 0.4 -0.3 2.0 0.8 5.5 0.4 V V V V IOL = 8mA IOH = -8mA SYMBOL MIN TYP MAX UNITS NOTES
Table 7.5 100BASE-TX Transceiver Characteristics PARAMETER Peak Differential Output Voltage High Peak Differential Output Voltage Low Signal Amplitude Symmetry Signal Rise & Fall Time Rise & Fall Time Symmetry Duty Cycle Distortion Overshoot & Undershoot Jitter Note 7.3 Note 7.4 Note 7.5 SYMBOL VPPH VPPL VSS TRF TRFS DCD VOS MIN 950 -950 98 3.0 35 TYP 50 MAX 1050 -1050 102 5.0 0.5 65 5 1.4 UNITS mVpk mVpk % nS nS % % nS Note 7.5 NOTES Note 7.3 Note 7.3 Note 7.3 Note 7.3 Note 7.3 Note 7.4
Measured at the line side of the transformer, line replaced by 100Ω (+/- 1%) resistor. Offset from16 nS pulse width at 50% of pulse peak Measured differentially.
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Table 7.6 10BASE-T Transceiver Characteristics PARAMETER Transmitter Peak Differential Output Voltage Receiver Differential Squelch Threshold Note 7.6 SYMBOL VOUT VDS MIN 2.2 300 TYP 2.5 420 MAX 2.8 585 UNITS V mV NOTES Note 7.6
Measured at the line side of the transformer, line replaced by 100Ω (+/- 1%) resistor.
7.5
Clock Circuit
The LAN9218I can accept either a 25MHz crystal (preferred) or a 25 MHz clock oscillator (±50 PPM) input. The LAN9218I shares the 25MHz clock oscillator input (CLKIN) with the crystal input XTAL1/CLKIN (pin 6). The Input Clock Duty Cycle is 40% minimum, 50% typical and 60% maximum. It is recommended that a crystal utilizing matching parallel load capacitors be used for the LAN9218I crystal input/output signals (XTAL1, XTAL2). See Table 7.7, "Crystal Specifications" for crystal specifications. Table 7.7 Crystal Specifications Frequency Tolerance @ 25° C Frequency Stability Over Temp Operating Temp Range Shunt Capacitance Load Capacitance Drive Level ±50 PPM ±50 PPM -40 to 85° C 7.0 pF 20 pF ~ Parallel 0.5 mW
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Chapter 8 Package Outline
Figure 8.1 100 Pin TQFP Package Definition Table 8.1 100 Pin TQFP Package Parameters A A1 A2 D D1 E E1 H L L1 e q W R1 R2 ccc MIN ~ 0.05 1.35 15.80 13.90 15.80 13.90 0.09 0.45 ~ 0o 0.17 0.08 0.08 ~ NOMINAL ~ ~ ~ ~ ~ ~ ~ ~ 0.60 1.00 0.50 Basic ~ 0.22 ~ ~ ~ MAX 1.60 0.15 1.45 16.20 14.10 16.20 14.10 0.20 0.75 ~ 7o 0.27 ~ 0.20 0.08 REMARKS Overall Package Height Standoff Body Thickness X Span X body Size Y Span Y body Size Lead Frame Thickness Lead Foot Length Lead Length Lead Pitch Lead Foot Angle Lead Width Lead Shoulder Radius Lead Foot Radius Coplanarity
Notes: 1. Controlling Unit: millimeter. 2. Tolerance on the true position of the leads is ± 0.04 mm maximum. 3. Package body dimensions D1 and E1 do not include the mold protrusion. Maximum mold protrusion is 0.25 mm. 4. Dimension for foot length L measured at the gauge plane 0.25 mm above the seating plane. 5. Details of pin 1 identifier are optional but must be located within the zone indicated.
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