KSZ8862-16/32MQL
2-Port Ethernet Switch with Non-PCI Interface and Fiber Support Rev 3.1
General Description
The KSZ8862M is 2-port switch with non-PCI CPU interface and fiber support, and is available in 8/16-bit and 32-bit bus designs (see Ordering Information). This datasheet describes the KSZ8862M non-PCI CPU interface chip. The KSZ8862M is the industry’s first fully managed, 2port switch with a non-PCI CPU interface and fiber th support. It is based on a proven, 4 generation, integrated Layer-2 switch, compliant with IEEE 802.3u standards. For industrial applications, the KSZ8862M can run in half-duplex mode regardless of the application. In fiber mode, port 1 can be configurable to either 100BASE-FX or 100BASE-SX/10BASE-FL. The LED driver and post amplifier are also included for 10Base-FL and 100Base-SX applications. LinkMD
®
In copper mode, port 2 supports 10/100BASE-T/TX with HP Auto MDI/MDI-X for reliable detection of and correction for straight-through and crossover cables. ® Micrel’s proprietary LinkMD Time Domain Reflectometry (TDR)-based function is also available for determining the cable length, as well as cable diagnostics for identifying faulty cabling. The KSZ8862M offers an extensive feature set that includes tag/port-based VLAN, quality of service (QoS) priority management, management information base (MIB) counters, and CPU control/data interfaces to effectively address Fast Ethernet applications. The KSZ8862M contains: Two 10/100 transceivers with patented, mixed-signal, low-power technology, two media access control (MAC) units, a direct memory access (DMA) channel, a high-speed, non-blocking, switch fabric, a dedicated 1K entry forwarding table, and an on-chip frame buffer memory.
Functional Diagram
TX P o rt 1 F ib e r RX P o rt 2 Copper
LED D r iv e r Post Am p 1 0 /1 0 0 B a s e F L /F X /S X PHY 1 1 0 /1 0 0 MAC 1 1 K lo o k -u p E n g in e
FIFO, Flow Control, VLAN Tagging ,Priority
1 0 /1 0 0 B a s e T /T X PHY 2
1 0 /1 0 0 MAC 2
S c h e d u lin g M anagem ent
E m bedded P r o c e s s o r In te r fa c e
N o n -P C I CPU Bus In t e r f a c e U n it
QMU DMA C hannel
RXQ 4K B TXQ 4K B
B u ffe r M anagem ent
S w it c h H ost MAC
F ra m e B u ffe rs
8 ,1 6 , o r 3 2 -b it G e n e ric H o s t In t e r f a c e
C o n tr o l R e g is te rs
M IB C o u n te rs
P 1 L E D [3 :0 ] P 2 L E D [3 :0 ] E E P R O M I/F
LED D riv e r s
EEPROM In te rfa c e
Figure 1. KSZ8862M Functional Diagram
LinkMD is a registered trademark of Micrel, Inc.
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
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Features
Switch Management • Non-blocking switch fabric assures fast packet delivery by utilizing a 1K entry forwarding table and a store-and-forward architecture • Fully compliant with IEEE 802.3u standards • Full-duplex IEEE 802.3x flow control (Pause) with force mode option • Half-duplex back pressure flow control Advanced Switch Management • IEEE 802.1Q VLAN support for up to 16 groups (full range of VLAN IDs) • VLAN ID tag/untag options, on a per port basis • IEEE 802.1p/Q tag insertion or removal on a per port basis (egress) • Programmable rate limiting at the ingress and egress ports • Broadcast storm protection • IEEE 802.1d spanning tree protocol support • MAC filtering function to filter or forward unknown unicast packets • Direct forwarding mode enabling the processor to identify the ingress port and to specify the egress port • Internet Group Management Protocol (IGMP) v1/v2 snooping support for multicast packet filtering • IPV6 Multicast Listener Discovery (MLD) snooping support Fiber Support • Integrated LED driver and post amplifier for 10BASEFL and 100BASE-SX optical modules • 100BASE-FX/SX and 10BASE-FL fiber support on port 1 Monitoring • Port mirroring/monitoring/sniffing: ingress and/or egress traffic to any port • MIB counters for fully compliant statistics gathering – 34 MIB counters per port • Loopback modes for remote failure diagnostics Comprehensive Register Access • Control registers configurable on-the-fly (port-priority, 802.1p/d/Q) QoS/CoS Packets Prioritization Support • Per port, 802.1p and DiffServ-based • Remapping of 802.1p priority field on a per port basis Power Modes, Packaging, and Power Supplies • Full-chip hardware power-down (register configuration not saved) allows low power dissipation • Per port-based, software power-save on PHY (idle link detection, register configuration preserved) • Single power supply: 3.3V • Commercial Temperature Range: 0oC to +70oC • Industrial Temperature Range: –40oC to +85oC (see Ordering Information). • Available in 128-pin PQFP • Available in –16 version for 8/16-bit bus support and – 32 version for 32-bit bus support (see Ordering Information). Additional Features In addition to offering all of the features of an integrated Layer-2 managed switch, the KSZ8862M offers: • Dynamic buffer memory scheme – Essential for applications such as Video over IP where image jitter is unacceptable • 2-port switch with a flexible 8, 16, or 32-bit generic host processor interfaces ® • Micrel LinkMD cable diagnostics to determine cable length, diagnose faulty cables, and determine distance-to-fault • Hewlett Packard (HP) Auto-MDIX crossover with disable and enable options • Four priority queues to handle voice, video, data, and control packets • Ability to transmit and receive jumbo frame sizes up to 1916 bytes
Applications
• • • • • • • • Video Distribution Systems High-end Cable, Satellite, and IP set-top boxes Video over IP Voice over IP (VoIP) and Analog Telephone Adapters (ATA) Industrial Control in Latency Critical Applications Motion Control Industrial Control Sensor Devices (Temperature, Pressure, Levels, and Valves) Security and Surveillance Cameras
Markets
• • • Fast Ethernet Embedded Ethernet Industrial Ethernet
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Ordering Information
Part Number KSZ8862-16MQL-FX KSZ8862-16MQL KSZ8862-32MQL-FX KSZ8862-32MQL KSZ8862-100FX-EVAL KSZ8862-10FL-EVAL Temperature Range 0 C to 70 C 0 C to 70 C 0 C to 70 C 0 C to 70 C
o o o o o o o o
Package 128-Pin PQFP 128-Pin PQFP 128-Pin PQFP 128-Pin PQFP
Comment Port 1 operates on 100BASE-FX mode only Port 1 operates on 10BASE-FL or 100BASE-SX mode only Port 1 operates on 100BASE-FX mode only Port 1 operates on 10BASE-FL or 100BASE-SX mode only
Evaluation Board for the KSZ8862-16MQL at 100FX Mode Evaluation Board for the KSZ8862-16MQL at 100SX_10FL Mode
Revision History
Revision 1.0 2.0 3.0 Date 07/18/06 09/13/06 04/04/07 Summary of Changes First released Information Added evaluation ordering info. to Ordering Information Table Updated part ordering info. to Ordering Information Table Improve the ARDY low time in read cycle to 40ns and in write cycle to 50 ns during QMU data register access Changed the FL/SX part order information
3.1
8/13/10
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Content
General Description ........................................................................................................................................................1 Functional Diagram.........................................................................................................................................................1 Features ...........................................................................................................................................................................2 Applications.....................................................................................................................................................................2 Markets.............................................................................................................................................................................2 Ordering Information ......................................................................................................................................................3 Revision History ..............................................................................................................................................................3 Content.............................................................................................................................................................................4 List of Figures..................................................................................................................................................................9 List of Tables .................................................................................................................................................................10 Pin Configuration for KSZ8862-16MQL (8/16-Bit) ......................................................................................................11 Pin Description for KSZ8862-16MQL (8/16-Bit) ..........................................................................................................12 Pin Configuration for KSZ8862-32MQL (32-Bit) .........................................................................................................17 Pin Description for KSZ8862-32 MQL (32-Bit) ............................................................................................................18 Functional Description .................................................................................................................................................23 Functional Overview: Physical Layer Transceiver ....................................................................................................23
100BASE-TX Transmit............................................................................................................................................................. 23 100BASE-TX Receive.............................................................................................................................................................. 23 Scrambler/De-scrambler (100BASE-TX only) .......................................................................................................................... 23 100BASE-FX Operation........................................................................................................................................................... 23 100BASE-FX Signal Detection................................................................................................................................................. 23 100BASE-FX Far-End-Fault (FEF) .......................................................................................................................................... 24 100BASE-SX Operation........................................................................................................................................................... 24 Physical Interface ................................................................................................................................................................ 24 Enabling 100BASE-SX Mode .............................................................................................................................................. 24 Enabling Fiber Forced Mode .............................................................................................................................................. 24 10BASE-FL Operation ............................................................................................................................................................. 24 Physical Interface ................................................................................................................................................................ 24 Enabling 10BASE-FL Mode ................................................................................................................................................ 24 Enabling Fiber Forced Mode .............................................................................................................................................. 24 10BASE-T Transmit ................................................................................................................................................................. 25 10BASE-T Receive .................................................................................................................................................................. 25 LED Driver ............................................................................................................................................................................... 25 Post Amplifier........................................................................................................................................................................... 25 Power Management................................................................................................................................................................. 25 MDI/MDI-X Auto Crossover...................................................................................................................................................... 25 Straight Cable ...................................................................................................................................................................... 26 Crossover Cable .................................................................................................................................................................. 26 Auto Negotiation ...................................................................................................................................................................... 27 ® LinkMD Cable Diagnostics ..................................................................................................................................................... 28 Access .................................................................................................................................................................................. 28 Usage.................................................................................................................................................................................... 28
Functional Overview: MAC and Switch ......................................................................................................................29
Address Lookup ....................................................................................................................................................................... 29 Learning................................................................................................................................................................................... 29 Migration .................................................................................................................................................................................. 29 Aging........................................................................................................................................................................................ 29 Forwarding ............................................................................................................................................................................... 30 Switching Engine ..................................................................................................................................................................... 32 MAC Operation ........................................................................................................................................................................ 32
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Inter Packet Gap (IPG) ............................................................................................................................................................ 32 Back-Off Algorithm................................................................................................................................................................... 32 Late Collision ........................................................................................................................................................................... 32 Legal Packet Size .................................................................................................................................................................... 32 Flow Control............................................................................................................................................................................. 32 Half-Duplex Backpressure ....................................................................................................................................................... 32 Broadcast Storm Protection ..................................................................................................................................................... 33 Clock Generator....................................................................................................................................................................... 33
Bus Interface Unit (BIU)................................................................................................................................................33
Asynchronous Interface ........................................................................................................................................................... 35 Synchronous Interface ............................................................................................................................................................. 36 Summary.................................................................................................................................................................................. 36 BIU Implementation Principles ................................................................................................................................................. 37
Queue Management Unit (QMU) ..................................................................................................................................38
Transmit Queue (TXQ) Frame Format..................................................................................................................................... 38 Receive Queue (RXQ) Frame Format ..................................................................................................................................... 39
Advanced Switch Functions ........................................................................................................................................41
Spanning Tree Support............................................................................................................................................................ 41 IGMP Support .......................................................................................................................................................................... 42 “IGMP” Snooping................................................................................................................................................................... 42 “Multicast Address Insertion” in the Static MAC Table........................................................................................................... 42 IPv6 MLD Snooping ................................................................................................................................................................. 42 Port Mirroring Support.............................................................................................................................................................. 42 IEEE 802.1Q VLAN Support .................................................................................................................................................... 43 QoS Priority Support ................................................................................................................................................................ 43 Port-Based Priority................................................................................................................................................................... 43 802.1p-Based Priority .............................................................................................................................................................. 43 DiffServ-Based Priority............................................................................................................................................................. 44 Rate Limiting Support .............................................................................................................................................................. 44 MAC Filtering Function ............................................................................................................................................................ 45 Configuration Interface............................................................................................................................................................. 45 EEPROM Interface .................................................................................................................................................................. 45 Loopback Support.................................................................................................................................................................... 46 Far-end Loopback ............................................................................................................................................................... 46 Near-end (Remote) Loopback............................................................................................................................................. 46
CPU Interface I/O Registers .........................................................................................................................................48
I/O Registers ............................................................................................................................................................................ 48 Internal I/O Space Mapping ..................................................................................................................................................... 49
Register Map: Switch and MAC/PHY...........................................................................................................................57
Bit Type Definition.................................................................................................................................................................... 57 Bank 0-63 Bank Select Register (0x0E): BSR (same location in all Banks)............................................................................. 57 Bank 0 Base Address Register (0x00): BAR............................................................................................................................ 57 Bank 0 QMU RX Flow Control High Watermark Configuration Register (0x04): QRFCR ........................................................ 57 Bank 0 Bus Error Status Register (0x06): BESR ..................................................................................................................... 58 Bank 0 Bus Burst Length Register (0x08): BBLR..................................................................................................................... 58 Bank 1 Reserved ..................................................................................................................................................................... 58 Bank 2 Host MAC Address Register Low (0x00): MARL ......................................................................................................... 58 Bank 2 Host MAC Address Register Middle (0x02): MARM..................................................................................................... 59 Bank 2 Host MAC Address Register High (0x04): MARH ........................................................................................................ 59 Bank 3 On-Chip Bus Control Register (0x00): OBCR .............................................................................................................. 59 Bank 3 EEPROM Control Register (0x02): EEPCR ................................................................................................................. 60 Bank 3 Memory BIST INFO Register (0x04): MBIR ................................................................................................................. 60
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Bank 3 Global Reset Register (0x06): GRR............................................................................................................................. 60 Bank 3 Bus Configuration Register (0x08): BCFG ................................................................................................................... 61 Banks 4 – 15: Reserved........................................................................................................................................................... 61 Bank 16 Transmit Control Register (0x00): TXCR ................................................................................................................... 61 Bank 16 Transmit Status Register (0x02): TXSR..................................................................................................................... 61 Bank 16 Receive Control Register (0x04): RXCR.................................................................................................................... 62 Bank 16 TXQ Memory Information Register (0x08): TXMIR .................................................................................................... 62 Bank 16 RXQ Memory Information Register (0x0A): RXMIR ................................................................................................... 63 Bank 17 TXQ Command Register (0x00): TXQCR .................................................................................................................. 63 Bank 17 RXQ Command Register (0x02): RXQCR ................................................................................................................. 63 Bank 17 TX Frame Data Pointer Register (0x04): TXFDPR .................................................................................................... 63 Bank 17 RX Frame Data Pointer Register (0x06): RXFDPR.................................................................................................... 64 Bank 17 QMU Data Register Low (0x08): QDRL ..................................................................................................................... 64 Bank 17 QMU Data Register High (0x0A): QDRH ................................................................................................................... 64 Bank 18 Interrupt Enable Register (0x00): IER ........................................................................................................................ 65 Bank 18 Interrupt Status Register (0x02): ISR ......................................................................................................................... 66 Bank 18 Receive Status Register (0x04): RXSR ..................................................................................................................... 67 Bank 18 Receive Byte Counter Register (0x06): RXBC........................................................................................................... 67 Bank 19 Multicast Table Register 0 (0x00): MTR0................................................................................................................... 68 Bank 19 Multicast Table Register 1 (0x02): MTR1................................................................................................................... 68 Bank 19 Multicast Table Register 2 (0x04): MTR2................................................................................................................... 68 Bank 19 Multicast Table Register 3 (0x06): MTR3................................................................................................................... 68 Banks 20 – 31: Reserved......................................................................................................................................................... 68 Bank 32 Switch ID and Enable Register (0x00): SIDER .......................................................................................................... 69 Bank 32 Switch Global Control Register 1 (0x02): SGCR1...................................................................................................... 69 Bank 32 Switch Global Control Register 2 (0x04): SGCR2...................................................................................................... 70 Bank 32 Switch Global Control Register 3 (0x06): SGCR3...................................................................................................... 71 Bank 32 Switch Global Control Register 4 (0x08): SGCR4...................................................................................................... 71 Bank 32 Switch Global Control Register 5 (0x0A): SGCR5 ..................................................................................................... 72 Bank 33 Switch Global Control Register 6 (0x00): SGCR6...................................................................................................... 73 Bank 33 Switch Global Control Register 7 (0x02): SGCR7...................................................................................................... 73 Banks 34 – 38: Reserved......................................................................................................................................................... 73 Bank 39 MAC Address Register 1 (0x00): MACAR1 ............................................................................................................... 74 Bank 39 MAC Address Register 2 (0x02): MACAR2 ............................................................................................................... 74 Bank 39 MAC Address Register 3 (0x04): MACAR3 ............................................................................................................... 74 Bank 40 TOS Priority Control Register 1 (0x00): TOSR1 ........................................................................................................ 74 Bank 40 TOS Priority Control Register 2 (0x02): TOSR2 ........................................................................................................ 75 Bank 40 TOS Priority Control Register 3 (0x04): TOSR3 ........................................................................................................ 75 Bank 40 TOS Priority Control Register 4 (0x06): TOSR4 ........................................................................................................ 76 Bank 40 TOS Priority Control Register 5 (0x08): TOSR5 ........................................................................................................ 76 Bank 40 TOS Priority Control Register 6 (0x0A): TOSR6 ........................................................................................................ 77 Bank 41 TOS Priority Control Register 7 (0x00): TOSR7 ........................................................................................................ 77 Bank 41 TOS Priority Control Register 8 (0x02): TOSR8 ........................................................................................................ 78 Bank 42 Indirect Access Control Register (0x00): IACR .......................................................................................................... 78 Bank 42 Indirect Access Data Register 1 (0x02): IADR1 ......................................................................................................... 79 Bank 42 Indirect Access Data Register 2 (0x04): IADR2 ......................................................................................................... 79 Bank 42 Indirect Access Data Register 3 (0x06): IADR3 ......................................................................................................... 79 Bank 42 Indirect Access Data Register 4 (0x08): IADR4 ......................................................................................................... 79 Bank 42 Indirect Access Data Register 5 (0x0A): IADR5......................................................................................................... 79 Bank 43: Reserved .................................................................................................................................................................. 79 Bank 44 Digital Testing Status Register (0x00): DTSR............................................................................................................ 80 Bank 44 Analog Testing Status Register (0x02): ATSR ........................................................................................................... 80
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Bank 44 Digital Testing Control Register (0x04): DTCR .......................................................................................................... 80 Bank 44 Analog Testing Control Register 0 (0x06): ATCR0 .................................................................................................... 80 Bank 44 Analog Testing Control Register 1 (0x08): ATCR1 .................................................................................................... 80 Bank 44 Analog Testing Control Register 2 (0x0A): ATCR2 .................................................................................................... 80 Bank 45 PHY 1 MII-Register Basic Control Register (0x00): P1MBCR ................................................................................... 80 Bank 45 PHY 1 MII-Register Basic Status Register (0x02): P1MBSR ..................................................................................... 82 Bank 45 PHY 1 PHYID Low Register (0x04): PHY1ILR........................................................................................................... 82 Bank 45 PHY 1 PHYID High Register (0x06): PHY1IHR ......................................................................................................... 82 Bank 45 PHY 1 Auto-Negotiation Advertisement Register (0x08): P1ANAR ........................................................................... 83 Bank 45 PHY 1 Auto-Negotiation Link Partner Ability Register (0x0A): P1ANLPR .................................................................. 83 Bank 46 PHY 2 MII-Register Basic Control Register (0x00): P2MBCR ................................................................................... 84 Bank 46 PHY 2 MII-Register Basic Status Register (0x02): P2MBSR ..................................................................................... 85 Bank 46 PHY 2 PHYID Low Register (0x04): PHY2ILR........................................................................................................... 85 Bank 46 PHY 2 PHYID High Register (0x06): PHY2IHR ......................................................................................................... 85 Bank 46 PHY 2 Auto-Negotiation Advertisement Register (0x08): P2ANAR ........................................................................... 86 Bank 46 PHY 2 Auto-Negotiation Link Partner Ability Register (0x0A): P2ANLPR .................................................................. 86 Bank 47 PHY1 Special Control/Status Register (0x02): P1PHYCTRL..................................................................................... 87 ® Bank 47 PHY2 LinkMD Control/Status (0x04): P2VCT .......................................................................................................... 87 Bank 47 PHY2 Special Control/Status Register (0x06): P2PHYCTRL..................................................................................... 88 Bank 48 Port 1 Control Register 1 (0x00): P1CR1................................................................................................................... 88 Bank 48 Port 1 Control Register 2 (0x02): P1CR2................................................................................................................... 89 Bank 48 Port 1 VID Control Register (0x04): P1VIDCR........................................................................................................... 90 Bank 48 Port 1 Control Register 3 (0x06): P1CR3................................................................................................................... 90 Bank 48 Port 1 Ingress Rate Control Register (0x08): P1IRCR ............................................................................................... 91 Bank 48 Port 1 Egress Rate Control Register (0x0A): P1ERCR.............................................................................................. 93 ® Bank 49 Port 1 PHY Special Control/Status, LinkMD (0x00): P1SCSLMD ............................................................................ 95 Bank 49 Port 1 Control Register 4 (0x02): P1CR4................................................................................................................... 95 Bank 49 Port 1 Status Register (0x04): P1SR ......................................................................................................................... 96 Bank 50 Port 2 Control Register 1 (0x00): P2CR1................................................................................................................... 97 Bank 50 Port 2 Control Register 2 (0x02): P2CR2................................................................................................................... 97 Bank 50 Port 2 VID Control Register (0x04): P2VIDCR........................................................................................................... 97 Bank 50 Port 2 Control Register 3 (0x06): P2CR3................................................................................................................... 97 Bank 50 Port 2 Ingress Rate Control Register (0x08): P2IRCR ............................................................................................... 97 Bank 50 Port 2 Egress Rate Control Register (0x0A): P2ERCR.............................................................................................. 97 ® Bank 51 Port 2 PHY Special Control/Status, LinkMD (0x00): P2SCSLMD ............................................................................ 98 Bank 51 Port 2 Control Register 4 (0x02): P2CR4................................................................................................................... 99 Bank 51 Port 2 Status Register (0x04): P2SR ....................................................................................................................... 100 Bank 52 Host Port Control Register 1 (0x00): P3CR1 ........................................................................................................... 101 Bank 52 Host Port Control Register 2 (0x02): P3CR2 ........................................................................................................... 101 Bank 52 Host Port VID Control Register (0x04): P3VIDCR.................................................................................................... 102 Bank 52 Host Port Control Register 3 (0x06): P3CR3 ........................................................................................................... 102 Bank 52 Host Port Ingress Rate Control Register (0x08): P3IRCR........................................................................................ 102 Bank 52 Host Port Egress Rate Control Register (0x0A): P3ERCR ...................................................................................... 102 Banks 53 – 63: Reserved....................................................................................................................................................... 102
MIB (Management Information Base) Counters.......................................................................................................103
Format of “All Ports Dropped Packet” MIB Counters ............................................................................................................. 104 Additional MIB Information..................................................................................................................................................... 105
Static MAC Address Table .........................................................................................................................................106
Static MAC Table Lookup Examples:
106
Dynamic MAC Address Table ....................................................................................................................................107
Dynamic MAC Address Lookup Example: ............................................................................................................................. 107
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VLAN Table ..................................................................................................................................................................108
VLAN Table Lookup Examples: ............................................................................................................................................. 108
Absolute Maximum Ratings ....................................................................................................................................109 (1) Operating Ratings ....................................................................................................................................................109 (1) Electrical Characteristics ........................................................................................................................................110 Timing Specifications .................................................................................................................................................111
Asynchronous Timing without using Address Strobe (ADSN = 0).......................................................................................... 111 Asynchronous Timing Using Address Strobe (ADSN) ........................................................................................................... 112 Asynchronous Timing Using DATACSN ................................................................................................................................ 113 Address Latching Timing for All Modes.................................................................................................................................. 114 Synchronous Timing in Burst Write (VLBUSN = 1) ................................................................................................................ 115 Synchronous Timing in Burst Read (VLBUSN = 1)................................................................................................................ 116 Synchronous Write Timing (VLBUSN = 0) ............................................................................................................................. 117 Synchronous Read Timing (VLBUSN = 0) ............................................................................................................................. 118 EEPROM Timing.................................................................................................................................................................... 119 Auto Negotiation Timing......................................................................................................................................................... 120 Reset Timing.......................................................................................................................................................................... 121
(1)
Selection of Isolation Transformers..........................................................................................................................122 Selection of Reference Crystal ..................................................................................................................................122 Package Information ...................................................................................................................................................123 Acronyms and Glossary.............................................................................................................................................124
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List of Figures
Figure 1. KSZ8862M Functional Diagram .................................................................................................................................... 1 Figure 2. Standard – KSZ8862-16 MQL 128-Pin PQFP (Top View) ...................................................................................... 11 Figure 3. Standard – KSZ8862-32 MQL 128-Pin PQFP (Top View) ...................................................................................... 17 Figure 4. Typical Straight Cable Connection ............................................................................................................................. 26 Figure 5. Typical Crossover Cable Connection ......................................................................................................................... 26 Figure 6. Auto Negotiation and Parallel Operation.................................................................................................................... 27 Figure 7. Destination Address Lookup Flow Chart in Stage One ........................................................................................... 30 Figure 8. Destination Address Resolution Flow Chart in Stage Two...................................................................................... 31 Figure 9. Mapping from ISA-like, EISA-like, and VLBus-like transactions to the KSZ8862M Bus..................................... 36 Figure 10. KSZ8862M 8-Bit, 16-Bit, and 32-Bit Data Bus Connections ................................................................................. 37 Figure 11. 802.1p Priority Field Format ...................................................................................................................................... 44 Figure 12. Port 2 Far-End Loopback Path .................................................................................................................................. 47 Figure 13. Port 1 and port 2 Near-End (Remote) Loopback Path .......................................................................................... 47 Figure 14. Asynchronous Cycle – ADSN = 0 ........................................................................................................................... 111 Figure 15. Asynchronous Cycle – Using ADSN ...................................................................................................................... 112 Figure 16. Asynchronous Cycle – Using DATACSN .............................................................................................................. 113 Figure 17. Address Latching Cycle for All Modes ................................................................................................................... 114 Figure 18. Synchronous Burst Write Cycles – VLBUSN = 1 ................................................................................................. 115 Figure 19. Synchronous Burst Read Cycles – VLBUSN = 1 ................................................................................................. 116 Figure 20. Synchronous Write Cycle – VLBUSN = 0 .............................................................................................................. 117 Figure 21. Synchronous Read Cycle – VLBUSN = 0 ............................................................................................................. 118 Figure 22. EEPROM Read Cycle Timing Diagram ................................................................................................................. 119 Figure 23. Auto-Negotiation Timing ........................................................................................................................................... 120 Figure 24. Reset Timing .............................................................................................................................................................. 121 Figure 25. 128-Pin PQFP Package ........................................................................................................................................... 123
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List of Tables
Table 1. MDI/MDI-X Pin Definitions.................................................................................................................................................. 25 Table 2. Bus Interface Unit Signal Grouping .................................................................................................................................... 35 Table 3. Transmit Queue Frame Format .......................................................................................................................................... 38 Table 4. Transmit Control Word Bit Fields........................................................................................................................................ 38 Table 5. Transmit Byte Count Format .............................................................................................................................................. 39 Table 6. Receive Queue Frame Format ........................................................................................................................................... 39 Table 7. FRXQ Packet Receive Status............................................................................................................................................. 40 Table 8. FRXQ RX Byte Count Field ................................................................................................................................................ 40 Table 9. Spanning Tree States......................................................................................................................................................... 41 Table 10. FID+DA Lookup in VLAN Mode........................................................................................................................................ 43 Table 11. FID+SA Lookup in VLAN Mode ........................................................................................................................................ 43 Table 12. EEPROM Format.............................................................................................................................................................. 45 Table 13. ConfigParam Word in EEPROM Format .......................................................................................................................... 46 Table 14. Format of Per Port MIB Counters .................................................................................................................................... 103 Table 15. Port 1 MIB Counters Indirect Memory Offset................................................................................................................... 104 Table 16. “All Ports Dropped Packet” MIB Counters Format ........................................................................................................... 104 Table 17. “All Ports Dropped Packet” MIB Counters Indirect Memory Offsets ................................................................................ 104 Table 18. Static MAC Table Format (8 Entries).............................................................................................................................. 106 Table 19. Dynamic MAC Address Table Format (1024 Entries)..................................................................................................... 107 Table 20. VLAN Table Format (16 Entries) ..................................................................................................................................... 108 Table 21. Maximum Ratings........................................................................................................................................................... 109 Table 22. Operating Ratings........................................................................................................................................................... 109 Table 23. Electrical Characteristics ................................................................................................................................................ 110 Table 24. Asynchronous Cycle (ADSN = 0) Timing Parameters .................................................................................................... 111 Table 25. Asynchronous Cycle using ADSN Timing Parameters ................................................................................................... 112 Table 26. Asynchronous Cycle using DATACSN Timing Parameters ............................................................................................ 113 Table 27. Address Latching Timing Parameters............................................................................................................................. 114 Table 28. Synchronous Burst Write Timing Parameters................................................................................................................. 115 Table 29. Synchronous Burst Read Timing Parameters ................................................................................................................ 116 Table 30. Synchronous Write (VLBUSN = 0) Timing Parameters .................................................................................................. 117 Table 31. Synchronous Read (VLBUSN = 0) Timing Parameters .................................................................................................. 118 Table 32. EEPROM Timing Parameters......................................................................................................................................... 119 Table 33. Auto Negotiation Timing Parameters.............................................................................................................................. 120 Table 34. Reset Timing Parameters............................................................................................................................................... 121 Table 35. Transformer Selection Criteria........................................................................................................................................ 122 Table 36. Qualified Single Port Magnetic ....................................................................................................................................... 122 Table 37. Typical Reference Crystal Characteristics...................................................................................................................... 122
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Pin Configuration for KSZ8862-16MQL (8/16-Bit)
Figure 2. 128-Pin PQFP (Top View)
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Pin Description for KSZ8862-16MQL (8/16-Bit)
Pin Number 1 2 3 Pin Name TEST_EN SCAN_EN P1LED2 P1LED1 P1LED0 Type I I Opu Opu Opu P1LED3 /P2LED3 P1LED2/P2LED2 P1LED1/P2LED1 P1LED0/P2LED0
2
Pin Function Test Enable For normal operation, 1K ohm pull-down this pin to ground. Scan Test Scan MUX Enable For normal operation, 1K ohm pull-down this pin to ground. Port 1 and Port 2 LED indicators defined as follows: Switch Global Control Register 5: SGCR5 bit [15,9] [0,0] Default — Link/Act Full duplex/Col Speed [0,1] — 100Link/Act 10Link/Act Full duplex
1
4
5
Reg. SGCR5 bit [15,9] [1,0] P1LED3 /P2LED3 P1LED2/P2LED2 P1LED1/P2LED1 P1LED0/P2LED0 6 7 8 P2LED2 P2LED1 P2LED0 Opu Opu Opu
2
[1,1] — — — —
Act Link Full duplex/Col Speed
Notes: 1. Link = On; Activity = Blink; Link/Act = On/Blink; Full Dup/Col = On/Blink; Full Duplex = On (Full duplex); Off (Half duplex) Speed = On (100BASE-T); Off (10BASE-T) 2. P1LED3 is pin 27. P2LED3 is pin 22. Digital ground 3.3V digital VDDIO input power supply for IO with well decoupling capacitors. Ready Return Not: For VLBus-like mode: Asserted by the host to complete synchronous read cycles. If the host doesn’t connect to this pin, assert this pin. For burst mode (32-bit interface only): Host drives this pin low to signal waiting states. Bus Interface Clock Local bus clock for synchronous bus systems. Maximum frequency is 50MHz. This pin should be tied Low or unconnected if it is in asynchronous mode. No connect. No connect. Synchronous Ready Not Ready signal to interface with synchronous bus for both EISA-like and VLBus-like extended accesses. For VLBus-like mode, the falling edge of this signal indicates ready. This signal is synchronous to the bus clock signal BCLK. For burst mode (32-bit interface only), the KSZ8862M drives this pin low to signal wait states.
9 10 11
DGND VDDIO RDYRTNN
Gnd P Ipd
12
BCLK
Ipd
13 14 15
NC NC SRDYN
Ipu Opu Opu
August 2010
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�Micrel, Inc.
Pin Number 16 Pin Name INTRN Type Opd Pin Function
KSZ8862-16/32MQL
Interrupt Active Low signal to host CPU to indicate an interrupt status bit is set, this pin need an external 4.7K pull-up resistor. Local Device Not Active Low output signal, asserted when AEN is Low and A15-A4 decode to the KSZ8862M address programmed into the high byte of the base address register. LDEVN is a combinational decode of the Address and AEN signal. Read Strobe Not Asynchronous read strobe, active Low. EEPROM Chip Select Asynchronous Ready ARDY may be used when interfacing asynchronous buses to extend bus access cycles. It is asynchronous to the host CPU or bus clock. This pin needs an external 4.7K pull-up resistor. Cycle Not For VLBus-like mode cycle signal; this pin follows the addressing cycle to signal the command cycle. For burst mode (32-bit interface only), this pin stays High for read cycles and Low for write cycles. Port 2 LED indicator See the description in pins 6, 7, and 8. Digital IO ground 1.2V digital core voltage output (internal 1.2V LDO power supply output), this 1.2V output pin provides power to VDDC, VDDA and VDDAP pins. Note: Internally generated power voltage. Do not connect an external power supply to this pin. This pin is used for connecting external filter (Ferrite bead and capacitors). VLBus-like Mode Pull-down or float: Bus interface is configured for synchronous mode. Pull-up: Bus interface is configured for 8-bit or 16-bit asynchronous mode or EISAlike burst mode. EEPROM Enable EEPROM is enabled and connected when this pin is pull-up. EEPROM is disabled when this pin is pull-down or no connect. Port 1 LED indicator. See the description in pins 3, 4, and 5. EEPROM Data Out This pin is connected to DI input of the serial EEPROM. EEPROM Serial Clock A 4μs serial output clock to load configuration data from the serial EEPROM.
17
LDEVN
Opd
18 19 20
RDN EECS ARDY
Ipd Opu Opd
21
CYCLEN
Ipd
22 23 24
P2LED3 DGND VDDCO
Opd Gnd P
25
VLBUSN
Ipd
26
EEEN
Ipd
27 28 29
P1LED3 EEDO EESK
Opd Opd Opd
30
EEDI
Ipd
EEPROM Data In This pin is connected to DO output of the serial EEPROM when EEEN is pull-up. This pin can be pull-down for 8-bit bus mode, pull-up for 16-bus mode or don’t care for 32-bus mode when EEEN is pull-down (without EEPROM). Synchronous Write/Read Write/Read signal for synchronous bus accesses. Write cycles when high and Read cycles when low. Address Enable Address qualifier for the address decoding, active Low.
31
SWR
Ipd
32
AEN
Ipu
August 2010
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�Micrel, Inc.
Pin Number 33 34 35 Pin Name WRN DGND ADSN Type Ipd Gnd Ipd Pin Function Write Strobe Not Asynchronous write strobe, active Low. Digital IO ground
KSZ8862-16/32MQL
Address Strobe Not For systems that require address latching, the rising edge of ADSN indicates the latching moment of A15-A1 and AEN. Full-chip power-down. Low = Power down; High or floating = Normal operation. Analog ground 1.2V analog VDD input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. Analog ground No connect Fiber mode select for port 1. 1K ohm pull-up to 3.3V for 100Base-FX, 100 ohm pulldown to GND for 100Base-SX or 10Base-FL. Analog ground 1.2V analog VDD input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. Fiber signal detect input for port 1 in 100Base-FX fiber mode. 1K ohm pull-up to 3.3V for port 1 in 100Base-SX or 10Base-FL fiber modes. Port 1 physical receive (MDI) signal (+ differential) from external fiber module Port 1 physical receive (MDI) signal (– differential) from external fiber module Analog ground Port 1 physical transmit (MDI) signal (+ differential) to external fiber module Port 1 physical transmit (MDI) signal (– differential) to external fiber module 3.3V analog VDD input power supply with well decoupling capacitors. 3.3V analog VDD input power supply with well decoupling capacitors. Port 2 physical receive (MDI) or transmit (MDIX) signal (- differential) Port 2 physical receive (MDI) or transmit (MDIX) signal (+ differential) Analog ground Port 2 physical transmit (MDI) or receive (MDIX) signal (- differential) Port 2 physical transmit (MDI) or receive (MDIX) signal (+ differential) 1.2 analog VDD input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. Analog ground No connect No connect Set physical transmits output current. Pull-down this pin with a 3.01K 1% resistor to ground. Analog ground 1.2V analog VDD for PLL input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. Analog ground
36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63
PWRDN AGND VDDA AGND NC 100FX/10FL AGND VDDA FXSD1 RXP1 RXM1 AGND TXP1 TXM1 VDDATX VDDARX RXM2 RXP2 AGND TXM2 TXP2 VDDA AGND NC NC ISET AGND VDDAP
Ipu Gnd P Gnd — Ipu Gnd P I I/O I/O Gnd I/O I/O P P I/O I/O Gnd I/O I/O P Gnd Ipu Ipu O Gnd P
64
AGND
Gnd
August 2010
14
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�Micrel, Inc.
Pin Number 65 66 Pin Name X1 X2 Type I O Pin Function
KSZ8862-16/32MQL
25MHz crystal or oscillator clock connection. Pins (X1, X2) connect to a crystal. If an oscillator is used, X1 connects to a 3.3V tolerant oscillator and X2 is a no connect. Note: Clock requirement is 50ppm for either crystal or oscillator. Hardware reset pin (active Low). This reset input is required minimum of 10ms low after stable supply voltage 3.3V. Address 15 Address 14 Address 13 Address 12 Address 11 Address 10 Address 9 Address 8 Address 7 Address 6 Digital IO ground 3.3V digital VDDIO input power supply for IO with well decoupling capacitors. Address 5 Address 4 Address 3 Address 2 Address 1 No Connect No Connect Byte Enable 1 Not, Active low for Data byte 1 enable (don’t care in 8-bit bus mode). Byte Enable 0 Not, Active low for Data byte 0 enable (there is an internal inverter enabled and connected to the BE1N for 8-bit bus mode). No Connect Digital core ground 1.2V digital core VDD input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. 3.3V digital VDDIO input power supply for IO with well decoupling capacitors. No Connect No Connect No Connect No Connect No Connect No Connect No Connect No Connect No Connect No Connect No Connect
67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103
RSTN A15 A14 A13 A12 A11 A10 A9 A8 A7 A6 DGND VDDIO A5 A4 A3 A2 A1 NC NC BE1N BE0N NC DGND VDDC VDDIO NC NC NC NC NC NC NC NC NC NC NC
Ipu I I I I I I I I I I Gnd P I I I I I I I I I I Gnd P P I I I I I I I I I I I
August 2010
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Pin Number 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 Pin Name NC NC NC DGND VDDIO NC D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 DGND DGND VDDIO D2 D1 D0 Type I I I Gnd P I I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O Gnd Gnd P I/O I/O I/O Pin Function No Connect No Connect No Connect Digital IO ground
KSZ8862-16/32MQL
3.3V digital VDDIO input power supply for IO with well decoupling capacitors. No Connect Data 15 Data 14 Data 13 Data 12 Data 11 Data 10 Data 9 Data 8 Data 7 Data 6 Data 5 Data 4 Data 3 Digital IO ground Digital core ground 3.3V digital VDDIO input power supply for IO with well decoupling capacitors. Data 2 Data 1 Data 0
Legend: P = Power supply Gnd = Ground I/O = Bi-directional I = Input O = Output Ipd = Input with internal pull-down Ipu = Input with internal pull-up Opd = Output with internal pull-down Opu = Output with internal pull-up
August 2010
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KSZ8862-16/32MQL
Pin Configuration for KSZ8862-32MQL (32-Bit)
Figure 3. 128-Pin PQFP (Top View)
August 2010
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M9999-081310-3.1
�Micrel, Inc.
KSZ8862-16/32MQL
Pin Description for KSZ8862-32 MQL (32-Bit)
Pin Number 1 2 3 4 5 Pin Name TEST_EN SCAN_EN P1LED2 P1LED1 P1LED0 Type I I Opu Opu Opu P1LED3 /P2LED3 P1LED2/P2LED2 P1LED1/P2LED1 P1LED0/P2LED0
2
Pin Function Test Enable For normal operation, 1K ohm pull-down this pin-to-ground. Scan Test Scan Mux Enable For normal operation, 1K ohm pull-down this pin-to-ground. Port 1 and Port 2 LED indicators defined as follows: Switch Global Control Register 5: SGCR5 bit [15,9] [0,0] Default — Link/Act Full duplex/Col Speed [0,1] — 100Link/Act 10Link/Act Full duplex
1
Reg. SGCR5 bit [15,9] [1,0] P1LED3 /P2LED3 P1LED2/P2LED2 P1LED1/P2LED1 P1LED0/P2LED0 6 7 8 P2LED2 P2LED1 P2LED0 Opu Opu Opu
2
[1,1] — — — —
Act Link Full duplex/Col Speed
Notes: 1. Link = On; Activity = Blink; Link/Act = On/Blink; Full Dup/Col = On/Blink; Full Duplex = On (Full duplex); Off (Half duplex) Speed = On (100BASE-T); Off (10BASE-T) 2. P1LED3 is pin 27. P2LED3 is pin 22. Digital ground 3.3V digital VDDIO input power supply for IO with well decoupling capacitors. Ready Return Not For VLBus-like mode: Asserted by the host to complete synchronous read cycles. If the host doesn’t connect to this pin, assert this pin. For burst mode (32-bit interface only): Host drives this pin low to signal waiting states. Bus Interface Clock Local bus clock for synchronous bus systems. Maximum frequency is 50MHz. This pin should be tied Low or unconnected if it is in asynchronous mode. DATA Chip Select Not (For KSZ8862-32 Mode only) Chip select signal for QMU data register (QDRH, QDRL), active Low. When DATACSN is Low, the data path can be accessed regardless of the value of AEN, A15-A1, and the content of the BANK select register. No connect. Synchronous Ready Not Ready signal to interface with synchronous bus for both EISA-like and VLBus-like extend accesses. For VLBus-like mode, the falling edge of this signal indicates ready. This signal is synchronous to the bus clock signal BCLK. For burst mode (32-bit interface only), the KSZ8862M drives this pin low to signal wait states.
9 10 11
DGND VDDIO RDYRTNN
Gnd P Ipd
12
BCLK
Ipd
13
DATACSN
Ipu
14 15
NC SRDYN
Opu Opu
August 2010
18
M9999-081310-3.1
�Micrel, Inc.
Pin Number 16 Pin Name INTRN Type Opd Pin Function
KSZ8862-16/32MQL
Interrupt Active Low signal to host CPU to indicate an interrupt status bit is set, this pin need an external 4.7K pull-up resistor. Local Device Not Active Low output signal, asserted when AEN is Low and A15-A4 decode to the KSZ8862M address programmed into the high byte of the base address register. LDEVN is a combinational decode of the Address and AEN signal. Read Strobe Not Asynchronous read strobe, active Low. EEPROM Chip Select Asynchronous Ready ARDY may be used when interfacing asynchronous buses to extend bus access cycles. It is asynchronous to the host CPU or bus clock. This pin needs an external 4.7K pull-up resistor. Cycle Not For VLBus-like mode cycle signal; this pin follows the addressing cycle to signal the command cycle. For burst mode (32-bit interface only), this pin stays High for read cycles and Low for write cycles. Port 2 LED indicator. See the description in pins 6, 7, and 8. Digital IO ground 1.2V digital core voltage output (internal 1.2V LDO power supply output), this 1.2V output pin provides power to VDDC, VDDA and VDDAP pins. Note: Internally generated power voltage. Do not connect an external power supply to this pin. This pin is used for connecting external filter (Ferrite Bead and capacitors). VLBus-like Mode Pull-down or float: Bus interface is configured for synchronous mode. Pull-up: Bus interface is configured for 32-bit asynchronous mode or EISA-like burst mode. EEPROM Enable EEPROM is enabled and connected when this pin is pull-up. EEPROM is disabled when this pin is pull-down or no connect. Port 1 LED indicator See the description in pins 3, 4, and 5. EEPROM Data Out This pin is connected to DI input of the serial EEPROM. EEPROM Serial Clock A 4μs serial output clock to load configuration data from the serial EEPROM.
17
LDEVN
Opd
18 19 20
RDN EECS ARDY
Ipd Opu Opd
21
CYCLEN
Ipd
22 23 24
P2LED3 DGND VDDCO
Opd Gnd P
25
VLBUSN
Ipd
26
EEEN
Ipd
27 28 29
P1LED3 EEDO EESK
Opd Opd Opd
30
EEDI
Ipd
EEPROM Data In This pin is connected to DO output of the serial EEPROM when EEEN is pull-up. This pin can be pulled-down for 8-bit bus mode, pulled-up for 16-bus mode or either way for 32-bus mode when EEEN is pulled-down (without EEPROM). Synchronous Write/Read Write/Read signal for synchronous bus accesses. Write cycles when high and Read cycles when low. Address Enable Address qualifier for the address decoding, active Low. Write Strobe Not Asynchronous write strobe, active Low.
31
SWR
Ipd
32 33
AEN WRN
Ipu Ipd
August 2010
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�Micrel, Inc.
Pin Number 34 35 Pin Name DGND ADSN Type Gnd Ipd Pin Function Digital IO ground
KSZ8862-16/32MQL
Address Strobe Not For systems that require address latching, the rising edge of ADSN indicates the latching moment of A15-A1 and AEN. Full-chip power-down. Low = Power down; High or floating = Normal operation. Analog ground 1.2V analog VDD input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. Analog ground No connect Fiber mode select for port 1. 1K ohm pull-up to 3.3V for 100Base-FX, 100 ohm pull-down to GND for 100Base-SX or 10Base-FL. Analog ground 1.2V analog VDD input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. Fiber signal detect input for port 1 in 100Base-FX fiber mode. 1K ohm pull-up to 3.3V for port 1 in 100Base-SX or 10Base-FL fiber modes. Port 1 physical receive (MDI) signal (+ differential) from external fiber module Port 1 physical receive (MDI) signal (– differential) from external fiber module Analog ground Port 1 physical transmit (MDI) signal (+ differential) to external fiber module Port 1 physical transmit (MDI) signal (– differential) to external fiber module 3.3V analog VDD input power supply with well decoupling capacitors. 3.3V analog VDD Port 2 physical receive (MDI) or transmit (MDIX) signal (- differential) Port 2 physical receive (MDI) or transmit (MDIX) signal (+ differential) Analog ground Port 2 physical transmit (MDI) or receive (MDIX) signal (- differential) Port 2 physical transmit (MDI) or receive (MDIX) signal (+ differential) 1.2 analog VDD input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. Analog ground No connect No connect Set physical transmits output current. Pull-down this pin with a 3.01K 1% resistor to ground. Analog ground 1.2V analog VDD for PLL input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. Analog ground 25MHz crystal or oscillator clock connection. Pins (X1, X2) connect to a crystal. If an oscillator is used, X1 connects to a 3.3V tolerant oscillator and X2 is a no connect. Note: Clock is 50ppm for either crystal or oscillator. Hardware reset pin (active Low). This reset input is required minimum of 10ms low after stable supply voltage 3.3V.
36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66
PWRDN AGND VDDA AGND NC 100FX/10F L AGND VDDA FXSD1 RXP1 RXM1 AGND TXP1 TXM1 VDDATX VDDARX RXM2 RXP2 AGND TXM2 TXP2 VDDA AGND NC NC ISET AGND VDDAP AGND X1 X2
Ipu Gnd P Gnd — Ipu Gnd P I I/O I/O Gnd I/O I/O P P I/O I/O Gnd I/O I/O P Gnd Ipu Ipu O Gnd P Gnd I O
67
RSTN
Ipu
August 2010
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Pin Number 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 Pin Name A15 A14 A13 A12 A11 A10 A9 A8 A7 A6 DGND VDDIO A5 A4 A3 A2 A1 BE3N BE2N BE1N BE0N D31 DGND VDDC VDDIO D30 D29 D28 D27 D26 D25 D24 D23 D22 D21 D20 D19 D18 D17 DGND VDDIO Type I I I I I I I I I I Gnd P I I I I I I I I I I/O Gnd P P I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O Gnd P Pin Function Address 15 Address 14 Address 13 Address 12 Address 11 Address 10 Address 9 Address 8 Address 7 Address 6 Digital IO ground
KSZ8862-16/32MQL
3.3V digital VDDIO input power supply for IO with well decoupling capacitors. Address 5 Address 4 Address 3 Address 2 Address 1 Byte Enable 3 Not, Active low for Data byte 3 enable. Byte Enable 2 Not, Active low for Data byte 2 enable. Byte Enable 1 Not, Active low for Data byte 1 enable. Byte Enable 0 Not, Active low for Data byte 0 enable. Data 31 Digital core ground 1.2V digital core VDD input power supply from VDDCO (pin24) through external Ferrite bead and capacitor. 3.3V digital VDDIO input power supply for IO with well decoupling capacitors. Data 30 Data 29 Data 28 Data 27 Data 26 Data 25 Data 24 Data 23 Data 22 Data 21 Data 20 Data 19 Data 18 Data 17 Digital IO ground 3.3V digital VDDIO input power supply for IO with well decoupling capacitors.
August 2010
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�Micrel, Inc.
Pin Number 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 Pin Name D16 D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 DGND DGND VDDIO D2 D1 D0 Type I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O Gnd Gnd P I/O I/O I/O Pin Function Data 16 Data 15 Data 14 Data 13 Data 12 Data 11 Data 10 Data 9 Data 8 Data 7 Data 6 Data 5 Data 4 Data 3 Digital IO ground Digital core ground
KSZ8862-16/32MQL
3.3V digital VDDIO input power supply for IO with well decoupling capacitors. Data 2 Data 1 Data 0
Legend: P = Power supply Gnd = Ground I/O = Bi-directional I = Input O = Output Ipd = Input with internal pull-down Ipu = Input with internal pull-up Opd = Output with internal pull-down Opu = Output with internal pull-up
August 2010
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KSZ8862-16/32MQL
Functional Description
The KSZ8862M contains two 10/100 physical layer transceivers (PHYs), two MAC units, and a DMA channel integrated with a Layer-2 switch. The KSZ8862M contains a bus interface unit (BIU), which controls the KSZ8862M via an 8, 16, or 32-bit host interface. Physical signal transmission and reception are enhanced through the use of analog circuits in the PHY that make the design more efficient and allow for low power consumption.
Functional Overview: Physical Layer Transceiver
100BASE-TX Transmit The 100BASE-TX transmit function (port 2 only) performs parallel-to-serial conversion, 4B/5B coding, scrambling, NRZ-toNRZI conversion, and MLT3 encoding and transmission. The circuitry starts with a parallel-to-serial conversion, which converts the MII data from the MAC into a 125MHz serial bit stream. The data and control stream is then converted into 4B/5B coding, followed by a scrambler. The serialized data is further converted from NRZ-to-NRZI format, and then transmitted in MLT3 current output. The output current is set by an external1% 3.01KΩ resistor for the 1:1 transformer ratio. The output signal has a typical rise/fall time of 4ns and complies with the ANSI TP-PMD standard regarding amplitude balance, overshoot, and timing jitter. The wave-shaped 10BASE-T output is also incorporated into the 100BASE-TX transmitter. 100BASE-TX Receive The 100BASE-TX receiver function (port 2 only) performs adaptive equalization, DC restoration, MLT3-to-NRZI conversion, data and clock recovery, NRZI-to-NRZ conversion, de-scrambling, 4B/5B decoding, and serial-to- parallel conversion. The receiving side begins with the equalization filter to compensate for inter-symbol interference (ISI) over the twisted pair cable. Since the amplitude loss and phase distortion is a function of the cable length, the equalizer must adjust its characteristics to optimize performance. In this design, the variable equalizer makes an initial estimation based upon comparisons of incoming signal strength against some known cable characteristics, and then tunes itself for optimization. This is an ongoing process and self-adjusts against environmental changes such as temperature variations. Next, the equalized signal goes through a DC restoration and data conversion block. The DC restoration circuit is used to compensate for the effect of baseline wander and to improve the dynamic range. The differential data conversion circuit converts the MLT3 format back to NRZI. The slicing threshold is also adaptive. The clock recovery circuit extracts the 125MHz clock from the edges of the NRZI signal. This recovered clock is then used to convert the NRZI signal into the NRZ format. This signal is sent through the de-scrambler followed by the 4B/5B decoder. Finally, the NRZ serial data is converted to the MII format and provided as the input data to the MAC. Scrambler/De-scrambler (100BASE-TX only) The purpose of the scrambler is to spread the power spectrum of the signal to reduce electromagnetic interference (EMI) and baseline wander. Transmitted data is scrambled through the use of an 11-bit wide linear feedback shift register (LFSR). The scrambler generates a 2047-bit non-repetitive sequence, and the receiver then de-scrambles the incoming data stream using the same sequence as at the transmitter. 100BASE-FX Operation 100BASE-FX operation is supported on port 1 and similar to 100BASE-TX operation with the differences being that the scrambler/descrambler and MLT3 encoder/decoder are bypassed on transmission and reception. In addition, autonegotiation is bypassed and auto MDI/MDI-X is disabled. 100BASE-FX Signal Detection In 100BASE-FX operation, FXSD1 (fiber signal detect), input pin 44, is usually connected to the fiber transceiver SD (signal detect) output pin. 100BASE-FX mode is activated when the FXSD1 input pin is greater than 1V. When FXSD1 is between 1V and 1.8V, no fiber signal is detected and a far-end fault (FEF) is generated. When FXSD1 is over 2.2V, the fiber signal is detected. Alternatively, the designer may choose not to implement the FEF feature. In this case, the FXSD1 input pin is tied high to force 100BASE-FX mode.
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KSZ8862-16/32MQL
The 100BASE-FX signal detection is summarized as below: When FXSD1 input voltage is less than 0.2V, this is not a fiber mode or there is no fiber connection. When FXSD1 input voltage is greater than 1.0V but less than 1.8V, this is a FX mode but no signal detected and far-end fault generated. When FXSD1 input voltage is greater than 2.2V, this is a FX mode with signal detected. To ensure proper operation, a resistive voltage divider is recommended to adjust the fiber transceiver SD output voltage swing to match the FXSD1 pin’s input voltage threshold. 100BASE-FX Far-End-Fault (FEF) A far-end-fault (FEF) occurs when the signal detection is logically false on the receive side of the fiber transceiver. The KSZ8862M detects a FEF when its FXSD1 input on port 1 is between 1V and 1.8V. When a FEF is detected, the KSZ8862M signals its fiber link partner that a FEF has occurred by sending 84 1’s followed by a zero in the idle period between frames. By default, FEF is enabled. FEF can be disabled through register setting at P1MBCR (bit2) or P1CR4 (bit12). 100BASE-SX Operation 100BASE-SX operation is supported on port 1 only. It conforms to the TIA/EIA-785 Standard for 100BASE-SX fiber operation. Fiber Link Negotiation Pulse (FLNP) Bursts are used to advertise link capabilities to the link partner during fiber auto-negotiation. FLNP Bursts are equivalent to the Fast Link Pulse (FLP) Bursts used in 10BASE-T and 100BASE-TX auto-negotiation defined by clause 28 of the IEEE802.3 Standard. Refer to respective Standard for details. Physical Interface For 100BASE-SX operation, port 1 interfaces with an external fiber module to drive 850nm fiber optic links up to a maximum distance of 300m. The interface connections between the KSZ8862M and fiber module are single-ended (common mode). 100BASE-SX signal transmission and reception are done on TXM1 (pin 49) and RXM1 (pin 46), respectively. Refer to Micrel reference schematic for recommended interface circuit and termination. Enabling 100BASE-SX Mode To enable 100BASE-SX mode, tie FXSD1 (pin 44) to high (+3.3V) and 100FX/10FL (pin 41)-to-ground. Enabling Fiber Forced Mode In 100BASE-SX mode, the KSZ8862M supports forced mode only. For forced mode, port 1 has auto-negotiation disabled, is forced to 100Mbps for the speed, and is set to either half or full duplex. Optionally, flow control can be enabled to send out PAUSE frames in full duplex mode. Forced mode and auto-negotiation disabled mode settings for 100BASE-SX fiber use the same registers (P1MBCR, P1CR4). These registers are summarized in the Register Map section. 10BASE-FL Operation 10BASE-FL operation is supported on port 1 only. It conforms to clause 15 and 18 of the IEEE802.3 Standard for 10BASE-FL fiber operation. Fiber Link Negotiation Pulse (FLNP) Bursts are used to advertise link capabilities to the link partner during fiber auto-negotiation. FLNP Bursts are equivalent to the Fast Link Pulse (FLP) Bursts used in 10BASE-T and 100BASE-TX auto-negotiation defined by clause 28 of the IEEE802.3 Standard. Refer to respective Standard for details. Physical Interface For 10BASE-FL operation, port 1 interfaces with an external fiber module to drive 850nm fiber optic links up to a maximum distance of 2km. The interface connections between the KSZ8862M and fiber module are single-ended (common mode). 10BASE-FL signal transmission and reception are done on TXM1 (pin 49) and RXM1 (pin 46), respectively. Refer to Micrel reference schematic for recommended interface circuit and termination. Enabling 10BASE-FL Mode To enable 10BASE-FL mode, tie FXSD1 (pin 44) to high (+3.3V) and 100FX/10FL (pin 41)-to-ground. Enabling Fiber Forced Mode In 10BASE-FL mode, the KSZ8862M supports forced mode only. For forced mode, port 1 has auto-negotiation disabled, is forced to 10Mbps for the speed, and is set to either half or full duplex. Optionally, flow control can be enabled to send out PAUSE frames in full duplex mode. August 2010 24 M9999-081310-3.1
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Forced mode and auto-negotiation disabled mode settings for 10BASE-FL fiber use the same registers (P1MBCR, P1CR4). These registers are summarized in the Register Map section. 10BASE-T Transmit The 10BASE-T driver (port 2 only) is incorporated with the 100BASE-TX driver to allow for transmission using the same magnetic. They are internally wave-shaped and pre-emphasized into outputs with typically 2.3V amplitude. The harmonic contents are at least 27dB below the fundamental frequency when driven by an all-ones Manchester-encoded signal. 10BASE-T Receive On the receive side (port 2 only), input buffers and level detecting squelch circuits are employed. A differential input receiver circuit and a phase-locked loop (PLL) perform the decoding function. The Manchester-encoded data stream is separated into clock signal and NRZ data. A squelch circuit rejects signals with levels less than 400mV or with short pulse widths to prevent noise at the RXP-or-RXM input from falsely triggering the decoder. When the input exceeds the squelch limit, the PLL locks onto the incoming signal and the KSZ8862M decodes a data frame. The receiver clock is maintained active during idle periods in between data reception. LED Driver The device provides a current mode fiber LED driver (port 1 only). The edge-enhanced current mode does not require any output wave shaping. The drive current of the LED driver can be programmed through ATCR0 [7:6] register in Bank 44. Post Amplifier The chip also includes a post amplifier (port 1 only). The post amplifier is intended for interfacing the output of the preamplifier of the PIN diode module. The minimum sensitivity of the amplifier is 2.5 mV (rms) for 10Base-FL receive on pin RXM1 or 16mV (rms) for 100Base-SX receive on pin RXM1. Power Management The KSZ8862M features per port power-down mode. To save power, the user can power-down the port that is not in use by setting bit 11 in either P1CR4 or P1MBCR register for port 1 and setting bit 11 in either P2CR4 or P2MBCR register for port 2. To bring the port back up, reset bit 11 in these registers. In addition, there is a full switch power-down mode. This mode shuts the entire switch down, when the PWRDN (pin 36) is pulled down to low. MDI/MDI-X Auto Crossover To eliminate the need for crossover cables between similar devices, the KSZ8862M supports HP-Auto MDI/MDI-X and IEEE 802.3u standard MDI/MDI-X auto crossover on port 2. HP-Auto MDI/MDI-X is the default. The auto-sense function detects remote transmit and receive pairs and correctly assigns the transmit and receive pairs for the KSZ8862M device. This feature is extremely useful when end users are unaware of cable types in addition to saving on an additional uplink configuration connection. The auto-crossover feature can be disabled through the port control registers. The IEEE 802.3u standard MDI and MDI-X definitions are:
MDI RJ45 Pins 1 2 3 6 Signals TD+ TDRD+ RDMDI-X RJ45 Pins 1 2 3 6 Signals RD+ RDTD+ TD-
Table 1. MDI/MDI-X Pin Definitions
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Straight Cable A straight cable connects an MDI device to an MDI-X device or an MDI-X device to an MDI device. The following diagram shows a typical straight cable connection between a network interface card (NIC) (MDI) and a switch, or hub (MDI-X).
Figure 4. Typical Straight Cable Connection
Crossover Cable A crossover cable connects an MDI device to another MDI device, or an MDI-X device to another MDI-X device. The following diagram shows a typical crossover cable connection between two switches or hubs (two MDI-X devices).
10/ 100 Ether net Media Dep en dent Int erface 10/100 Ethernet Media Dependent Interface
1 Receiv e Pair 2 3 4 Tr ansmit Pa ir 5 6 7 8
Crossover Cable
1 R eceive Pair 2 3 4 Transmit Pair 5 6 7 8
Modula r Connector ( RJ-45) HUB (Repeat er or Sw it ch)
Modular Connector (RJ-45) HUB (Repeater or Switch)
Figure 5. Typical Crossover Cable Connection
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Auto Negotiation The KSZ8862M conforms to the auto negotiation protocol as described by the 802.3 committee to allow the channel to operate at 10Base-T or 100Base-TX on port 2 only. Auto negotiation allows unshielded twisted pair (UTP) link partners to select the best common mode of operation. In auto negotiation, the link partners advertise capabilities across the link to each other. If auto negotiation is not supported or the link partner to the KSZ8862M is forced to bypass auto negotiation, the mode is set by observing the signal at the receiver. This is known as parallel mode because while the transmitter is sending auto negotiation advertisements, the receiver is listening for advertisements or a fixed signal protocol. The link setup is shown in the following flow diagram (Figure 6).
Start Auto Negotiation
Force Link Setting
NO
Parallel Operation
YES
Bypass Auto Negotiation and Set Link Mode
Attempt Auto Negotiation
Listen for 100BASE-TX Idles
Listen for 10BASE-T Link Pulses
Join Flow
NO Link Mode Set ?
YES
Link Mode Set
Figure 6. Auto Negotiation and Parallel Operation
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®
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LinkMD Cable Diagnostics ® The KSZ8862M LinkMD uses Time Domain Reflectometry (TDR) to analyze the port 2 cabling plant for common cabling problems such as open circuits, short circuits, and impedance mismatches. ® LinkMD works by sending a pulse of known amplitude and duration down the MDI and MDI-X pairs and then analyzes the shape of the reflected signal. Timing the pulse duration gives an indication of the distance to the cabling fault with a maximum distance of 200m and an accuracy of +/–2m. Internal circuitry displays the TDR information in a user-readable digital format in register P2VCT [8:0]. Note: cable diagnostics are only valid for copper connection (port 2) –fiber-optic operation is not supported. Access ® ® LinkMD is initiated by accessing register P2VCT, the LinkMD Control/Status register, in conjunction with register P2CR4, the 100BASE-TX PHY Controller register. Usage ® LinkMD can be run at any time by making sure Auto MDIX has been disabled. To disable Auto-MDIX, write a ‘1’ to ® P2CR4 [10] for port 2 to enable manual control over the pair used to transmit the LinkMD pulse. The self-clearing cable diagnostic test enable bit P2VCT [15] for port 2, is set to ‘1’ to start the test on this pair. When bit P2VCT [15] returns to ‘0’, the test is complete. The test result is returned in bits P2VCT [14:13] and the distance is returned in bits P2VCT [8:0]. The cable diagnostic test results are as follows: 00 = Valid test, normal condition 01 = Valid test, open circuit in cable 10 = Valid test, short circuit in cable ® 11 = Invalid test, LinkMD failed If P2VCT [14:13] =11, this indicates an invalid test, and occurs when the KSZ8862M is unable to shut down the link partner. In this instance, the test is not run, as it is not possible for the KSZ8862M to determine if the detected signal is a reflection of the signal generated or a signal from another source. Cable distance can be approximated by the following formula: P2VCT [8:0] X 0.4m for port 2 cable distance This constant may be calibrated for different cabling conditions, including cables with a velocity of propagation that varies significantly from the norm.
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Functional Overview: MAC and Switch
Address Lookup The internal lookup table stores MAC addresses and their associated information. It contains a 1K entry unicast address learning table plus switching information. The KSZ8862M is guaranteed to learn 1K addresses and distinguishes itself from hash-based look-up tables, which depending upon the operating environment and probabilities, may not guarantee the absolute number of addresses it can learn. Learning The internal lookup engine updates its table with a new entry if the following conditions are met: 1. The received packet's Source Address (SA) does not exist in the lookup table. 2. The received packet is good without receiving errors; the packet size is legal length. The lookup engine inserts the qualified SA into the table, along with the port number and time stamp. If the table is full, then the last entry of the table is deleted to make room for the new entry. Migration The internal look-up engine also monitors whether a station has moved. If a station has moved, it updates the table accordingly. Migration happens when the following conditions are met: 1. The received packet's SA is in the table but the associated source port information is different. 2. The received packet is good without receiving errors; the packet size is legal length. The lookup engine updates the existing record in the table with the new source port information. Aging The look-up engine updates the time stamp information of a record whenever the corresponding SA appears. The time stamp is used in the aging process. If a record is not updated for a period of time, the look-up engine removes the record from the table. The look-up engine constantly performs the aging process and continuously removes aging records. The aging period is about 200 seconds. This feature can be enabled or disabled through Global Register SGCR1 [10].
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Forwarding The KSZ8862M forwards packets using the algorithm that is depicted in the following flowcharts. Figure 7 shows stage one of the forwarding algorithm where the search engine looks up the VLAN ID, static table, and dynamic table for the destination address, and comes up with “port to forward 1” (PTF1). PTF1 is then further modified by spanning tree, IGMP snooping, port mirroring, and port VLAN processes to come up with “port to forward 2” (PTF2), as shown in Figure 8. The packet is sent to PTF2.
Start
PTF1 = NULL
NO
VLAN ID valid?
- Search VLAN table - Ingress VLAN filtering - Discard NPVID check
YES
Search complete. Get PTF1 from Static MAC Table
FOUND
Search Static Table
This search is based on DA or DA+FID
NOT FOUND
Search complete. Get PTF1 from Dynamic MAC Table
FOUND
Dynamic Table Search
This search is based on DA+FID
NOT FOUND
Search complete. Get PTF1 from VLAN table
PTF1
Figure 7. Destination Address Lookup Flow Chart in Stage One
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PTF1
Spanning Tree Process
- Check receiving port's receive enable bit - Check destination port's transmit enable bit - Check whether packets are special (BPDU) or s pecified
- Applied to MAC #1 and MAC #2 IGMP Process - IGMP will be forwarded to the host port
Port Mirror Process
- RX Mirror - TX Mirror - RX or TX Mirror - RX and TX Mirror
Port VLAN Membership Check
PTF2
Figure 8. Destination Address Resolution Flow Chart in Stage Two
The KSZ8862M will not forward the following packets: 1. Error packets. These include framing errors, Frame Check Sequence (FCS) errors, alignment errors, and illegal size packet errors. 2. 802.3x pause frames. The KSZ8862M intercepts these packets and performs the flow control. 3. "Local" packets. Based on destination address (DA) look-up. If the destination port from the lookup table matches the port from which the packet originated, the packet is defined as "local."
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Switching Engine The KSZ8862M features a high-performance switching engine to move data to and from the MAC’s packet buffers. It operates in store and forward mode, while the efficient switching mechanism reduces overall latency. The switching engine has a 32KB internal frame buffer. This resource is shared between all the ports. There are a total of 256 buffers available. Each buffer is sized at 128B. M AC Operation The KSZ8862M strictly abides by IEEE 802.3 standards to maximize compatibility. Additionally, there is an added MAC filtering function to filter Unicast packets. The MAC filtering function is useful in applications such as VoIP where restricting certain packets reduces congestion and thus improves performance. Inter Packet Gap (IPG) If a frame is successfully transmitted, the minimum 96-bit time for IPG is measured between two consecutive packets. If the current packet is experiencing collisions, then the minimum 96-bit time for IPG is measured from carrier sense (CRS) to the next transmit packet. Back-Off Algorithm The KSZ8862M implements the IEEE standard 802.3 binary exponential back-off algorithm in half-duplex mode, and optional "aggressive mode" back-off. After 16 collisions, the packet is optionally dropped depending upon the switch configuration in SGCR1 [8]. Late Collision If a transmit packet experiences collisions after 512 bit times of the transmission, then the packet is dropped. Legal Packet Size The KSZ8862M discards packets less than 64 bytes and can be programmed to accept packet size up to 1536 bytes in SGCR2 [1]. The KSZ8862M can also be programmed for special applications to accept packet size up to 1916 bytes in SGCR2 [2]. Flow Control The KSZ8862M supports standard 802.3x flow control frames on both transmit and receive sides. On the receive side, if the KSZ8862M receives a pause control frame, the KSZ8862M will not transmit the next normal frame until the timer, specified in the pause control frame, expires. If another pause frame is received before the current timer expires, the timer will be updated with the new value in the second pause frame. During this period (while it is flow controlled), only flow control packets from the KSZ8862M are transmitted. On the transmit side, the KSZ8862M has intelligent and efficient ways to determine when to invoke flow control. The flow control is based on availability of the system resources, including available buffers, available transmit queues, and available receive queues. The KSZ8862M will flow control a port that has just received a packet if the destination port resource is busy. The KSZ8862M issues a flow control frame (Xoff), containing the maximum pause time as defined in IEEE standard 802.3x. Once the resource is freed up, the KSZ8862M then sends out the other flow control frame (Xon) with zero pause time to turn off the flow control (turn on transmission to the port). A hysteresis feature is provided to prevent the flow control mechanism from being constantly activated and deactivated. The KSZ8862M flow controls all ports if the receive queue becomes full. Half-Duplex Backpressure A half-duplex backpressure option (not in IEEE 802.3 standards) is also provided. The activation and deactivation conditions are the same in full-duplex mode. If backpressure is required, then the KSZ8862M sends preambles to defer the other stations' transmission (carrier sense deference).
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To avoid jabber and excessive deference (as defined in the 802.3 standard), after a certain time, the KSZ8862M discontinues the carrier sense and then raises it again quickly. This short silent time (no carrier sense) prevents other stations from sending out packets thus keeping other stations in a carrier sense deferred state. If the port has packets to send during a backpressure situation, then the carrier sense type backpressure is interrupted and those packets are transmitted instead. If there are no additional packets to send, then the carrier sense type backpressure is reactivated again until switch resources free up. If a collision occurs, then the binary exponential back-off algorithm is skipped and carrier sense is generated immediately, thus reducing the chance of further collisions and carrier sense is maintained to prevent packet reception. To ensure no packet loss in 10 BASE-T or 100 BASE-TX half-duplex modes, the user must enable the following: 1. Aggressive back off (bit 8 in SGCR1) 2. No excessive collision drop (bit 3 in SGCR2) Note: These bits are not set in default, since this is not the IEEE standard. Broadcast Storm Protection The KSZ8862M has an intelligent option to protect the switch system from receiving too many broadcast packets. As the broadcast packets are forwarded to all ports except the source port, an excessive number of switch resources (bandwidth and available space in transmit queues) may be utilized. The KSZ8862M has the option to include “multicast packets” for storm control. The broadcast storm rate parameters are programmed globally, and can be enabled or disabled on a per port basis in P1CR1 [7] and P2CR1 [7]. The rate is based on a 67ms interval for 100BT and a 670ms interval for 10BT. At the beginning of each interval, the counter is cleared to zero and the rate limit mechanism starts to count the number of bytes during the interval. The rate definition is described in SGCR3 [2:0] [15:8]. The default setting is 0x63 (99 decimal). This is equal to a rate of 1%, calculated as follows: 148,800 frames/sec X 67 ms/interval X 1% = 99 frames/interval (approx.) = 0x63 Note: 148,800 frames/sec is based on 64-byte block of packets in 100BASE-T with 12 bytes of IPG and 8 bytes of preamble between two packets. Clock Generator The X1 and X2 pins are connected to a 25 MHz crystal. X1 can also serve as the connector to a 3.3V, 25 MHz oscillator (as described in the pin description). The bus interface unit (BIU) uses BCLK (Bus Clock) for synchronous accesses. The maximum host port frequency is 50 MHz for VLBus-like and burst mode (32-bit interface only).
Bus Interface Unit (BIU)
The host interface of the BIU is designed to communicate with embedded processors. The host interface of the KSZ8862M is a generic bus interface. Some glue logic may be required when the interface talks to various buses and processors. In terms of transfer type, the BIU can support two transfers: asynchronous transfer and synchronous transfer. To support these transfers (asynchronous and synchronous), the BIU provides three groups of signals: 1. Synchronous signals 2. Asynchronous signals 3. Common signals used for both synchronous and asynchronous transfers. Since both synchronous and asynchronous signals are independent of each other, synchronous burst transfer and asynchronous transfer can be mixed or interleaved but cannot be overlapped (due to the sharing of the common signals). In terms of physical data bus size, the KSZ8862M supports 8, 16, and 32 bit host/industrial standard data bus sizes. Given a physical data bus size, the KSZ8862M supports 8, 16, or 32-bit data transfers depending upon the size of the physical data bus. For example, for a 32-bit system/host data bus, it allows 8, 16, and 32-bit data transfers (KSZ886232MQL); for a 16-bit system/host data bus, it allows 8 and 16-bit data transfers (KSZ8862-16MQL); and for 8-bit system/host data bus, it only allows 8-bit data transfers (KSZ8862-16MQL). Note that KSZ8862M does not support internal data byte-swap but it does support internal data word-swap. This means that the system/host data bus HD [7:0] has to connect to both D [7:0] and D [15:8] for 8-bit data bus interfaces. However, the system/host data bus HD [15:8] and HD [7:0] just connects to D [15:8] and D [7:0], respectively, for 16-bit data bus interface; there is no need to connect HD [31:24] and HD [23:16] to D [31:24] and D [23:16].
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Signal Common Signals A[15:1] AEN I I Address Type
(1)
KSZ8862-16/32MQL
Function
Address Enable Address Enable asserted indicates memory address on the bus for DMA access and since the device is an I/O device, address decoding is only enabled when AEN is low. Byte Enable BE0N 0 0 1 0 1 1 1 BE1N 0 0 1 1 0 1 1 BE2N 0 1 0 1 1 0 1 BE3N 0 1 0 1 1 1 0 Description 32-bit access (32-bit bus only) Lower 16-bit (D[15:0]) access Higher 16-bit (D[31:16]) access (32bit bus only) Byte 0 (D[7:0]) access Byte 1 (D[15:8]) access Byte 2 (D[23:16]) access (32-bit bus only) Byte 3 (D[31:24]) access (32-bit bus only)
BE3N, BE2N, BE1N, BE0N
I
Note 1: BE3N, BE2N, BE1N and BE0N are ignored when DATACSN is low because 32 bit transfers are assumed. Note 2: BE2N and BE3N are valid only for the KSZ8862-32 mode, and are NC for the KSZ8862-16 mode. D[31:16] D[15:0] ADSN LDEVN I/O I/O I O Data For KSZ8862-32 Mode only Data For both KSZ8862-32 and KSZ8862-16 Modes Address Strobe The rising edge of ADSN is used to latch A[15:1], AEN, BE3N, BE2N, BE1N and BE0N. Local Device This signal is a combinatorial decode of AEN and A[15:4], The A[15:4] is used to compare against the Base Address Register. Data Register Chip Select (For KSZ8862-32 Mode only) This signal is used for central decoding architecture (mostly for embedded application). When asserted, the device’s local decoding logic is ignored and the 32-bit access to QMU Data Register is assumed. Interrupt VLBUSN = 0, VLBus-like cycle. VLBUSN = 1, burst cycle (both host/system and KSZ8862 can insert wait state) For VLBus-like access: used to sample SWR when asserted. For burst access: used to connect to IOWC# bus signal to indicate burst write. Write/Read For VLBus-like access: used to indicate write (High) or read (Low) transfer. For burst access: used to connect to IORC# bus signal to indicate burst read.
DATACSN
I
INTRN VLBUSN CYCLEN SWR
O I I I
Synchronous Transfer Signals
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Signal SRDYN
Type O
(1)
Function Synchronous Ready For VLBus-like access: exactly the same signal definition of nSRDY in VLBus. For burst access: insert wait state by the KSZ8862M whenever necessary during the Data Register access. Ready Return For VLBus-like access: exactly like RDYRTNN signal in VLBus to end the cycle. For burst access: exactly like EXRDY signal in EISA to insert wait states. Note that the wait states are inserted by system logic (memory) not by KSZ8862M. Bus Clock Asynchronous Read Asynchronous Write Asynchronous Ready This signal is asserted (low) to insert wait states. Table 2. Bus Interface Unit Signal Grouping
RDYRTNN
I
BCLK RDN WRN ARDY
I I I O
Asynchronous Transfer Signals
Legend: I = Input. O = Output. I/O = Bi-directional.
Regardless of whether the transfer is synchronous or asynchronous, if the address latch is required, use the rising edge of ADSN to latch the incoming signals A[15:1], AEN, BE3N, BE2N, BE1N, and BE0N. Note: Whether the transfer is synchronous or asynchronous, if the local device decoder is used, LDEVN will be asserted to indicate that the KSZ8862M is successfully targeted. Basically, signal LDEVN is a combinatorial decode of AEN and A[15:4]. Asynchronous Interface For asynchronous transfers, the asynchronous dedicated signals RDN (for read) or WRN (for write) toggle, but the synchronous dedicated signals BCLK, CYCLEN, SWR, and RDYRTNN are de-asserted and stay at the same logic level throughout the entire asynchronous transfer. There is no data burst support for asynchronous transfer. All asynchronous transfers are single-data transfers. The BIU, however, provides flexible asynchronous interfacing to communicate with various applications and architectures. Three major ways of interfacing with the system (host) are. 1. Interfacing with the system/host relying on local device decoding and having stable address throughout the whole transfer: The typical example for this application is ISA-like bus interface using latched address signals as shown in the Figure 16. No additional address latch is required, therefore ADSN should be connected Low. The BIU decodes A[15:4] and qualifies with AEN (Address Enable) to determine if the KSZ8862M switch is the intended target. The host utilizes the rising edge of RDN to latch read data and the BIU will use rising edge of WRN to latch write data. 2. Interfacing with the system/host relying on local device decoding but not having stable address throughout the entire transfer: the typical example for this application is EISA-like bus (non-burst) interface as shown in the Figure 17. This type of interface requires ADSN to latch the address on the rising edge. The BIU decodes latched A[15:4] and qualifies with AEN to determine if the KSZ8862M switch is the intended target. The data transfer is the same as the first case. 3. Interfacing with the system/host relying on central decoding (KSZ8862-32 mode only). The typical example for this application is for an embedded processor having a central decoder on the system board or within the processor. Connecting the chip select (CS) from system/host to DATACSN bypasses the local device decoder. When the DATACSN is asserted, it only allows access to the Data Register in 32 bits and BE3N, BE2N, BE1N, and BE0N are ignored as shown in the Figure 18. No other registers can be accessed by asserting DATACSN. The data transfer is the same as in the first case, independent of the type of asynchronous interface used. To insert a August 2010 35 M9999-081310-3.1
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KSZ8862-16/32MQL
Synchronous Interface For synchronous transfers, the synchronous dedicated signals CYCLEN, SWR, and RDYRTNN will toggle but the asynchronous dedicated signals RDN and WRN are de-asserted and stay at the same logic level throughout the entire synchronous transfer. The synchronous interface mainly supports two applications, one for VLBus-like and the other for EISA-like (DMA type C) burst transfers. The VLBus-like interface supports only single-data transfer. The pin option VLBUSN determines if it is a VLBus-like or EISA-like burst transfer – if VLBUSN = 0, the interface is for VLBus-like transfer; if VLBUSN = 1, the interface is for EISA-like burst transfer. For VLBus-like transfer interface (VLBUSN = 0): This interface is used in an architecture in which the device’s local decoder is utilized; that is, the BIU decodes latched A[15:4] and qualifies with AEN (Address Enable) to determine if the switch is the intended target. No burst is supported in this application. The M/nIO signal connection in VLBus is routed to AEN. The CYCLEN in this application is used to sample the SWR signal when it is asserted. Usually, CYCLEN is one clock delay of ADSN. There is a handshaking process to end the cycle of VLBus-like transfers. When the KSZ8862M is ready to finish the cycle, it asserts SRDYN. The system/host acknowledges SRDYN by asserting RDYRTNN after the system/host has latched the read data. The KSZ8862M holds the read data until RDYRTNN is asserted. The timing waveform is shown in Figure 22 and Figure 23. For EISA-like burst transfer interface (VLBUSN = 1): The SWR is connected to IORC# in EISA to indicate the burst read and CYCLEN is connected to IOWC# in EISA to indicate the burst write. Note that in this application, both the system/host/memory and KSZ8862M are capable of inserting wait states. For system/host/memory to insert a wait state, assert the RDYRTNN signal; for the KSZ8862M to insert the wait state, assert the SRDYN signal. The timing waveform is shown in Figure 20 and Figure 21. Summary Figure 9 shows the mapping from ISA-like, EISA-like and VLBus-like transactions to the switch’s BIU. Figure 10 shows the connection for different data bus sizes. Note: For the 8-bit data bus mode, the internal inverter is enabled and connected between BE0N and BE1N, so even address will enable the BE0N and odd address will enable the BE1N.
KSZ8862M BIU
ISA
Host Logic
No Addr Latch (ADSN = 0) Address Latch Central decode
Local decode
Non-burst EISA
Host Logic
Asynchronous Interface
Burst
Host Logic
Central decode (VLBUSN = 1) Local decode (VLBUSN = 0)
Synchronous Interface
VLBus
Host Logic
Address Latch
Note: To use DATACSN & 32-bit only for Central decode
Figure 9. Mapping from ISA-like, EISA-like, and VLBus-like transactions to the KSZ8862M Bus
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KSZ8862-16
HA[1] HA[15:2] HD[7:0] HD[15:8] A[1] A[15:2] D[7:0] D[15:8] GND HA[15:2] HD[7:0] HD[15:8] HD[23:16] HD[31:24] HA[0] VDD BE0N BE1N HA[0] nSBHE BE0N BE1N nHBE[0] nHBE[1] nHBE[2] nHBE[3]
KSZ8862-16/32MQL
KSZ8862-16
HA[1] HA[15:2] HD[7:0] A[1] A[15:2] D[7:0] D[15:8]
KSZ8862-32
A[1] A[15:2] D[7:0] D[15:8] D[23:16] D[31:24] BE0N BE1N BE2N BE3N
8-bit Data Bus
16-bit Data Bus (for example: ISA-like)
32-bit Data Bus (for example: EISA-like)
Figure 10. KSZ8862M 8-Bit, 16-Bit, and 32-Bit Data Bus Connections
BIU Implementation Principles Since the KSZ8862M is an I/O device with 16 addressable locations, address decoding is based on the values of A15-A4 and AEN. Whenever DATACSN is asserted, the address decoder is disabled and a 32-bit transfer to Data Register is assumed (BE3N – BE0N are ignored). If address latching is required, the address is latched on the rising edge of ADSN and is transparent when ADSN=0. 1. Byte, word, and double-word data buses and accesses (transfers) are supported. 2. Internal byte swapping is not implemented and word swapping is supported internally. Refer to Figure 12 for the appropriate 8-bit, 16-bit, and 32-bit data bus connection. 3. Since independent sets of synchronous and asynchronous signals are provided, synchronous and asynchronous cycles can be mixed or interleaved as long as they are not active simultaneously. 4. The asynchronous interface uses RDN and WRN signal strobes for data latching. If necessary, ARDY is deasserted on the leading edge of the strobe. 5. The VLBUS-like synchronous interface uses BCLK, ADSN, and SWR and CYCLEN to control read and write operations and generate SRDYN to insert the wait state, if necessary, when VLBUSN = 0. For read, the data must be held until RDYRTNN is asserted. 6. The EISA-like burst transfer is supported using synchronous interface signals and DATACSN when I/O signal VLBUSN = 1. Both the system/host/memory and KSZ8862M are capable of inserting wait states. To set the system/host/memory to insert a wait state, assert RDYRTNN signal. To set the KSZ8862M to insert a wait state, assert SRDYN signal.
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Queue Management Unit (QMU)
The Queue Management Unit (QMU) manages packet traffic between the MAC/PHY interface and the system host. It has built-in packet memory for receive and transmit functions called TXQ (Transmit Queue) and RXQ (Receive Queue). Each queue contains 4KB of memory for back-to-back, non-blocking frame transfer performance. It provides a group of control registers for system control, frame status registers for current packet transmit/receive status, and interrupts to inform the host of the real time TX/RX status. Transmit Queue (TXQ) Frame Format The frame format for the transmit queue is shown in the following Table 3. The first word contains the control information for the frame to transmit. The second word is used to specify the total number of bytes of the frame. The packet data follows. The packet data area holds the frame itself. It may or may not include the CRC checksum depending on whether hardware CRC checksum generation is enabled. Multiple frames can be pipelined in both the transmit queue and receive queue as long as there is enough queue memory, thus avoiding overrun. For each transmitted frame, the transmit status information for the frame is located in the TXSR register.
Packet Memory Address Offset 0 2 4 - up Bit 15 nd 2 Byte Control Word Byte Count Packet Data (maximum size is 1916) Table 3. Transmit Queue Frame Format Bit 0 st 1 Byte
Since multiple packets can be pipelined into the TX packet memory for transmit, the transmit status reflects the status of the packet that is currently being transferred on the MAC interface (which may or may not be the last queued packet in the TX queue). The transmit control word is the first 16-bit word in the TX packet memory, followed by a 16-bit byte count. It must be word aligned. Each control word corresponds to one TX packet. Table 4 gives the transmit control word bit fields.
Bit 15
Description TXIC Transmit Interrupt on Completion When bit is set, the KSZ8862M sets the transmit interrupt after the present frame has been transmitted. Reserved TXDPN Transmit Destination Port Number When bit is set, this field indicates the destination port(s) where the packet is forwarded from host system. Set bit 8 to indicate that port 1 is the destination port. Set bit 9 to indicate that port 2 is the destination port. Setting all ports to 1 causes the switch engine to broadcast the packet to both ports. Setting all bits to 0 has no effect. The internal switch engine forwards the packets according to the switching algorithm in its MAC lookup table. Reserved TXFID Transmit Frame ID This field specifies the frame ID that is used to identify the frame and its associated status information in the transmit status register TXSR[5:0]. Table 4. Transmit Control Word Bit Fields
14-10 9-8
7-6 5-0
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The transmit Byte Count specifies the total number of bytes to be transmitted from the TXQ. Its format is given in Table 5.
Bit 15-11 10-0 Description Reserved TXBC Transmit Byte Count Transmit Byte Count. Hardware uses the byte count information to conserve the TX buffer memory for better utilization of the packet memory. Note: The hardware behavior is unknown if an incorrect byte count information is written to this field. Writing a 0 value to this field is not permitted. Table 5. Transmit Byte Count Format
The data area contains six bytes of Destination Address (DA) followed by six bytes of Source Address (SA), followed by a variable-length number of bytes. On transmit, all bytes are provided by the CPU, including the source address. The KSZ8862M does not insert its own source address. The 802.3 Frame Length word (Frame Type in Ethernet) is not interpreted by the KSZ8862M. It is treated transparently as data for transmit operations. Receive Queue (RXQ) Frame Format The frame format for the receive queue is shown in Table 6. The first word contains the status information for the frame received. The second word is the total number of bytes of the RX frame. Following that is the packet data area. The packet data area holds the frame itself. It may or may not include the CRC checksum depending on whether hardware CRC stripping is enabled.
Packet Memory Address Offset 0 2 4 - up Bit 15 nd 2 Byte Status Word Byte Count Packet Data (maximum size is 1916) Table 6. Receive Queue Frame Format Bit 0 st 1 Byte
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For receive, the packet receive status always reflects the receive status of the packet received in the current RX packet memory (see Table 7). The RXSR register indicates the status of the current received frame.
Bit 15 Description RXFV Receive Frame Valid When bit is set, indicates that the present frame in the receive packet memory is valid and received from MAC/PHY. The status information currently in this location is also valid. When bit is reset, indicates that there is either no pending receive frame or current frame is still in the process of receiving and has not completed yet. Reserved RXSPN Receive Source Port Number When bit is set, this field indicates the source port where the packet was received. (Setting bit 9 = 0 and bit 8 = 1 indicates the packet was received from port 1. Setting bit 9 = 1 and bit 8 = 0 indicates that the packet was received from port 2. Valid port is either port 1 or port 2. RXBF Receive Broadcast Frame When bit is set, indicates that this frame has a broadcast address. RXMF Receive Multicast Frame When bit is set, it indicates that this frame has a multicast address (including the broadcast address). RXUF Receive Unicast Frame When bit is set, indicates that this frame has a unicast address. Reserved RXFT Receive Frame Type When bit is set, indicates that the frame is an Ethernet-type frame (frame length is greater than 1500 bytes). When clear, indicate that the frame is an IEEE 802.3 frame. This bit is not valid for runt frames. RXTL Receive Frame Too Long When bit is set, indicates that the frame length exceeds the maximum size of 1518 bytes. Frames too long are passed to the host only if the pass bad frame bit is set. Note: Frame too long is only a frame length indication and does not cause any frame truncation. RXRF Receive Runt Frame When bit is set, indicates that a frame was damaged by a collision or premature termination before the collision window has passed. Runt frames are passed to the host only if the pass bad frame bit is set. RXCE Receive CRC Error When bit is set, indicates that a CRC error has occurred on the current received frame. CRC error frame are passed to the host only if the pass bad frame bit is set. Table 7. FRXQ Packet Receive Status
14-10 9-8
7 6
5 4 3
2
1
0
Table 8 gives the format of the RX byte count field.
Bit 15-11 10-0 Description Reserved RXBC Receive Byte Count Receive Byte Count. Table 8. FRXQ RX Byte Count Field
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Advanced Switch Functions
Spanning Tree Support To support spanning tree, the host port is the designated port for the processor. The other ports can be configured in one of the five spanning tree states via “transmit enable”, “receive enable” and “learning disable” register settings in registers P1CR2 and P2CR2 for ports 1 and 2, respectively. Table 9 shows the port setting and software actions taken for each of the five spanning tree states.
Disable State The port should not forward or receive any packets. Learning is disabled. Blocking State Port Setting Software Action The processor should not send any packets to the port. The switch may still send specific packets to the processor (packets that match some entries in the “static MAC table” with “overriding bit” set) and the processor should discard those packets. Address learning is disabled on the port in this state. Software Action The processor should not send any packets to the port(s) in this state. The processor should program the “Static MAC table” with the entries that it needs to receive (for example, BPDU packets). The “overriding” bit should also be set so that the switch will forward those specific packets to the processor. Address learning is disabled on the port in this state. Software Action The processor should program the “Static MAC table” with the entries that it needs to receive (for example, BPDU packets). The “overriding” bit should be set so that the switch will forward those specific packets to the processor. The processor may send packets to the port(s) in this state. Address learning is disabled on the port in this state. Software Action The processor should program the “Static MAC table” with the entries that it needs to receive (for example, BPDU packets). The “overriding” bit should be set so that the switch will forward those specific packets to the processor. The processor may send packets to the port(s) in this state. Address learning is enabled on the port in this state. Software Action The processor programs the “Static MAC table” with the entries that it needs to receive (for example, BPDU packets). The “overriding” bit is set so that the switch forwards those specific packets to the processor. The processor can send packets to the port(s) in this state. Address learning is enabled on the port in this state. Table 9. Spanning Tree States
“transmit enable = 0, receive enable = 0, learning disable =1”
Port Setting
Only packets to the processor are forwarded.
“transmit enable = 0, receive enable = 0, learning disable =1”
Port Setting
Listening State Only packets to and from the processor are forwarded. Learning is disabled. Learning State Only packets to and from the processor are forwarded. Learning is enabled. Forwarding State Packets are forwarded and received normally. Learning is enabled.
“transmit enable = 0, receive enable = 0, learning disable =1”
Port Setting
“transmit enable = 0, receive enable = 0, learning disable = 0”
Port Setting “transmit enable = 1, receive enable = 1, learning disable = 0”
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IGMP Support For Internet Group Management Protocol (IGMP) support in Layer 2, the KSZ8862M provides two components: “IGMP” Snooping The KSZ8862M traps IGMP packets and forwards them only to the processor (host port). The IGMP packets are identified as IP packets (either Ethernet IP packets, or IEEE 802.3 SNAP IP packets) with IP version = 0x4 and protocol version number = 0x2. “Multicast Address Insertion” in the Static MAC Table Once the multicast address is programmed in the Static MAC Table, the multicast session is trimmed to the subscribed ports, instead of broadcasting to all ports. IPv6 MLD Snooping The KSZ8862M traps IPv6 Multicast Listener Discovery (MLD) packets and forwards them only to the processor (host port). MLD snooping is controlled by SGCR2 [13] (MLD snooping enable) and SGCR2 [12] (MLD option). Setting SGCR2 [13] causes the KSZ8862M to trap packets that meet all of the following conditions: • • • • IPv6 multicast packets Hop count limit = 1 IPv6 next header = 1 or 58 (or = 0 with hop-by-hop next header = 1 or 58) If SGCR2[12] = 1, IPv6 next header = 43, 44, 50, 51, or 60 (or =0 with hop-by-hop next header = 43, 44, 50, 51, or 60)
Port Mirroring Support KSZ8862M supports “Port Mirroring” comprehensively as: “Receive only” mirror on a port All the packets received on the port are mirrored on the sniffer port. For example, port 1 is programmed to be “receive sniff” and the host port is programmed to be the “sniffer port”. A packet received on port 1 is destined to port 2 after the internal lookup. The KSZ8862M forwards the packet to both port 2 and the host port. The KSZ8862M can optionally even forward “bad” received packets to the “sniffer port”. “Transmit only” mirror on a port All the packets transmitted on the port are mirrored on the sniffer port. For example, port 1 is programmed to be “transmit sniff” and the host port is programmed to be the “sniffer port”. A packet received on port 2 is destined to port 1 after the internal lookup. The KSZ8862M forwards the packet to both port 1 and the host port. “Receive and transmit” mirror on two ports All the packets received on port A and transmitted on port B are mirrored on the sniffer port. To turn on the “AND” feature, set register SGCR2, bit 8 to “1”. For example, port 1 is programmed to be “receive sniff”, port 2 is programmed to be “transmit sniff”, and the host port is programmed to be the “sniffer port”. A packet received on port 1 is destined to port 2 after the internal lookup. The KSZ8862M forwards the packet to both port 2 and the host port. Multiple ports can be selected as “receive sniff” or “transmit sniff”. In addition, any port can be selected as the “sniffer port”. All these per port features can be selected through registers P1CR2, P2CR2, and P3CR2 for ports 1, 2, and the host port, respectively.
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IEEE 802.1Q VLAN Support The KSZ8862M supports 16 active VLANs out of the 4096 possible VLANs specified in the IEEE 802.1Q specification. KSZ8862M provides a 16-entry VLAN table, which converts the 12-bits VLAN ID (VID) to the 4-bits Filter ID (FID) for address lookup. If a non-tagged or null-VID-tagged packet is received, the ingress port default VID is used for lookup. In VLAN mode, the lookup process starts with VLAN table lookup to determine whether the VID is valid. If the VID is not valid, the packet is dropped and its address is not learned. If the VID is valid, the FID is retrieved for further lookup. The FID + Destination Address (FID+DA) are used to determine the destination port. The FID + Source Address (FID+SA) are used for address learning. (See Tables 10 and 11.)
DA found in Static MAC Table? No No Yes Yes Yes Yes
Use FID flag? Don’t care Don’t care 0 1 1 1
FID match? Don’t care Don’t care Don’t care No No Yes
DA+FID found in Dynamic MAC Table? No Yes Don’t care No Yes Don’t care
Action Broadcast to the membership ports defined in the VLAN Table bits [18:16] Send to the destination port defined in the Dynamic MAC Address Table bits [53:52] Send to the destination port(s) defined in the Static MAC Address Table bits [50:48] Broadcast to the membership ports defined in the VLAN Table bits [18:16] Send to the destination port defined in the Dynamic MAC Address Table bits [53:52] Send to the destination port(s) defined in the Static MAC Address Table bits [50:48]
Table 10. FID+DA Lookup in VLAN Mode FID+SA found in Dynamic MAC Table? No Yes Action Learn and add FID+SA to the Dynamic MAC Address Table Update time stamp Table 11. FID+SA Lookup in VLAN Mode
QoS Priority Support The KSZ8862M provides Quality of Service (QoS) for applications such as VoIP and video conferencing. Offering four priority queues per port, the per-port transmit queue can be split into four priority queues: Queue 3 is the highest priority queue and Queue 0 is the lowest priority queue. Bit 0 of registers P1CR1, P2CR1, and P3CR1 is used to enable split transmit queues for ports 1, 2, and the host port, respectively. Port-Based Priority W ith port-based priority, each ingress port is individually classified as a high-priority receiving port. All packets received at the high-priority receiving port are marked as high priority and are sent to the high-priority transmit queue if the corresponding transmit queue is split. Bit 4 and 3 of registers P1CR1, P2CR1, and P3CR1 is used to enable port-based priority for ports 1, 2, and the host port, respectively. 802.1p-Based Priority For 802.1p-based priority, the KSZ8862M examines the ingress (incoming) packets to determine whether they are tagged. If tagged, the 3-bit priority field in the VLAN tag is retrieved and compared against the “priority mapping” value, as specified by the register SGCR6. The “priority mapping” value is programmable.
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�Micrel, Inc. Figure 11 illustrates how the 802.1p priority field is embedded in the 802.1Q VLAN tag.
KSZ8862-16/32MQL
Bytes
7 Preamble
1 SFD
6 DA
6 SA
2 VPID
2 TCI
2 length
46-1500 Data
4 FCS
Bits 802.1q VLAN Tag
16 Tagged Packet Type (8100 for Ethernet)
3 802.1p
1 CFI
12 VLAN ID
Figure 11. 802.1p Priority Field Format
802.1p-based priority is enabled by bit 5 of registers P1CR1, P2CR1, and P3CR1 for ports 1, 2, and the host port, respectively. The KSZ8862M provides the option to insert or remove the priority tagged frame's header at each individual egress port. This header, consisting of the 2 bytes VLAN protocol ID (VPID) and the 2 bytes tag control information field (TCI), is also referred to as the 802.1Q VLAN tag. Tag insertion is enabled by bit 2 of registers P1CR1, P2CR1, and P3CR1 for ports 1, 2, and the host port, respectively. At the egress port, untagged packets are tagged with the ingress port’s default tag. The default tags are programmed in register sets P1VIDCR, P2VIDCR, and P3VIDCR for ports 1, 2 and the host port, respectively. The KSZ8862M does not add tags to already tagged packets. Tag removal is enabled by bit 1 of registers P1CR1, P2CR1, and P3CR1 for ports 1, 2, and the host port, respectively. At the egress port, tagged packets will have their 802.1Q VLAN Tags removed. The KSZ8862M will not modify untagged packets. The CRC is recalculated for both tag insertion and tag removal. 802.1p priority field re-mapping is a QoS feature that allows the KSZ8862M to set the “User Priority Ceiling” at any ingress port. If the ingress packet’s priority field has a higher priority value than the default tag’s priority field of the ingress port, the packet’s priority field is replaced with the default tag’s priority field. The “User Priority Ceiling” is enabled by bit 3 of registers P1CR2, P2CR2, and P3CR2 for ports 1, 2, and the host port, respectively. DiffServ-Based Priority DiffServ-based priority uses the ToS registers shown in the Priority Control Registers section. The ToS priority control registers implement a fully decoded, 128-bit Differentiated Services Code Point (DSCP) register to determine packet priority from the 6-bit ToS field in the IP header. When the most significant 6 bits of the ToS field are fully decoded, the resultant of the 64 possibilities is compared with the corresponding bits in the DSCP register to determine priority. Rate Limiting Support The KSZ8862M supports hardware rate limiting from 64 Kbps to 88 Mbps, independently on the “receive side” and on the “transmit side” on a per port basis. For 10-base T, a rate setting above 10 Mbps means the rate is not limited. On the receive side, the data receive rate for each priority at each port can be limited by setting up Ingress Rate Control Registers. On the transmit side, the data transmit rate for each priority queue at each port can be limited by setting up Egress Rate Control Registers. The size of each frame has options to include minimum IFG (Inter Frame Gap) or August 2010 44 M9999-081310-3.1
�Micrel, Inc. Preamble byte, in addition to the data field (from packet DA to FCS).
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For ingress rate limiting, KSZ8862M provides options to selectively choose frames from all types, multicast, broadcast, and flooded unicast frames. The KSZ8862M counts the data rate from those selected type of frames. Packets are dropped at the ingress port when the data rate exceeds the specified rate limit. For egress rate limiting, the Leaky Bucket algorithm is applied to each output priority queue for shaping output traffic. Inter frame gap is stretched on a per frame base to generate smooth, non-burst egress traffic. The throughput of each output priority queue is limited by the egress rate specified. If any egress queue receives more traffic than the specified egress rate throughput, packets may be accumulated in the output queue and packet memory. After the memory of the queue or the port is used up, packet dropping or flow control will be triggered. As a result of congestion, the actual egress rate may be dominated by flow control/dropping at the ingress end, and may be therefore slightly less than the specified egress rate. To reduce congestion, it is good practice to make sure the egress bandwidth exceeds the ingress bandwidth. M AC Filtering Function Use the static table to assign a dedicated MAC address to a specific port. When a unicast MAC address is not recorded in the static table, it is also not learned in the dynamic MAC table. The KSZ8862M includes an option that can filter or forward unicast packets for an unknown MAC address. This option is enabled by SGCR7 [7]. The unicast MAC address filtering function is useful in preventing the broadcast of unicast packets that could degrade the quality of this port in applications such as voice over Internet Protocol (VoIP). Configuration Interface The KSZ8862M operates only as a managed switch. EEPROM Interface It is optional in the KSZ8862M to use an external EEPROM. In the case that an EEPROM is not used, the EEEN pin must be tied Low or floating. The external serial EEPROM with a standard microwire bus interface is used for non-volatile storage of information such as the host MAC address, base address, and default configuration settings. The KSZ8862M can detect if the EEPROM is a 1KB (93C46) or 4KB (93C66) EEPROM device (the 93C46 and the 93C66 are typical EEPROM devices). The EEPROM is organized as 16-bit mode. If the EEEN pin is pulled high, the KSZ8862M performs an automatic read of the external EEPROM words 0H to 6H after the de-assertion of Reset. The EEPROM values are placed in certain host-accessible registers. EEPROM read/write functions can also be performed by software read/writes to the EEPCR registers. The KSZ8862M EEPROM format is given below.
WORD 0H 1H 2H 3H 4H 5H 6H 7H-3FH
15 Base Address Host MAC Address Byte 2 Host MAC Address Byte 4 Host MAC Address Byte 6 Reserved Reserved
8
7 Host MAC Address Byte 1 Host MAC Address Byte 3 Host MAC Address Byte 5
0
ConfigParam (see Table 13) Not used for KSZ8862M (available for user to use) Table 12. EEPROM Format
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Bit 15 -2 1 Bit Name Reserved Clock_Rate Description Reserved
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Internal clock rate selection 0: 125 MHz 1: 25 MHz Note: At power up, this chip operates on 125 MHz clock. The internal frequency can be dropped to 25 MHz via the external EEPROM. Async 8-bit or 16-bit bus select 1= bus is configured for 16-bit width 0= bus is configured for 8-bit width (32-bit width, KSZ8862-32, don’t care this bit setting) Table 13. ConfigParam Word in EEPROM Format
0
ASYN_8bit
Loopback Support The KSZ8862M provides loopback support for remote diagnostic of failure. In loopback mode, the speed at both PHY ports will be set to 100BASE-TX full-duplex mode. Two types of loopback are supported: Far-end Loopback and Near-end (Remote) Loopback. Far-end Loopback Far-end loopback is conducted between the KSZ8862M’s two PHY ports. The loopback path starts at the “Originating.” PHY port’s receive inputs (RXP/RXM), wraps around at the “loopback” PHY port’s PMD/PMA, and ends at the “Originating” PHY port’s transmit outputs (TXP/TXM). Bit [8] of registers P1CR4 and P2CR4 is used to enable far-end loopback for ports 1 and 2, respectively. Alternatively, Bit [14] of registers P1MBCR and P2MBCR can also be used to enable far-end loopback. The port 2 far-end loopback path is illustrated in the Figure 12. Near-end (Remote) Loopback Near-end (Remote) loopback is conducted at either PHY port 1 or PHY port 2 of the KSZ8862M. The loopback path starts at the PHY port receiving inputs (RXPx/RXMx), wraps around at the same PHY port’s PMD/PMA, and ends at the PHY port’s transmit outputs (TXPx/TXMx). Bit [1] of registers P1PHYCTRL and P2PHYCTRL is used to enable near-end loopback for ports 1 and 2, respectively. Alternatively, Bit [9] of registers P1SCSLMD and P2SCSLMD can also be used to enable near-end loopback. The both ports 1 and 2 near-end loopback paths are illustrated in the following Figure 13.
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RXP1 / RXM 1
O r ig in a tin g P H Y P ort 1
TXP1 / TXM 1
P M D 1 /P M A 1
PCS1 MAC1 S w it c h MAC2 PCS2
P M D 2 /P M A 2
P H Y P ort 2 F a r-e n d L o o p b a ck
Figure 12. Port 2 Far-End Loopback Path
RXP1 / RXM1
P H Y P o rt 1 N e a r -e n d (re m o te ) Loopback
TXP1 / TXM 1
P M D 1 /P M A 1
PCS1 MAC1 S w itc h MAC2 PCS2
P M D 2 /P M A 2
TXP2 / TXM 2
P H Y P o rt 2 N e a r-e n d (re m o te ) Loopback
RXP2 / RXM2
Figure 13. Port 1 and port 2 Near-End (Remote) Loopback Path
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CPU Interface I/O Registers
The KSZ8862M provides an EISA-like, ISA-like, or VLBUS-like bus interface for the CPU to access its internal I/O registers. I/O registers serve as the address that the microprocessor uses when communicating with the device. This is used for configuring operational settings, reading or writing control, status information, and transferring packets by reading and writing through the packet data registers. I/O Registers Input/Output (I/O) registers are limited to 16 locations as required by most ISA bus-based systems; therefore, registers are assigned to different banks. The last word of the I/O register locations (0xE - 0xF) is shared by all banks and can be used to change the bank in use. The following I/O Space Mapping Tables apply to 8, 16 or 32-bit bus products. Depending on the bus interface used and byte enable signals (BE[3:0]N control byte access), each I/O access can be performed as an 8-bit, 16-bit, or 32-bit operation. (The KSZ8862M is not limited to 8/16-bit performance and 32-bit read/write are also supported).
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�Micrel, Inc. Internal I/O Space Mapping I/O Register Location
32-Bit 16-Bit 8-Bit
0x0 0x0 - 0x1 0x0 To 0x3 0x2 - 0x3 0x3 QMU RX Flow Control Watermark [7:0] QMU RX Flow Control Watermark [15:8] Bus Error Status [7:0] Bus Error Status [15:8] Bus Burst Length [7:0] Bus Burst Length [15:8] Reserved Reserved 0x2 0x1
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Bank Location
Bank 1 Bank 2 Bank 3 Bank 4 Bank 5 Bank 6 Bank 7
Host MAC On-Chip Bus Address Low Control [7:0] [7:0] Host MAC On-Chip Bus Address Low Control [15:8] [15:8] Host MAC EEPROM Address Mid Control [7:0] [7:0] Host MAC EEPROM Address Mid Control [15:8] [15:8] Host MAC Memory BIST Address High Info [7:0] [7:0] Host MAC Memory BIST Address High Info [15:8] [15:8] Global Reset [7:0] Global Reset [15:8] Bus Configuration [7:0] Bus Configuration [15:8]
Bank 0
Base Address [7:0] Base Address [15:8]
Reserved
Reserved
Reserved
0x4 0x4 - 0x5 0x4 To 0x7 0x6 0x6 - 0x7 0x7 0x5
Reserved
Reserved
Reserved
Reserved
Reserved
0x8 0x8 - 0x9 0x9 0x8 To 0xB 0xA - 0xB 0xB 0xA
Reserved
Reserved
Reserved
Reserved
0xC 0xC - 0xD 0xC To 0xF 0xE 0xE - 0xF 0xF Bank Select [15:8] Bank Select [7:0] 0xD Reserved
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32-Bit 16-Bit 8-Bit
0x0 0x0 - 0x1 0x0 To 0x3 0x2 - 0x3 0x3 Reserved 0x2 0x1 Reserved
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Bank Location
Bank 8 Bank 9 Bank 10 Bank 11 Bank 12 Bank 13 Bank 14 Bank 15
0x4 0x4 - 0x5 0x4 To 0x7 0x6 - 0x7 0x7 Reserved 0x6 0x5 Reserved
0x8 0x8 - 0x9 0x8 To 0xB 0xA - 0xB 0xB Reserved 0xA 0x9 Reserved
0xC 0xC - 0xD 0xC To 0xF 0xE 0xE - 0xF 0xF Bank Select [15:8] Bank Select [7:0] 0xD Reserved
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�Micrel, Inc. Internal I/O Space Mapping (continued) I/O Register Location
32-Bit 16-Bit 8-Bit
0x0 0x0 - 0x1 0x0 To 0x3 0x2 - 0x3 0x3 0x2 0x1
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Bank Location
Bank 16
Transmit Control [7:0] Transmit Control [15:8] Transmit Status [7:0] Transmit Status [15:8] Receive Control [7:0] Receive Control [15:8]
Bank 17
TXQ Command [7:0] TXQ Command [15:8] RXQ Command [7:0] RXQ Command [15:8] TX Frame Data Pointer [7:0] TX Frame Data Pointer [15:8] RX Frame Data Pointer [7:0] RX Frame Data Pointer [15:8]
Bank 18
Interrupt Enable [7:0] Interrupt Enable [15:8] Interrupt Status [7:0] Interrupt Status [15:8] Receive Status [7:0] Receive Status [15:8] Receive Byte Counter [7:0] Receive Byte Counter [15:8]
Bank 19
Multicast Table 0 [7:0] Multicast Table 0 [15:8] Multicast Table 1 [7:0] Multicast Table 1 [15:8] Multicast Table 2 [7:0] Multicast Table 2 [15:8] Multicast Table 3 [7:0] Multicast Table 3 [15:8]
Bank 20
Bank 21
Bank 22
Bank 23
Reserved
Reserved
0x4 0x4 - 0x5 0x4 To 0x7 0x6 - 0x7 0x7 0x6 0x5
Reserved
Reserved
Reserved
0x8 0x8 - 0x9 0x9 0x8 To 0xB 0xA - 0xB 0xB 0xA
QMU Data Low [7:0] QMU Data Low [15:8] RXQ Memory QMU Data Information High [7:0] [7:0] RXQ Memory Information [15:8] QMU Data High [15:8]
TXQ Memory Information [7:0] TXQ Memory Information [15:8]
Reserved
Reserved
Reserved
Reserved
0xC 0xC - 0xD 0xC To 0xF 0xE 0xE - 0xF 0xF Bank Select [15:8] Bank Select [7:0] 0xD Reserved
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�Micrel, Inc. Internal I/O Space Mapping (continued) I/O Register Location
32-Bit 16-Bit 8-Bit
0x0 0x0 - 0x1 0x0 To 0x3 0x2 - 0x3 0x3 Reserved 0x2 0x1 Reserved
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Bank Location
Bank 24 Bank 25 Bank 26 Bank 27 Bank 28 Bank 29 Bank 30 Bank 31
0x4 0x4 - 0x5 0x4 To 0x7 0x6 - 0x7 0x7 Reserved 0x6 0x5 Reserved
0x8 0x8 - 0x9 0x8 To 0xB 0xA - 0xB 0xB Reserved 0xA 0x9 Reserved
0xC 0xC - 0xD 0xC To 0xF 0xE 0xE - 0xF 0xF Bank Select [15:8] Bank Select [7:0] 0xD Reserved
August 2010
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M9999-081310-3.1
�Micrel, Inc. Internal I/O Space Mapping (continued) I/O Register Location
32-Bit 16-Bit 8-Bit
0x0 0x0 - 0x1 0x0 To 0x3 0x2 - 0x3 0x3 0x2 0x1
KSZ8862-16/32MQL
Bank Location
Bank 32
Switch ID and Enable [7:0] Switch ID and Enable [15:8] Switch Global Control 1 [7:0] Switch Global Control 1 [15:8] Switch Global Control 2 [7:0] Switch Global Control 2 [15:8] Switch Global Control 3 [7:0] Switch Global Control 3 [15:8] Switch Global Control 4 [7:0] Switch Global Control 4 [15:8] Switch Global Control 5 [7:0] Switch Global Control 5 [15:8]
Bank 33
Switch Global Control 6 [7:0] Switch Global Control 6 [15:8] Switch Global Control 7 [7:0] Switch Global Control 7 [15:8]
Bank 34
Bank 35
Bank 36
Bank 37
Bank 38
Bank 39
MAC Address 1 [7:0] MAC Address 1 [15:8] MAC Address 2 [7:0] MAC Address 2 [15:8] MAC Address 3 [7:0] MAC Address 3 [15:8]
Reserved
Reserved
0x4 0x4 - 0x5 0x4 To 0x7 0x6 - 0x7 0x7 0x6 0x5
Reserved
Reserved
0x8 0x8 - 0x9 0x9 0x8 To 0xB 0xA - 0xB 0xB 0xA
Reserved
Reserved
0xC 0xC - 0xD 0xC To 0xF 0xE 0xE - 0xF 0xF Bank Select [15:8] Bank Select [7:0] 0xD Reserved
August 2010
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M9999-081310-3.1
�Micrel, Inc. Internal I/O Space Mapping (continued) I/O Register Location
32-Bit 16-Bit 8-Bit
0x0 0x0 - 0x1 0x0 To 0x3 0x2 0x2 - 0x3 0x3 TOS Priority TOS Priority Indirect Control 2 Control 8 Access Data 1 [7:0] [7:0] [7:0] TOS Priority TOS Priority Indirect Control 2 Control 8 Access Data 1 [15:8] [15:8] [15:8] TOS Priority Control 3 [7:0] Reserved 0x5 TOS Priority Control 3 [15:8] TOS Priority Control 4 [7:0] TOS Priority Control 4 [15:8] TOS Priority Control 5 [7:0] TOS Priority Control 5 [15:8] TOS Priority Control 6 [7:0] TOS Priority Control 6 [15:8] Indirect Access Data 2 [15:8] Indirect Access Data 3 [7:0] Indirect Access Data 3 [15:8] Indirect Access Data 4 [7:0] Indirect Access Data 4 [15:8] Indirect Access Data 5 [7:0] Reserved Indirect Access Data 5 [15:8] Reserved Indirect Access Data 2 [7:0] Reserved Digital Test Control [15:8] Analog Test Control 0 [7:0] Analog Test Control 0 [15:8] Analog Test Control 1 [7:0] Analog Test Control 1 [15:8] Analog Test Control 2 [7:0] Analog Test Control 2 [15:8] Reserved Analog Test Status [7:0] Analog Test Status [15:8] Digital Test Control [7:0] 0x1
KSZ8862-16/32MQL
Bank Location
Bank 40 Bank 41 Bank 42 Bank 43 Bank 44
Digital Test Status [7:0] Reserved Ctrl. Digital Test Status [15:8]
Bank 45
PHY1 MIIRegister Basic Control [7:0] PHY1 MIIRegister Basic Control [15:8] PHY1 MIIRegister Basic Status [7:0] PHY1 MIIRegister Basic Status [15:8] PHY1 PHYID Low [7:0]
Bank 46
PHY2 MIIRegister Basic Control [7:0] PHY2 MIIRegister Basic Control [15:8] PHY2 MIIRegister Basic Status [7:0] PHY2 MIIRegister Basic Status [15:8] PHY2 PHYID Low [7:0]
Bank 47
TOS Priority TOS Priority Indirect Control 1 Control 7 Access Ctrl. [7:0] [7:0] [7:0] TOS Priority TOS Priority Indirect Control 1 Control 7 Access [15:8] [15:8] [15:8]
Reserved
PHY1 Special Control/Status [7:0] PHY1 Special Control/Status [15:8] PHY2 LinkMD® Control/Status [7:0]
0x4 0x4 - 0x5 0x4 To 0x7 0x6 0x6 - 0x7 0x7
Reserved
Reserved
PHY1 PHYID PHY2 PHYID PHY2 Low Low LinkMD® Control/Status [15:8] [15:8] [15:8] PHY1 PHYID PHY2 PHYID PHY2 Special High High Control/Status [7:0] [7:0] [7:0] PHY1 PHYID PHY2 PHYID PHY2 Special High High Control/Status [15:8] [15:8] [15:8] PHY1 A.N. Advertisement [7:0] PHY1 A.N. Advertisement [15:8] PHY1 A.N. Link Partner Ability [7:0] PHY1 A.N. Link Partner Ability [15:8] PHY2 A.N. Advertisement [7:0] PHY2 A.N. Advertisement [15:8] PHY2 A.N. Link Partner Ability [7:0] PHY2 A.N. Link Partner Ability [15:8]
0x8 0x8 - 0x9 0x9 0x8 To 0xB 0xA - 0xB 0xB 0xA
Reserved
Reserved
Reserved
Reserved
0xC 0xC - 0xD 0xC To 0xF 0xE 0xE - 0xF 0xF Bank Select [15:8] Bank Select [7:0] 0xD Reserved
August 2010
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M9999-081310-3.1
�Micrel, Inc. Internal I/O Space Mapping (continued) I/O Register Location
32-Bit 16-Bit 8-Bit
0x0 0x0 - 0x1 0x0 To 0x3 0x2 0x2 - 0x3 0x3 0x1 Port 1 Control 1 [15:8]
KSZ8862-16/32MQL
Bank Location
Bank 48
Port 1 Control 1 [7:0]
Bank 49
Port 1 PHY Special Control/Status, LinkMD® [7:0] Port 1 PHY Special Control/Status, LinkMD® [15:8] Port 1 Control 4 [7:0] Port 1 Control 4 [15:8]
Bank 50
Port 2 Control 1 [7:0] Port 2 Control 1 [15:8]
Bank 51
Port 2 PHY Special Control/Status, LinkMD® [7:0] Port 1 PHY Special Control/Status, LinkMD® [15:8] Port 2 Control 4 [7:0] Port 2 Control 4 [15:8]
Bank 52
Host Port Control 1 [7:0] Host Port Control 1 [15:8]
Bank 53
Bank 54
Bank 55
Reserved
0x4 0x4 - 0x5 0x4 To 0x7 0x6 - 0x7 0x7 0x6 0x5
Port 1 Control 2 [7:0] Port 1 Control 2 [15:8] Port 1 VID Port 1 Control Status [7:0] [7:0]
Port 2 Control 2 [7:0] Port 2 Control 2 [15:8] Port 2 VID Port 2 Control Status [7:0] [7:0] Port 2 Control [15:8] Port 2 Control 3 [7:0] Port 2 Control 3 [15:8] Port2 Ingress Rate Control [7:0] Port2 Ingress Rate Control [15:8] Port2 Egress Rate Control [7:0] Port2 Egress Rate Control [15:8] VID Port 2 Status [15:8]
Host Port Control 2 [7:0] Host Port Control 2 [15:8] Host Port VID Control [7:0] Host Port VID Control [15:8] Host Port Control 3 [7:0] Host Port Control 3 [15:8] Host Port Ingress Rate Control [7:0] Host Port Ingress Rate Control [15:8] Host Port Egress Rate Control [7:0]
Reserved
Reserved
0x8 0x8 - 0x9 0x9 0x8 To 0xB 0xA - 0xB 0xB 0xA
Port 1 VID Port 1 Control Status [15:8] [15:8] Port 1 Control 3 [7:0] Reserved Port 1 Control 3 [15:8] Port1 Ingress Rate Control [7:0] Reserved Port1 Ingress Rate Control [15:8] Port1 Egress Rate Control [7:0] Reserved Port1 Egress Rate Control [15:8]
Reserved
Reserved
Reserved
Reserved
Reserved
Host Port Egress Rate Control [15:8]
Reserved
0xC 0xC - 0xD 0xC To 0xF 0xE 0xE - 0xF 0xF Bank Select [15:8] Bank Select [7:0] 0xD Reserved
August 2010
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M9999-081310-3.1
�Micrel, Inc. Internal I/O Space Mapping (continued) I/O Register Location
32-Bit 16-Bit 8-Bit
0x0 0x0 - 0x1 0x0 To 0x3 0x2 - 0x3 0x3 Reserved 0x2 0x1 Reserved
KSZ8862-16/32MQL
Bank Location
Bank 56 Bank 57 Bank 58 Bank 59 Bank 60 Bank 61 Bank 62 Bank 63
0x4 0x4 - 0x5 0x4 To 0x7 0x6 - 0x7 0x7 Reserved 0x6 0x5 Reserved
0x8 0x8 - 0x9 0x8 To 0xB 0xA - 0xB 0xB Reserved 0xA 0x9 Reserved
0xC 0xC - 0xD 0xC To 0xF 0xE 0xE - 0xF 0xF Bank Select [15:8] Bank Select [7:0] 0xD Reserved
August 2010
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�Micrel, Inc.
KSZ8862-16/32MQL
Register Map: Switch and MAC/PHY
Do not write to bit values or to registers defined as Reserved. Manipulating reserved bits or registers causes unpredictable and often fatal results. If the user wants to write to these reserved bits, the user has to read back these reserved bits (RO or RW) first, then “OR” with the read value of the reserved bits and write back to these reserved bits. Bit Type Definition RO = Read only. RW = Read/Write. W1C = Write 1 to Clear (writing a one to this bit clears it). Bank 0-63 Bank Select Register (0x0E): BSR (same location in all Banks) The bank select register is used to select or to switch between different sets of register banks for I/O access. There are a total of 64 banks available to select, including the built-in switch engine registers.
Bit 15-6 5-0 Default Value 0x000 0x00 R/W RO R/W Description Reserved BSA Bank Select Address Bits BSA bits select the I/O register bank in use. This register is always accessible regardless of the register bank currently selected. Notes: The bank select register can be accessed as a doubleword (32-bit) at offset 0xC, as a word (16-bit) at offset 0xE, or as a byte (8-bit) at offset 0xE. A doubleword write to offset 0xC writes to the BANK Select Register but does not write to registers 0xC and 0xD; it only writes to register 0xE.
Bank 0 Base Address Register (0x00): BAR This register holds the base address for decoding a device access. Its value is loaded from the external EEPROM (0x0H) upon a power-on reset if the EEPROM Enable (EEEN) pin is tied to High. Its value can also be modified after reset. Writing to this register does not store the value into the EEPROM. When the EEEN pin is tied to Low, the default base address is 0x0300.
Bit 15-8 Default Value 0x03 if EEEN is Low or, the value from EEPROM if EEEN is High 0x0 if EEEN is Low or, the value from EEPROM if EEEN is High 0x00 R/W RW Description BARH Base Address High These bits are compared against the address on the bus ADDR[15:8] to determine the BASE for the KSZ8862M registers.
7-5
RW
BARL Base Address Low These bits are compared against the address on the bus ADDR[7:5] to determine the BASE for the KSZ8862M registers.
4-0
RO
Reserved
Bank 0 QMU RX Flow Control High Watermark Configuration Register (0x04): QRFCR This register contains the user defined QMU RX Queue high watermark configuration bit as below.
Bit 15-13 12 11-0 Default Value 0x0 0 0x000 R/W RO RW RO Description Reserved QMU RX Flow Control High Watermark Configuration 0: To select 3 Kbytes, 1: To select 2 Kbytes Reserved
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�Micrel, Inc. Bank 0 Bus Error Status Register (0x06): BESR This register flags the different kinds of errors on the host bus.
Bit 15 Default Value 0 R/W RO Description
KSZ8862-16/32MQL
IBEC Illegal Byte Enable Combination 1: illegal byte enable combination occurs. The illegal combination value can be found from bit 14 to bit 11. 0: legal byte enable combination. Write 1 to clear. IBECV Illegal Byte Enable Combination Value Bit 14: byte enable 3. Bit 13: byte enable 2. Bit 12: byte enable 1. Bit 11: byte enable 0. This value is valid only when bit 15 is set to 1. SSAXFER Simultaneous Synchronous and Asnychronous Transfers 1: Synchronous and Asnychronous Transfers occur simultaneously. 0: normal. Write 1 to clear. Reserved
14-11
-
RO
10
0
RO
9-0
0x000
RO
Bank 0 Bus Burst Length Register (0x08): BBLR Before the burst can be sent, the burst length needs to be programmed.
Bit 15 14-12 Default Value 0 0x0 R/W RO RW Description Reserved BRL Burst Length (for burst read and write) 000: single. 011: fixed burst read length of 4. 101: fixed burst read length of 8. 111: fixed burst read length of 16. Reserved
11-0
0x000
RO
Bank 1 Reserved Except Bank Select Register (0xE). Bank 2 Host MAC Address Register Low (0x00): MARL This register along with the other two Host MAC address registers are loaded starting at word location 0x1 of the EEPROM upon hardware reset. The software driver can modify the register, but it will not modify the original Host MAC address value in the EEPROM. These six bytes of Host MAC address in external EEPROM are loaded to these three registers as mapping below: MARL[15:0] = EEPROM 0x1(MAC Byte 2 and 1) MARM[15:0] = EEPROM 0x2(MAC Byte 4 and 3) MARH[15:0] = EEPROM 0x3(MAC Byte 6 and 5) The Host MAC address is used to define the individual destination address that the KSZ8862M responds to when receiving frames. Network addresses are generally expressed in the form of 01:23:45:67:89:AB, where the bytes are received from left to right, and the bits within each byte are received from right to left (LSB to MSB). For example, the actual transmitted and received bits are on the order of 10000000 11000100 10100010 11100110 10010001 11010101. These three registers value for Host MAC address 01:23:45:67:89:AB will be held as below: MARL[15:0] = 0x89AB MARM[15:0] = 0x4567 August 2010 58 M9999-081310-3.1
�Micrel, Inc. MARH[15:0] = 0x0123 The following table shows the register bit fields:
Bit 15-0 Default Value R/W RW Description MARL MAC Address Low The least significant word of the MAC address.
KSZ8862-16/32MQL
Bank 2 Host MAC Address Register Middle (0x02): MARM The middle word of Host MAC address. The following table shows the register bit fields:
Bit 15-0 Default Value R/W RW Description MARM MAC Address Middle The middle word of the MAC address.
Bank 2 Host MAC Address Register High (0x04): MARH The high word of Host MAC address. The following table shows the register bit fields.
Bit 15-0 Default Value R/W RW Description MARH MAC Address High The Most significant word of the MAC address.
Bank 3 On-Chip Bus Control Register (0x00): OBCR This register controls the on-chip bus speed for the KSZ8862M. It is used for power management when the external host CPU is running at a slow frequency. The default of the on-chip bus speed is 125 MHz without EEPROM. When the external host CPU is running at a higher clock rate, the on-chip bus should be adjusted for the best performance.
Bit 15-2 1-0 Default Value 0x0 R/W RO RW Description Reserved OBSC On-Chip Bus Speed Control 00: 125MHz. 01: 62.5MHz. 10: 41.66MHz. 11: 25MHz. Note: When external EEPROM is enabled, the bit 1 in Configparm word (0x6H) is used to contol this speed as below: Bit 1 = 0 , this value will be 00 for 125 MHz. Bit 1 = 1 , this value will be 11 for 25 MHz. (User still can write these two bits to change speed after EEPROM data loaded)
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KSZ8862-16/32MQL
Bank 3 EEPROM Control Register (0x02): EEPCR To support an external EEPROM, tie the EEPROM Enable (EEEN) pin to High; otherwise, tie it to Low. If an external EEPROM is not used, the default chip Base Address (0x300), and the software programs the host MAC address. If an EEPROM is used in the design (EEPROM Enable pin to High), the chip Base Address and host MAC address are loaded from the EEPROM immediately after reset. The KSZ8862M allows the software to access (read and write) the EEPROM directly; that is, the EEPROM access timing can be fully controlled by the software if the EEPROM Software Access bit is set.
Bit 15-5 4 Default Value 0 R/W RO RW Description Reserved EESA EEPROM Software Access 1: enable software to access EEPROM through bit 3 to bit 0. 0: disable software to access EEPROM. EECB EEPROM Status Bit Data Receive from EEPROM. This bit directly reads the EEDI pin. EECB EEPROM Control Bits Bit 2: Data Transmit to EEPROM. This bit directly controls the device’s EEDO pin. Bit 1: Serial Clock. This bit directly controls the device’s EESK pin. Bit 0: Chip Select for EEPROM. This bit directly controls the device’s EECS pin.
3 2-0
0x0
RO RW
Bank 3 Memory BIST INFO Register (0x04): MBIR
Bit 15-13 12 11 10-5 4 3 2-0 Default Value 0x0 R/W RO RO RO RO RO RO RO Description Reserved TXMBF TX Memory Bist Finish When set, it indicates the Memory Built In Self Test completion for the TX Memory. TXMBFA TX Memory Bist Fail When set, it indicates the Memory Built In Self Test has failed. Reserved RXMBF RX Memory Bist Finish When set, it indicates the Memory Built In Self Test completion for the RX Memory. RXMBFA RX Memory Bist Fail When set, it indicates the Memory Built In Self Test has failed. Reserved
Bank 3 Global Reset Register (0x06): GRR This register controls the global reset function with information programmed by the CPU.
Bit 15-1 0 Default Value 0x0000 0 R/W RO RW Description Reserved Global Soft Reset 1: software reset is active. 0: software reset is inactive. Software reset will affect PHY, MAC, QMU, DMA, and the switch core, only the BIU (base address registers) remains unaffected by a software reset.
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KSZ8862-16/32MQL
Bank 3 Bus Configuration Register (0x08): BCFG This register is a read-only register. The bit 0 is automatically downloaded from bit 0 Configparm word of EEPROM, if pin EEEN is high (enabled EEPROM)
Bit 15-1 0 Default Value 0x0000 R/W RO RO Description Reserved Bus Configuration (only for KSZ8862-16 device) 1: bus width is 16 bits. 0: bus width is 8 bits. (this bit is only avaiable when EEPROM is enabled)
Banks 4 – 15: Reserved Except Bank Select Register (0xE). Bank 16 Transmit Control Register (0x00): TXCR This register holds control information programmed by the CPU to control the QMU transmit module function.
Bit 15 14 13 12-4 3 Default Value 0x0 0x0 0x0 R/W RO RW RW RO RW Description Reserved Reserved Reserved Reserved TXFCE Transmit Flow Control Enable When this bit is set, the QMU sends flow control pause frames from the host port if the RX FIFO has reached its threshold. Note: the SGCR3[5] in Bank 32 also needs to be enabled. TXPE Transmit Padding Enable When this bit is set, the KSZ8862M automatically adds a padding field to a packet shorter than 64 bytes. Note: Setting this bit requires enabling the ADD CRC feature to avoid CRC errors for the transmit packet. TXCE Transmit CRC Enable When this bit is set, the KSZ8862M automatically adds a CRC checksum field to the end of a transmit frame. TXE Transmit Enable When this bit is set, the transmit module is enabled and placed in a running state. When reset, the transmit process is placed in the stopped state after the transmission of the current frame is completed.
2
0x0
RW
1
0x0
RW
0
0x0
RW
Bank 16 Transmit Status Register (0x02): TXSR This register keeps the status of the last transmitted frame.
Bit 15-6 5-0 Default Value 0x000 R/W RO RO Description Reserved TXFID Transmit Frame ID This field identifies the transmitted frame. All of the transmit status information in this register belongs to the frame with this ID.
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�Micrel, Inc. Bank 16 Receive Control Register (0x04): RXCR This register holds control information programmed by the CPU to control the receive function.
Bit 15-11 10 Default Value 0x0 R/W RO RW Description Reserved
KSZ8862-16/32MQL
RXFCE Receive Flow Control Enable When this bit is set, the KSZ8862M will acknowledge a PAUSE frame from the receive interface; i.e., the outgoing packets are pending in the transmit buffer until the PAUSE frame control timer expires. When this bit is cleared, flow control is not enabled. RXEFE Receive Error Frame Enable When this bit is set, CRC error frames are allowed to be received into the RX queue. When reset, all CRC error frames are discarded. Reserved RXBE Receive Broadcast Enable When this bit is set, the RX module receives all the broadcast frames. RXME Receive Multicast Enable When this bit is set, the RX module receives all the multicast frames (including broadcast frames). RXUE Receive Unicast When this bit is set, the RX module receives unicast frames that match the 48-bit Station MAC address of the module. RXRA Receive All When this bit is set, the KSZ8862M receives all incoming frames, regardless of the frame’s destination address. RXSCE Receive Strip CRC When this bit is set, the KSZ8862M strips the CRC on the received frames. Once cleared, the CRC is stored in memory following the packet. QMU Receive Multicast Hash-Table Enable When this bit is set, this bit enables the RX function to receive multicast frames that pass the CRC Hash filtering mechanism. Reserved RXE Receive Enable When this bit is set, the RX block is enabled and placed in a running state. When reset, the receive process is placed in the stopped state upon completing reception of the current frame.
9
0x0
RW
8 7 6
0x0 0x0
RO RW RW
5
0x0
RW
4
0x0
RW
3
0x0
RW
2
0x0
RW
1 0
0x0
RO RW
Bank 16 TXQ Memory Information Register (0x08): TXMIR This register indicates the amount of free memory available in the TXQ of the QMU module.
Bit 15-13 12-0 Default Value R/W RO RO Description Reserved TXMA Transmit Memory Available The amount of memory available is represented in units of byte. The TXQ memory is used for both frame payload, control word. There is total 4096 bytes in TXQ. Note: Software must be written to ensure that there is enough memory for the next transmit frame including control information before transmit data is written to the TXQ.
August 2010
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�Micrel, Inc. Bank 16 RXQ Memory Information Register (0x0A): RXMIR This register indicates the amount of receive data available in the RXQ of the QMU module.
Bit 15-13 12-0 Default Value R/W RO RO Description
KSZ8862-16/32MQL
Reserved RXMA Receive Packet Data Available The amount of Receive packet data available is represented in units of byte. The RXQ memory is used for both frame payload, status word. There is total 4096 bytes in RXQ. This counter will update after a complete packet is received and also issues an interrupt when receive interrupt enable IER[13] in Bank 18 is set. Note: Software must be written to empty the RXQ memory to allow for the new RX frame. If this is not done, the frame may be discarded as a result of insufficient RXQ memory.
Bank 17 TXQ Command Register (0x00): TXQCR This register is programmed by the Host CPU to issue a transmit command to the TXQ. The present transmit frame in the TXQ memory is queued for transmit.
Bit 15-1 0 Default Value 0x0 R/W RO RW Description Reserved TXETF Enqueue TX Frame When this bit is set as 1, the current TX frame prepared in the TX buffer is queued for transmit. Note: This bit is self-clearing after the frame is finished transmitting. The software should wait for the bit to be cleared before setting up another new TX frame.
Bank 17 RXQ Command Register (0x02): RXQCR This register is programmed by the Host CPU to issue release command to the RXQ. The current frame in the RXQ frame buffer is read out by the host and the memory space is released.
Bit 15-1 0 Default Value 0x0 R/W RO RW Description Reserved Do not write to this register. RXRRF Release RX Frame When this bit is set as 1, the current RX frame buffer is released. Note: This bit is self-clearing after the frame memory is released. The software should wait for the bit to be cleared before processing new RX frames.
Bank 17 TX Frame Data Pointer Register (0x04): TXFDPR The value of this register determines the address to be accessed within the TXQ frame buffer. When the AUTO increment is set, it will automatically increment the pointer value on Write accesses to the data register. The counter is incremented by one for every byte access, by two for every word access, and by four for every double word access.
Bit 15 14 Default Value 0x0 R/W RO RW Description Reserved TXFPAI TX Frame Data Pointer Auto Increment When this bit is set, the TX Frame data pointer register increments automatically on accesses to the data register. The increment is by one for every byte access, by two for every word access, and by four for every doubleword access. When this bit is reset, the TX frame data pointer is manually controlled by user to access the TX frame location. Reserved TXFP TX Frame Pointer TX Frame Pointer index to the Frame Data register for access. This field reset to next available TX frame location when the TX Frame Data has been enqueued through the TXQ command register.
13-11 10-0
0x0
RO RW
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KSZ8862-16/32MQL
Bank 17 RX Frame Data Pointer Register (0x06): RXFDPR The value of this register determines the address to be accessed within the RXQ frame buffer. When the Auto Increment is set, it will automatically increment the RXQ Pointer on read accesses to the data register. The counter is incremented is by one for every byte access, by two for every word access, and by four for every double word access.
Bit 15 14 Default Value 0x0 R/W RO RW Description Reserved RXFPAI RX Frame Pointer Auto Increment When this bit is set, the RXQ Address register increments automatically on accesses to the data register. The increment is by one for every byte access, by two for every word access, and by four for every double word access. When this bit is reset, the RX frame data pointer is manually controlled by user to access the RX frame location. Reserved RXFP RX Frame Pointer RX Frame data pointer index to the Data register for access. This field reset to next available RX frame location when RX Frame release command is issued (through the RXQ command register).
13-11 10-0
0x0
RO RW
Bank 17 QMU Data Register Low (0x08): QDRL This register QDRL(0x08-0x09) contains the Low data word presently addressed by the pointer register. Reading maps from the RXQ, and writing maps to the TXQ.
Bit 15-0 Default Value R/W RW Description QDRL Queue Data Register Low This register is mapped into two uni-directional buffers for 16-bit buses, and one unidirectional buffer for 32-bit buses, (TXQ when Write, RXQ when Read) that allow moving words to and from the KSZ8862M regardless of whether the pointer is even, odd, or Dword aligned. Byte, word, and Dword access can be mixed on the fly in any order. This register along with DQRH is mapped into two consecutive word locations for 16-bit buses, or one word location for 32-bit buses, to facilitate Dword move operations.
Bank 17 QMU Data Register High (0x0A): QDRH This register QDRH(0x0A-0x0B) contains the High data word presently addressed by the pointer register. Reading maps from the RXQ, and writing maps to the TXQ.
Bit 15-0 Default Value R/W RW Description QDRL Queue Data Register High This register is mapped into two uni-directional buffers for 16-bit buses, and one unidirectional buffer for 32-bit buses, (TXQ when Write, RXQ when Read) that allow moving words to and from the KSZ8862M regardless of whether the pointer is even, odd, or dword aligned. Byte, word, and Dword access can be mixed on the fly in any order. This register along with DQRL is mapped into two consecutive word locations for 16-bit buses, or one word location for 32-bit buses, to facilitate Dword move operations.
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�Micrel, Inc. Bank 18 Interrupt Enable Register (0x00): IER This register enables the interrupts from the QMU and other sources.
Bit 15 Default Value 0x0 R/W RW Description LCIE Link Change Interrupt Enable When this bit is set, the link change interrupt is enabled. When this bit is reset, the link change interrupt is disabled. TXIE Transmit Interrupt Enable When this bit is set, the transmit interrupt is enabled. When this bit is reset, the transmit interrupt is disabled. RXIE Receive Interrupt Enable When this bit is set, the receive interrupt is enabled. When this bit is reset, the receive interrupt is disabled. Reserved RXOIE Receive Overrun Interrupt Enable When this bit is set, the Receive Overrun interrupt is enabled. When this bit is reset, the Receive Overrun interrupt is disabled. Reserved
KSZ8862-16/32MQL
14
0x0
RW
13
0x0
RW
12 11
0x0 0x0
RW RW
10 9
0x0 0x0
RW RW
TXPSIE Transmit Process Stopped Interrupt Enable When this bit is set, the Transmit Process Stopped interrupt is enabled. When this bit is reset, the Transmit Process Stopped interrupt is disabled. RXPSIE Receive Process Stopped Interrupt Enable When this bit is set, the Receive Process Stopped interrupt is enabled. When this bit is reset, the Receive Process Stopped interrupt is disabled. RXEFIE Receive Error Frame Interrupt Enable When this bit is set, the Receive error frame interrupt is enabled. When this bit is reset, the Receive error frame interrupt is disabled. Reserved
8
0x0
RW
7
0x0
RW
6-0
-
RO
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M9999-081310-3.1
�Micrel, Inc. Bank 18 Interrupt Status Register (0x02): ISR This register contains the status bits for all QMU and other interrupt sources. When the corresponding enable bit is set, it causes the interrupt pin to be asserted.
KSZ8862-16/32MQL
This register is usually read by the host CPU and device drivers during interrupt service routine or polling. The register bits are not cleared when read. The user has to write “1” to clear.
Bit 15 Default Value 0x0 R/W RO (W1C) Description LCIS Link Change Interrupt Status When this bit is set, it indicates that the link status has changed from link up to link down, or link down to link up. This edge-triggered interrupt status is cleared by writing 1 to this bit. TXIS Transmit Status When this bit is set, it indicates that the TXQ MAC has transmitted at least a frame on the MAC interface and the QMU TXQ is ready for new frames from the host. This edge-triggered interrupt status is cleared by writing 1 to this bit. RXIS Receive Interrupt Status When this bit is set, it indicates that the QMU RXQ has received a frame from the MAC interface and the frame is ready for the host CPU to process. This edge-triggered interrupt status is cleared by writing 1 to this bit. Reserved RXOIS Receive Overrun Interrupt Status When this bit is set, it indicates that the Receive Overrun status has occurred. This edge-triggered interrupt status is cleared by writing 1 to this bit. Reserved TXPSIE Transmit Process Stopped Status When this bit is set, it indicates that the Transmit Process has stopped. This edge-triggered interrupt status is cleared by writing 1 to this bit. RXPSIE Receive Process Stopped Status When this bit is set, it indicates that the Receive Process has stopped. This edge-triggered interrupt status is cleared by writing 1 to this bit. RXEFIE Receive Error Frame Interrupt Status When this bit is set, it indicates that the Receive error frame status has occurred. This edge-triggered interrupt status is cleared by writing 1 to this bit. Reserved
14
0x0
RO (W1C)
13
0x0
RO (W1C)
12 11
0x0 0x0
RO RO (W1C)
10 9
0x0 0x1
RO RO (W1C)
8
0x1
RO (W1C)
7
0x0
RO (W1C)
6-0
-
RO
August 2010
66
M9999-081310-3.1
�Micrel, Inc.
KSZ8862-16/32MQL
Bank 18 Receive Status Register (0x04): RXSR This register indicates the status of the current received frame and mirrors the Receive Status word of the Receive Frame in the RXQ.
Bit 15 Default Value R/W RO Description RXFV Receive Frame Valid When set, it indicates that the present frame in the receive packet memory is valid. The status information currently in this location is also valid. When clear, it indicates that there is either no pending receive frame or that the current frame is still in the process of receiving. Reserved RXSPN Receive Source Port Number When bit is set, this field indicates the source port where the packet was received. (Setting bit 9 = 0 and bit 8 = 1 indicates the packet was received from port 1. Setting bit 9 = 1 and bit 8 = 0 indicates that the packet was received from port 2. Valid port is either port 1 or port 2. RXBF Receive Broadcast Frame When set, it indicates that this frame has a broadcast address. RXMF Receive Multicast Frame When set, it indicates that this frame has a multicast address (including the broadcast address). RXUF Receive Unicast Frame When set, it indicates that this frame has a unicast address. Reserved RXFT Receive Frame Type When set, it indicates that the frame is an Ethernet-type frame (frame length is greater than 1500 bytes). When clear, it indicate that the frame is an IEEE 802.3 frame. This bit is not valid for runt frames. RXTL Receive Frame Too Long When set, it indicates that the frame length exceeds the maximum size of 1916 bytes. Frames that are too long are passed to the host only if the pass bad frame bit is set (bit 9 in RXCR register) Note: Frame too long is only a frame length indication and does not cause any frame truncation. RXRF Receive Runt Frame When set, it indicates that a frame was damaged by a collision or premature termination before the collision window has passed. Runt frames are passed to the host only if the pass bad frame bit is set (bit 9 in RXCR register). RXCE Receive CRC Error When set, it indicates that a CRC error has occurred on the current received frame. A CRC error frame is passed to the host only if the pass bad frame bit is set (bit 9 in RXCR register).
14-10 9-8
-
RO RO
7 6
-
RO RO
5 4 3
-
RO RO RO
2
-
RO
1
-
RO
0
-
RO
Bank 18 Receive Byte Counter Register (0x06): RXBC This register indicates the status of the current received frame and mirrors the Receive Byte Count word of the Receive Frame in the RXQ.
Bit 15-11 10-0 Default Value R/W RO RO Description Reserved RXBC Receive Byte Count Receive Byte Count.
August 2010
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�Micrel, Inc.
KSZ8862-16/32MQL
Bank 19 Multicast Table Register 0 (0x00): MTR0 The 64-bit multicast table is used for group address filtering. This value is defined as the six most significant bits from CRC circuit calculation result that is based on 48-bit of DA input. The two most significant bits select one of the four registers to be used, while the others determine which bit within the register. Multicast table register 0.
Bit 15-0 Default Value 0x0000 R/W RW Description MTR0 Multicast Table 0 When the appropriate bit is set, if the packet received with DA matches the CRC, the hashing function is received without being filtered. When the appropriate bit is cleared, the packet will drop. Note: When the receive all (RXRA) or receive multicast (RXRM) bit is set in the RXCR, all multicast addresses are received regardless of the multicast table value.
Bank 19 Multicast Table Register 1 (0x02): MTR1 Multicast table register 1.
Bit 15-0 Default Value 0x0000 R/W RW Description MTR0 Multicast Table 1 When the appropriate bit is set, if the packet received with DA matches the CRC, the hashing function is received without being filtered. When the appropriate bit is cleared, the packet will drop. Note: When the receive all (RXRA) or receive multicast (RXRM) bit is set in the RXCR, all multicast addresses are received regardless of the multicast table value.
Bank 19 Multicast Table Register 2 (0x04): MTR2 Multicast table register 2.
Bit 15-0 Default Value 0x0000 R/W RW Description MTR0 Multicast Table 2 When the appropriate bit is set, if the packet received with DA matches the CRC, the hashing function is received without being filtered. When the appropriate bit is cleared, the packet will drop. Note: When the receive all (RXRA) or receive multicast (RXRM) bit is set in the RXCR, all multicast addresses are received regardless of the multicast table value.
Bank 19 Multicast Table Register 3 (0x06): MTR3 Multicast table register 3.
Bit 15-0 Default Value 0x0000 R/W RW Description MTR0 Multicast Table 3 When the appropriate bit is set, if the packet received with DA matches the CRC, the hashing function is received without being filtered. When the appropriate bit is cleared, the packet will drop. Note: When the receive all (RXRA) or receive multicast (RXRM) bit is set in the RXCR, all multicast addresses are received regardless of the multicast table value.
Banks 20 – 31: Reserved Except Bank Select Register (0xE).
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M9999-081310-3.1
�Micrel, Inc. Bank 32 Switch ID and Enable Register (0x00): SIDER This register contains the switch ID and the switch enable control.
Bit 15-8 7-4 3-1 0 Default 0x88 0x8 0x1 0 R/W RO RO RO RW Description Family ID Chip family ID Chip ID 0x8 is assigned to KSZ8862M Revision ID Start Switch 1 = start the chip. 0 = switch is disabled.
KSZ8862-16/32MQL
Bank 32 Switch Global Control Register 1 (0x02): SGCR1 This register contains the global control for the switch function.
Bit 15 Default 0 R/W RW Description Pass All Frames 1 = switch all packets including bad ones. Used solely for debugging purposes. Works in conjunction with Sniffer mode only. Reserved IEEE 802.3x Transmit Direction Flow Control Enable 1 = enables transmit direction flow control feature. 0 = will not enable transmit direction flow control feature. The switch will not generate any flow control packets. IEEE 802.3x Receive Direction Flow Control Enable 1 = enables receive direction flow control feature. 0 = will not enable receive direction flow control feature. The switch will not react to any received flow control packets. Frame Length Field Check 1 = checks frame length field in the IEEE packets. If the actual length does not match, the packet will be dropped (for Length/Type field < 1500). Aging Enable 1 = enable age function in the chip. 0 = disable age function in the chip. Fast Age Enable 1 = turn on fast age (800us). Aggressive Back-Off Enable 1 = enable more aggressive back off algorithm in half-duplex mode to enhance performance. This is not an IEEE standard. Reserved Pass Flow Control Packet 1 = switch will not filter 802.1x “flow control” packets. Reserved Link Change Age 1 = link change from “link” to “no link” will cause fast aging ( TXP2/TXM2. see Figure 15) 0 = normal operation Reserved
KSZ8862-16/32MQL
Bit is same as: Bank 51 0x04 bit 13
4
0
RO
Bank 51 0x04 bit 7
3
0
RW
Bank 51 0x00 bit 11
2
1
RW
Bank 51 0x00 bit 10
1
0
RW
Bank 51 0x00 bit 9
0
0
RW
Bank 48 Port 1 Control Register 1 (0x00): P1CR1 This register contains the global per port control for the switch function.
Bit 15-8 7 Default 0x00 0 R/W RO RW Description Reserved Broadcast Storm Protection Enable 1 = enable broadcast storm protection for ingress packets on the port. 0 = disable broadcast storm protection. Diffserv Priority Classification Enable 1= enable DiffServ priority classification for ingress packets on the port. 0 = disable DiffServ function. 802.1p Priority Classification Enable 1= enable 802.1p priority classification for ingress packets on the port. 0 = disable 802.1p. Port-Based Priority Classification 00 - ingress packets on port are classified as priority 0 queue if “DiffServ” or “802.1p” classification is not enabled or fails to classify. 01 - ingress packets on port are classified as priority 1 queue if “DiffServ” or “802.1p” classification is not enabled or fails to classify. 10 - ingress packets on port are classified as priority 2 queue if “DiffServ” or “802.1p” classification is not enabled or fails to classify. 11 - ingress packets on port are classified as priority 3 queue if “Diffserv” or “802.1p” classification is not enabled or fails to classify. Note: “DiffServ”, “802.1p” and port priority can be enabled at the same time. The OR’ed result of 802.1p and DSCP overwrites the port priority. Tag Insertion 1 = when packets are output on the port, the switch adds 802.1p/q tags to packets without 802.1p/q tags when received. The switch will not add tags to packets already tagged. The tag inserted is the ingress port’s “port VID”. 0 = disable tag insertion.
6
0
RW
5
0
RW
4-3
0x0
RW
2
0
RW
August 2010
88
M9999-081310-3.1
�Micrel, Inc.
KSZ8862-16/32MQL
Bit 1
Default 0
R/W RW
Description Tag Removal 1 = when packets are output on the port, the switch removes 802.1p/q tags from packets with 802.1p/q tags when received. The switch will not modify packets received without tags. 0 = disable tag removal. TX Multiple Queues Select Enable 1 = the port output queue is split into four priority queues. 0 = single output queue on the port. There is no priority differentiation even though packets are classified into high or low priority.
0
0
RW
Bank 48 Port 1 Control Register 2 (0x02): P1CR2 This register contains the global per port control for the switch function.
Bit 15 14 Default 0 0 R/W RW RW Description Reserved Ingress VLAN Filtering 1= the switch discards packets whose VID port membership in VLAN table bits [18:16] does not include the ingress port VID. 0 = no ingress VLAN filtering. Discard Non PVID Packets 1 = the switch discards packets whose VID does not match the ingress port default VID. 0 = no packets are discarded. Force Flow Control 1 = always enable flow control on the port, regardless of AN result. 0 = the flow control is enabled based on AN result. Back Pressure Enable 1 = enable port’s half-duplex back pressure. 0 = disable port’s half-duplex back pressure. Transmit Enable 1 = enable packet transmission on the port. 0 = disable packet transmission on the port. Receive Enable 1 = enable packet reception on the port. 0 = disable packet reception on the port. Learning Disable 1 = disable switch address learning capability. 0 = enable switch address learning. Sniffer Port 1 = port is designated as a sniffer port and transmits packets that are monitored. 0 = port is a normal port. Receive Sniff 1 = all packets received on the port are marked as “monitored packets” and forwarded to the designated “sniffer port.” 0 = no receive monitoring. Transmit Sniff 1 = all packets transmitted on the port are marked as “monitored packets” and forwarded to the designated “sniffer port.” 0 = no transmit monitoring. Reserved
13
0
RW
12
0
RW
11
0
RW
10
1
RW
9
1
RW
8
0
RW
7
0
RW
6
0
RW
5
0
RW
4
0
RW
August 2010
89
M9999-081310-3.1
�Micrel, Inc.
KSZ8862-16/32MQL
Bit 3
Default 0
R/W RW
Description User Priority Ceiling 1 = if the packet’s “priority field” is greater than the “user priority field” in the port VID control register bit[15:13], replace the packet’s “priority field” with the “user priority field” in the port VID control register bit[15:13]. 0 = do no compare and replace the packet’s “priority field.” Port VLAN Membership Define the port’s Port VLAN membership. Bit 2 stands for the host port, bit 1 for port 2, and bit 0 for port 1. The port can only communicate within the membership. A ‘1’ includes a port in the membership; a ‘0’ excludes a port from the membership.
2-0
0x7
RW
Bank 48 Port 1 VID Control Register (0x04): P1VIDCR This register contains the global per port control for the switch function.
Bit 15-13 12 11-0 Default 0x0 0 0x001 R/W RW RW RW Description Default Tag[15:13] Port’s default tag, containing “User Priority Field” bits. Default Tag[12] Port’s default tag, containing CFI bit. Default Tag[11:0] Port’s default tag, containing VID[11:0].
Note: This VID Control register serves two purposes: 1. Associated with the ingress untagged packets, and used for egress tagging. 2. Default VID for the ingress untagged or null-VID-tagged packets, and used for address lookup.
Bank 48 Port 1 Control Register 3 (0x06): P1CR3 Bit
15-5 4 3-2
Default
0x000 0x0 0x0
R/W
RO RW RW
Description
Reserved Reserved Ingress Limit Mode These bits determine what kinds of frames are limited and counted against Ingress limiting as follows: 00 = Limit and count all frames. 01 = Limit and count Broadcast, Multicast, and flooded unicast frames. 10 = Limit and count Broadcast and Multicast frames only. 11 = Limit and count Broadcast frames only. Count IFG Count IFG Bytes. 1= each frame’s minimum inter frame gap. (IFG) bytes (12 per frame) are included in Ingress and Egress rate limiting calculations. 0= IFG bytes are not counted. Count Preamble Count preamble Bytes. 1 = each frame’s preamble bytes (8 per frame) are included in Ingress and Egress rate limiting calculations. 0 = preamble bytes are not counted.
1
0
RW
0
0
RW
August 2010
90
M9999-081310-3.1
�Micrel, Inc. Bank 48 Port 1 Ingress Rate Control Register (0x08): P1IRCR
Bit 15-12 Default 0x0 R/W RW Description
KSZ8862-16/32MQL
Ingress Pri3 Rate Priority 3 frames will be discarded after the ingress rate selected as shown below is reached or exceeded. 0000 = Not limited (default) 0001 = 64Kbps 0010 = 128Kbps 0011 = 256Kbps 0100 = 512Kbps 0101 = 1Mbps 0110 = 2Mbps 0111 = 4Mbps 1000 = 8Mbps 1001 = 16Mbps 1010 = 32Mbps 1011 = 48Mbps 1100 = 64 Mbps 1101 = 72Mbps 1110 = 80Mbps 1111 = 88Mbps Note: For 10BT, rate settings above 10Mbps are set to the default value 0000 (not limited). Ingress Pri2 Rate Priority 2 frames will be discarded after the ingress rate selected as shown below is reached or exceeded. 0000 = Not limited (default) 0001 = 64Kbps 0010 = 128Kbps 0011 = 256Kbps 0100 = 512Kbps 0101 = 1Mbps 0110 = 2Mbps 0111 = 4Mbps 1000 = 8Mbps 1001 = 16Mbps 1010 = 32Mbps 1011 = 48Mbps 1100 = 64 Mbps 1101 = 72Mbps 1110 = 80Mbps 1111 = 88Mbps Note: For 10BT, rate settings above 10Mbps are set to the default value 0000 (not limited).
11-8
0x0
RW
7-4
0x0
RW
Ingress Pri1 Rate Priority 1 frames will be discarded after the ingress rate selected as shown below is reached or exceeded. 0000 = Not limited (default) 0001 = 64Kbps 0010 = 128Kbps 0011 = 256Kbps 0100 = 512Kbps 0101 = 1Mbps
August 2010
91
M9999-081310-3.1
�Micrel, Inc.
Bit Default R/W
KSZ8862-16/32MQL
Description 0110 = 2Mbps 0111 = 4Mbps 1000 = 8Mbps 1001 = 16Mbps 1010 = 32Mbps 1011 = 48Mbps 1100 = 64 Mbps 1101 = 72Mbps 1110 = 80Mbps 1111 = 88Mbps Note: For 10BT, rate settings above 10Mbps are set to the default value 0000 (not limited). Ingress Pri0 Rate Priority 0 frames will be discarded after the ingress rate selected as shown below is reached or exceeded. 0000 = Not limited (default) 0001 = 64Kbps 0010 = 128Kbps 0011 = 256Kbps 0100 = 512Kbps 0101 = 1Mbps 0110 = 2Mbps 0111 = 4Mbps 1000 = 8Mbps 1001 = 16Mbps 1010 = 32Mbps 1011 = 48Mbps 1100 = 64 Mbps 1101 = 72Mbps 1110 = 80Mbps 1111 = 88Mbps Note: For 10BT, rate settings above 10Mbps are set to the default value 0000 (not limited).
3-0
0x0
RW
August 2010
92
M9999-081310-3.1
�Micrel, Inc. Bank 48 Port 1 Egress Rate Control Register (0x0A): P1ERCR
Bit 15-12 Default 0x0 R/W RW Description
KSZ8862-16/32MQL
Egress Pri3 Rate Egress data rate limit for priority 3 frames. Output traffic from this priority queue is shaped according to the egress rate selected below: 0000 = Not limited (default) 0001 = 64Kbps 0010 = 128Kbps 0011 = 256Kbps 0100 = 512Kbps 0101 = 1Mbps 0110 = 2Mbps 0111 = 4Mbps 1000 = 8Mbps 1001 = 16Mbps 1010 = 32Mbps 1011 = 48Mbps 1100 = 64 Mbps 1101 = 72Mbps 1110 = 80Mbps 1111 = 88Mbps Notes: For 10BT, rate settings above 10Mbps are set to the default value 0000 (not limited). When multiple queue select enable is off (only 1 queue per port), rate limiting applies only to priority 0 queue. Egress Pri2 Rate Egress data rate limit for priority 2 frames. Output traffic from this priority queue is shaped according to the egress rate selected below: 0000 = Not limited (default) 0001 = 64Kbps 0010 = 128Kbps 0011 = 256Kbps 0100 = 512Kbps 0101 = 1Mbps 0110 = 2Mbps 0111 = 4Mbps 1000 = 8Mbps 1001 = 16Mbps 1010 = 32Mbps 1011 = 48Mbps 1100 = 64 Mbps 1101 = 72Mbps 1110 = 80Mbps 1111 = 88Mbps Notes: For 10BT, rate settings above 10Mbps are set to the default value 0000 (not limited). When multiple queue select enable is off (only 1 queue per port), rate limiting applies only to priority 0 queue. Egress Pri1 Rate Egress data rate limit for priority 1 frames. Output traffic from this priority queue is shaped according to the egress rate selected below: 0000 = Not limited (default) 0001 = 64Kbps 0010 = 128Kbps 0011 = 256Kbps 0100 = 512Kbps 0101 = 1Mbps
11-8
0x0
RW
7-4
0x0
RW
August 2010
93
M9999-081310-3.1
�Micrel, Inc.
Bit Default R/W Description
KSZ8862-16/32MQL
0110 = 2Mbps 0111 = 4Mbps 1000 = 8Mbps 1001 = 16Mbps 1010 = 32Mbps 1011 = 48Mbps 1100 = 64 Mbps 1101 = 72Mbps 1110 = 80Mbps 1111 = 88Mbps Notes: For 10BT, rate settings above 10Mbps are set to the default value 0000 (not limited). When multiple queue select enable is off (only 1 queue per port), rate limiting applies only to priority 0 queue. 3-0 0x0 RW Egress Pri0 Rate Egress data rate limit for priority 0 frames. Output traffic from this priority queue is shaped according to the egress rate selected below: 0000 = Not limited (default) 0001 = 64Kbps 0010 = 128Kbps 0011 = 256Kbps 0100 = 512Kbps 0101 = 1Mbps 0110 = 2Mbps 0111 = 4Mbps 1000 = 8Mbps 1001 = 16Mbps 1010 = 32Mbps 1011 = 48Mbps 1100 = 64 Mbps 1101 = 72Mbps 1110 = 80Mbps 1111 = 88Mbps Notes: For 10BT, rate settings above 10Mbps are set to the default value 0000 (not limited). When multiple queue select enable is off (only 1 queue per port), rate limiting applies only to priority 0 queue.
August 2010
94
M9999-081310-3.1
�Micrel, Inc. Bank 49 Port 1 PHY Special Control/Status, LinkMD (0x00): P1SCSLMD
Bit 15 14-13 12 11 Default 0 0x0 0 0 R/W RO RO RW RW Description Reserved Reserved Reserved Force_lnk Force link. 1 = force link pass. 0 = normal operation. pwrsave Power-saving. 1 = disable power saving. 0 = enable power saving. Remote (Near-End) Loopback (rlb) 1 = perform remote loopback at Port 1's PHY (RXP1/RXM1 -> TXP1/TXM1, see Figure 15) 0 = normal operation Reserved
®
KSZ8862-16/32MQL
Bit is same as:
Bank 47 0x02 bit 3
10
1
RW
Bank 47 0x02 bit 2
9
0
RW
Bank 47 0x02 bit 1
8-0
0x000
RO
Bank 49 Port 1 Control Register 4 (0x02): P1CR4 This register contains the global per port control for the switch function.
Bit 15 Default 0 R/W RW Description LED Off 1 = Turn off all of the port 1 LEDs (P1LED3, P1LED2, P1LED1, P1LED0). These pins are driven high if this bit is set to one. 0 = normal operation. Txids 1 = disable the port’s transmitter. 0 = normal operation. Restart AN (Note 1) 1 = restart auto-negotiation. 0 = normal operation. Disable Far-End-Fault 1 = disable far-end-fault detection and pattern transmission. 0 = enable far end fault detection and pattern transmission. Power Down 1 = power down. 0 = normal operation. Disable auto MDI/MDI-X 1 = disable auto MDI/MDI-X function. 0 = enable auto MDI/MDI-X function. Force MDI-X 1= if auto MDI/MDI-X is disabled, force PHY into MDI-X mode. 0 = do not force PHY into MDI-X mode. Far-End Loopback 1 = perform loopback, as indicated: Start: RXP2/RXM2 (port 2). Loopback: PMD/PMA of port 1’s PHY. End: TXP2/TXM2 (port 2). 0 = normal operation. Bit is same as: Bank 45 0x00 bit 0
14
0
RW
Bank 45 0x00 bit1
13
0
RW
Bank 45 0x00 bit 9
12
0
RW
Bank 45 0x00 bit 2
11
0
RW
Bank 45 0x00 bit 11
10
0
RW
Bank 45 0x00 bit 3
9
0
RW
Bank 45 0x00 bit 4
8
0
RW
Bank 45 0x00 bit 14
August 2010
95
M9999-081310-3.1
�Micrel, Inc.
Bit 7 Default 1 R/W RW Description Auto Negotiation Enable (Note 1) 1 = auto negotiation is enabled. 0 = disable auto negotiation, speed, and duplex are decided by bits 6 and 5 of the same register. Force Speed 1 = force 100BT if AN is disabled (bit 7). 0 = force 10BT if AN is disabled (bit 7). Force Duplex 1 = force full duplex if (1) AN is disabled or (2) AN is enabled but failed. 0 = force half duplex if (1) AN is disabled or (2) AN is enabled but failed. Advertised flow control capability. 1 = advertise flow control (pause) capability. 0 = suppress flow control (pause) capability from transmission to link partner. Advertised 100BT full-duplex capability. 1 = advertise 100BT full-duplex capability. 0 = suppress 100BT full-duplex capability from transmission to link partner. Advertised 100BT half-duplex capability. 1 = advertise 100BT half-duplex capability. 0 = suppress 100BT half-duplex capability from transmission to link partner. Advertised 10BT full-duplex capability. 1 = advertise 10BT full-duplex capability. 0 = suppress 10BT full-duplex capability from transmission to link partner. Advertised 10BT half-duplex capability. 1 = advertise 10BT half-duplex capability. 0 = suppress 10BT half-duplex capability from transmission to link partner.
KSZ8862-16/32MQL
Bit is same as: Bank 45 0x00 bit 12
6
0
RW
Bank 45 0x00 bit 13
5
0
RW
Bank 45 0x00 bit 8
4
1
RW
Bank 45 0x08 bit 10
3
1
RW
Bank 45 0x08 bit 8
2
1
RW
Bank 45 0x08 bit 7
1
1
RW
Bank 45 0x08 bit 6
0
1
RW
Bank 45 0x08 bit 5
Bank 49 Port 1 Status Register (0x04): P1SR This register contains the global per port status for the switch function.
Bit 15 Default 1 R/W RW Description HP_mdix 1 = HP Auto MDI-X mode. 0 = Micrel Auto MDI-X mode. Reserved Polarity Reverse 1 = polarity is reversed. 0 = polarity is not reversed. Receive Flow Control Enable 1 = receive flow control feature is active. 0 = receive flow control feature is inactive. Transmit Flow Control Enable 1 = transmit flow control feature is active. 0 = transmit flow control feature is inactive. Operation Speed 1 = link speed is 100Mbps. 0 = link speed is 10Mbps. Bank 47 0x02 bit 5 Bit is same as: Bank 45 0x00 bit 5
14 13
0 0
RO RO
12
0
RO
11
0
RO
10
0
RO
August 2010
96
M9999-081310-3.1
�Micrel, Inc.
Bit 9 Default 0 R/W RO Description Operation Duplex 1 = link duplex is full. 0 = link duplex is half. Far-End-Fault 1 = far-end-fault status detected. 0 = no Far-end-fault status detected. MDI-X status 1 = MDI. 0 = MDI-X. Reserved Link Good 1 = link good. 0 = link not good. Partner flow control capability. 1 = link partner flow control (pause) capable. 0 = link partner not flow control (pause) capable. Partner 100BT full-duplex capability. 1 = link partner 100BT full-duplex capable. 0 = link partner not 100BT full-duplex capable. Partner 100BT half-duplex capability. 1 = link partner 100BT half-duplex capable. 0= link partner not 100BT half-duplex capable. Partner 10BT full-duplex capability. 1= link partner 10BT full-duplex capable. 0 = link partner not 10BT full-duplex capable. Partner 10BT half-duplex capability. 1 = link partner 10BT half-duplex capable. 0 = link partner not 10BT half-duplex capable.
KSZ8862-16/32MQL
Bit is same as:
8
0
RO
Bank 45 0x02 bit 4
7
0
RO
Bank 47 0x02 bit 4
6 5
0 0
RO RO
Bank 45 0x02 bit 5 Bank 45 0x02 bit 2
4
0
RO
Bank 45 0x0A bit 10
3
0
RO
Bank 45 0x0A bit 8
2
0
RO
Bank 45 0x0A bit 7
1
0
RO
Bank 45 0x0A bit 6
0
0
RO
Bank 45 0x0A bit 5
Bank 50 Port 2 Control Register 1 (0x00): P2CR1 This register contains the global per port control for the switch function. See description in P1CR1, Bank 48 (0x00) Bank 50 Port 2 Control Register 2 (0x02): P2CR2 This register contains the global per port control for the switch function. See description in P1CR2, Bank 48 (0x02) Bank 50 Port 2 VID Control Register (0x04): P2VIDCR This register contains the global per port control for the switch function. See description in P1VIDCR, Bank 48 (0x04) Bank 50 Port 2 Control Register 3 (0x06): P2CR3 This register contains the global per port control for the switch function. See description in P1CR3, Bank 48 (0x06) Bank 50 Port 2 Ingress Rate Control Register (0x08): P2IRCR This register contains per port ingress rate control. See description in P1IRCR, Bank 48 (0x08) Bank 50 Port 2 Egress Rate Control Register (0x0A): P2ERCR This register contains per port egress rate control. See description in P1ERCR, Bank 48 (0x0A)
August 2010
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M9999-081310-3.1
�Micrel, Inc. Bank 51 Port 2 PHY Special Control/Status, LinkMD (0x00): P2SCSLMD
Bit 15 14-13 Default 0 0x0 R/W RO RO Description Vct_10m_short 1 = Less than 10 meter short. Vct_result VCT result. [00] = normal condition. [01] = open condition has been detected in the cable. [10] = short condition has been detected in the cable. [11] = cable diagnostic test has failed. Vct_en VCT enable. 1 = the cable diagnostic test is enabled. It is self-cleared after the VCT test is done. 0 = it indicates the cable diagnostic test is completed and the status information is valid for read Force_lnk Force link. 1 = force link pass. 0 = normal operation. Pwrsave Power-saving. 1 = disable power saving. 0 = enable power saving. Remote (Near-End) Loopback (rlb) 1 = perform remote loopback at Port 2's PHY (RXP2/RXM2 -> TXP2/TXM2, see Figure 15) 0 = normal operation Vct_fault_count VCT fault count. The distance to the fault is approximately 0.4m*vct_fault_count.
®
KSZ8862-16/32MQL
Bit is same as: Bank 47 0x04 bit 12 Bank 47 0x04 bit 14-13
12
0
RW SC
Bank 47 0x04 bit 15
11
0
RW
Bank 47 0x06 bit 3
10
1
RW
Bank 47 0x06 bit 2
9
0
RW
Bank 47 0x06 bit 1
8-0
0x000
RO
Bank 47 0x04 bit 8-0
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�Micrel, Inc. Bank 51 Port 2 Control Register 4 (0x02): P2CR4 This register contains the global per port control for the switch function.
Bit 15 Default 0 R/W RW Description LED Off 1 = turn off all of the port 2 LEDs (P2LED3, P2LED2, P2LED1, P2LED0). These pins are driven High if this bit is set to 1. 0 = normal operation. Txids 1 = disable port’s transmitter. 0 = normal operation. Restart AN 1 = restart auto-negotiation. 0 = normal operation. Reserved Power Down 1 = power-down. 0 = normal operation. Disable Auto MDI/MDI-X 1= disable auto MDI/MDI-X function. 0= enable auto MDI/MDI-X function. Force MDI-X 1 = if auto MDI/MDI-X is disabled, force PHY into MDI-X mode. 0 = do not force PHY into MDI-X mode. Far-End Loopback 1 = perform loopback, as indicated (see Figure 14): Start: RXP1/RXM1 (port 1). Loopback: PMD/PMA of port 2’s PHY. End: TXP1/TXM1 (port 1). 0 = normal operation. Auto Negotiation Enable 0 = disable auto negotiation, speed and duplex are decided by bits 6 and 5 of the same register. 1 = auto negotiation is ON. Force Speed 1 = force 100BT if AN is disabled (bit 7). 0 = force 10BT if AN is disabled (bit 7). Force Duplex 1 = force full duplex if (1) AN is disabled or (2) AN is enabled but failed. 0 = force half duplex if (1) AN is disabled or (2) AN is enabled but failed. Advertised flow control capability. 1 = advertise flow control (pause) capability. 0 = suppress flow control (pause) capability from transmission to the link partner. Advertised 100BT Full-duplex capability. 1 = advertise 100BT full-duplex capability. 0 = suppress 100BT full-duplex capability from transmission to the link partner. Advertised 100BT half-duplex capability. 1 = advertise 100BT half-duplex capability. 1 = suppress 100BT half-duplex capability from transmission to the link partner.
KSZ8862-16/32MQL
Bit is same as: Bank 46 0x00 bit 0
14
0
RW
Bank 46 0x00 bit 1
13
0
RW
Bank 46 0x00 bit 9
12 11
0 0
RW RW
Bank 46 0x00 bit 2 Bank 46 0x00 bit 11
10
0
RW
Bank 46 0x00 bit 3
9
0
RW
Bank 46 0x00 bit 4
8
0
RW
Bank 46 0x00 bit 14
7
1
RW
Bank 46 0x00 bit 12
6
0
RW
Bank 46 0x00 bit 13
5
0
RW
Bank 46 0x00 bit 8
4
1
RW
Bank 46 0x08 bit 10
3
1
RW
Bank 46 0x08 bit 8
2
1
RW
Bank 46 0x08 bit 7
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Bit 1
Default 1
R/W RW
Description Advertised 10BT full-duplex capability. 1 = advertise 10BT full-duplex capability. 0 = suppress 10BT full-duplex capability from transmission to the link partner. Advertised 10BT half-duplex capability. 1 = advertise 10BT half-duplex capability. 0 = suppress 10BT half-duplex capability from transmission to the link partner.
Bit is same as: Bank 46 0x08 bit 6
0
1
RW
Bank 46 0x08 bit 5
Bank 51 Port 2 Status Register (0x04): P2SR This register contains the global per port status for the switch function.
Bit 15 Default 1 R/W RW Description HP_mdix 1 = HP Auto MDI-X mode. 0 = Micrel Auto MDI-X mode. Reserved Polarity Reverse 1 = polarity is reversed. 0 = polarity is not reversed. Receive Flow Control Enable 1 = receive flow control feature is active. 0 = receive flow control feature is inactive. Transmit Flow Control Enable 1 = transmit flow control feature is active. 0 = transmit flow control feature is inactive. Operation Speed 1 = link speed is 100Mbps. 0 = link speed is 10Mbps. Operation Duplex 1 = link duplex is full. 0 = link duplex is half. Reserved MDI-X Status 1 = MDI. 0 = MDI-X. AN Done 1 = AN done. 0 = AN not done. Link Good 1 = link good. 0 = link not good. Partner flow control capability. 1 = link partner flow control (pause) capable. 0 = link partner not flow control (pause) capable. Partner 100BT full-duplex capability. 1 = link partner 100BT full-duplex capable. 0 = link partner not 100BT full-duplex capable. Bank 46 0x02 bit 4 Bank 47 0x06 bit 4 Bank 47 0x06 bit 5 Bit is same as: Bank 46 0x00 bit 5
14 13
0 0
RO RO
12
0
RO
11
0
RO
10
0
RO
9
0
RO
8 7
0 0
RO RO
6
0
RO
Bank 46 0x02 bit 5
5
0
RO
Bank 46 0x02 bit 2
4
0
RO
Bank 46 0x0A bit 10
3
0
RO
Bank 46 0x0A bit 8
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Bit 2
Default 0
R/W RO
Description Partner 100BT half duplex capability. 1 = link partner 100BT half-duplex capable. 0 = link partner not 100BT half-duplex capable. Partner 10BT full-duplex capability. 1 = link partner 10BT full-duplex capable. 0 = link partner not 10BT full-duplex capable. Partner 10BT half-duplex capability. 1 = link partner 10BT half-duplex capable. 0 = link partner not 10BT half-duplex capable.
Bit is same as: Bank 46 0x0A bit 7
1
0
RO
Bank 46 0x0A bit 6
0
0
RO
Bank 46 0x0A bit 5
Bank 52 Host Port Control Register 1 (0x00): P3CR1 This register contains the global per port control for the switch function. See description in P1CR1, Bank 48 (0x00) Bank 52 Host Port Control Register 2 (0x02): P3CR2 This register contains the global per port control for the switch function.
Bit 15 14 Default 0 0 RW R/W Description Reserved Ingress VLAN Filtering 1 = the switch discards packets whose VID port membership in VLAN table bits [18:16] does not include the ingress port. 0 = no ingress VLAN filtering. Discard Non PVID Packets 1 = the switch discards packets whose VID does not match the ingress port default VID. 0 = no packets are discarded. Reserved Reserved Transmit Enable 1 = enable packet transmission on the port. 0 = disable packet transmission on the port. Receive Enable 1 = enable packet reception on the port. 0 = disable packet reception on the port. Learning Disable 1 = disable switch address learning capability. 0 = enable switch address learning. Sniffer Port 1 = port is designated as the sniffer port and transmits packets that are monitored. 0 = port is a normal port. Receive Sniff 1 = all packets received on the port are marked as “monitored packets” and forwarded to the designated “sniffer port”. 0 = no receive monitoring. Transmit Sniff 1 = all packets transmitted on the port are marked as “monitored packets” and forwarded to the designated “sniffer port”. 0 = no transmit monitoring. Reserved
13
0
RW
12 11 10
0 0 1
RO RO RW
9
1
RW
8
0
RW
7
0
RW
6
0
RW
5
0
RW
4
0
RW
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Bit 3 Default 0 R/W RW Description
KSZ8862-16/32MQL
User Priority Ceiling 1 = if the packet’s “user priority field” is greater than the “user priority field” in the port default tag register, replace the packet’s “user priority field” with the “user priority field” in the port default tag register. 0 = do no compare and replace the packet’s ‘user priority field.” Port VLAN Membership Define the port’s Port VLAN membership. Bit 2 stands for host port, bit 1 for port 2, and bit 0 for port 1. The port can only communicate within the membership. A ‘1’ includes a port in the membership; a ‘0’ excludes a port from the membership.
2-0
0x7
RW
Bank 52 Host Port VID Control Register (0x04): P3VIDCR This register contains the global per port control for the switch function. See description in P1VIDCR, Bank 48 (0x04) Bank 52 Host Port Control Register 3 (0x06): P3CR3 This register contains the global per port control for the switch function. See description in P1CR3, Bank 48 (0x06) Bank 52 Host Port Ingress Rate Control Register (0x08): P3IRCR This register contains per port ingress rate control. See description in P1IRCR, Bank 48 (0x08) Bank 52 Host Port Egress Rate Control Register (0x0A): P3ERCR This register contains per port egress rate control. See description in P1ERCR, Bank 48 (0x0A) Banks 53 – 63: Reserved Except Bank Select Register (0xE)
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MIB (Management Information Base) Counters
The KSZ8862M provides 34 MIB counters for each port. These counters are used to monitor the port activity for network management. The MIB counters are formatted “per port” as shown in Table 14 and “all ports dropped packet” as shown in Table 16.
Bit 31 30 29-0 Name Overflow Count valid Counter values R/W RO RO RO Description 1: counter overflow. 0: no counter overflow. 1: counter value is valid. 0: counter value is not valid. Counter value (read clear) Table 14. Format of Per Port MIB Counters Default 0 0 0x00000000
“Per Port” MIB counters are read using indirect memory access. The base address offsets and address ranges for both Ethernet ports are: Port 1, base address is 0x00 and range is from 0x00 to 0x1f. Port 2, base address is 0x20 and range is from 0x20 to 0x3f. Per port MIB counters are read using indirect access control register in IACR, Bank 42 (0x00) and indirect access data registers in IADR4[15:0], IADR5[31:16]. Table 15 shows the port 1 MIB counters address memory offset.
Offset 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 0x8 0x9 0xA 0xB 0xC 0xD 0xE 0xF 0x10 0x11 0x12 Counter Name RxLoPriorityByte RxHiPriorityByte RxUndersizePkt RxFragments RxOversize RxJabbers RxSymbolError RxCRCError RxAlignmentError RxControl8808Pkts RxPausePkts RxBroadcast RxMulticast RxUnicast Rx64Octets Rx65to127Octets Rx128to255Octets Rx256to511Octets Rx512to1023Octets Description Rx lo-priority (default) octet count including bad packets Rx hi-priority octet count including bad packets Rx undersize packets w/ good CRC Rx fragment packets w/ bad CRC, symbol errors or alignment errors Rx oversize packets w/ good CRC (max: 1536 or 1522 bytes) Rx packets longer than 1522 bytes w/ either CRC errors, alignment errors, or symbol errors (depends on max packet size setting) Rx packets w/ invalid data symbol and legal packet size. Rx packets within (64,1522) bytes w/ an integral number of bytes and a bad CRC (upper limit depends on max packet size setting) Rx packets within (64,1522) bytes w/ a non-integral number of bytes and a bad CRC (upper limit depends on max packet size setting) Number of MAC control frames received by a port with 88-08h in EtherType field Number of PAUSE frames received by a port. PAUSE frame is qualified with EtherType (88-08h), DA, control opcode (00-01), data length (64B min), and a valid CRC Rx good broadcast packets (not including error broadcast packets or valid multicast packets) Rx good multicast packets (not including MAC control frames, error multicast packets or valid broadcast packets) Rx good unicast packets Total Rx packets (bad packets included) that were 64 octets in length Total Rx packets (bad packets included) that are between 65 and 127 octets in length Total Rx packets (bad packets included) that are between 128 and 255 octets in length Total Rx packets (bad packets included) that are between 256 and 511 octets in length Total Rx packets (bad packets included) that are between 512 and 1023 octets in length
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Offset 0x13 0x14 0x15 0x16 0x17 0x18 0x19 0x1A 0x1B 0x1C 0x1D 0x1E 0x1F Counter Name Rx1024to1522Octets TxLoPriorityByte TxHiPriorityByte TxLateCollision TxPausePkts TxBroadcastPkts TxMulticastPkts TxUnicastPkts TxDeferred TxTotalCollision TxExcessiveCollision TxSingleCollision TxMultipleCollision Description
KSZ8862-16/32MQL
Total Rx packets (bad packets included) that are between 1024 and 1522 octets in length (upper limit depends on max packet size setting) Tx lo-priority good octet count, including PAUSE packets Tx hi-priority good octet count, including PAUSE packets The number of times a collision is detected later than 512 bit-times into the Tx of a packet Number of PAUSE frames transmitted by a port Tx good broadcast packets (not including error broadcast or valid multicast packets) Tx good multicast packets (not including error multicast packets or valid broadcast packets) Tx good unicast packets Tx packets by a port for which the 1st Tx attempt is delayed due to the busy medium Tx total collision, half duplex only A count of frames for which Tx fails due to excessive collisions Successfully Tx frames on a port for which Tx is inhibited by exactly one collision Successfully Tx frames on a port for which Tx is inhibited by more than one collision Table 15. Port 1 MIB Counters Indirect Memory Offset
Format of “All Ports Dropped Packet” MIB Counters
Bit 30-16 15-0 Default 0x0000 R/W N/A RO Description Reserved Counter Value
Table 16. “All Ports Dropped Packet” MIB Counters Format
Note: “All Ports Dropped Packet” MIB Counters do not indicate overflow or validity; therefore, the application must keep track of overflow and valid conditions.
“All Ports Dropped Packet” MIB counters are read using indirect memory access. The address offsets for these counters are shown in Table 17.
Offset 0x100 0x101 0x103 0x104 Counter Name Port1 TX Drop Packets Port2 TX Drop Packets Port1 RX Drop Packets Port2 RX Drop Packets Description TX packets dropped due to lack of resources TX packets dropped due to lack of resources RX packets dropped due to lack of resources RX packets dropped due to lack of resources
Table 17. “All Ports Dropped Packet” MIB Counters Indirect Memory Offsets
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Examples: 1. MIB Counter Read (read port 1 “Rx64Octets” counter at indirect address offset 0x0E) W rite to reg. IACR with 0x1c0e (set indirect address and trigger a read MIB counters operation) Then Read reg. IADR5 (MIB counter value 31-16) // If bit 31 = 1, there was a counter overflow // If bit 30 = 0, restart (reread) from this register Read reg. IADR4 (MIB counter value 15-0) 2. MIB Counter Read (read port 2 “Rx64Octets” counter at indirect address offset 0x2E) W rite to reg. IACR with 0x1c2e (set indirect address and trigger a read MIB counters operation) Then Read reg. IADR5 (MIB counter value 31-16) // If bit 31 = 1, there was a counter overflow // If bit 30 = 0, restart (reread) from this register Read reg. IADR4 (MIB counter value 15-0) 3. MIB Counter Read (read “Port1 TX Drop Packets” counter at indirect address offset 0x100) W rite to reg. IACR with 0x1d00 (set indirect address and trigger a read MIB counters operation) Then Read reg. IADR4 (MIB counter value 15-0)
Additional MIB Information Per Port MIB counters are designed as “read clear”. That is, these counters will be cleared after they are read. All Ports Dropped Packet MIB counters are not cleared after they are accessed. The application needs to keep track of overflow and valid conditions on these counters.
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Static MAC Address Table
The KSZ8862M supports both a static and a dynamic MAC address table. In response to a Destination Address (DA) look up, The KSZ8862M searches both tables to make a packet forwarding decision. In response to a Source Address (SA) look up, only the dynamic table is searched for aging, migration and learning purposes. The static DA look up result takes precedence over the dynamic DA look up result. If there is a DA match in both tables, the result from the static table is used. These entries in the static table will not be aged out by the KSZ8862M.
Bit 57-54 53 Default Value 0000 0 R/W RW R/W Description FID Filter VLAN ID - identifies one of the 16 active VLANs. Use FID 1: specifies the useof FID+MAC for static table look ups 0: specifies only the use of MAC for static table look ups Override 1: overrides the port setting “transmit enable = 0” or “receive enable = 0” setting. 0: specifies no override Valid 1: specifies that this entry is valid, the look up result will be used 0: specifies that this entry is not valid Forwarding ports These 3 bits control the forwarding port(s): 000: no forward 001: forward to port 1 010: forward to port 2 100: forward to port 3 011: forward to port 1 and port 2 110: forward to port 2 and port 3 101: forward to port 1 and port 3 111: broadcasting (excluding the ingress port) MAC address 48 bits MAC Address Table 18. Static MAC Table Format (8 Entries)
52
0
R/W
51
0
R/W
50-48
000
R/W
47-0
0
R/W
Static MAC Table Lookup Examples: 1. Static Address Table Read (read the second entry at indirect address offset 0x01) W rite to reg. IACR with 0x1001 (set indirect address and trigger a read static MAC table operation) Then Read reg. IADR3 (static MAC table bits 57-48) Read reg. IADR2 (static MAC table bits 47-32) Read reg. IADR5 (static MAC table bits 31-16) Read reg. IADR4 (static MAC table bits 15-0) 2. Static Address Table Write (write the eighth entry at indirect address offset 0x07) W rite to reg. IADR3 (static MAC table bits 57-48) Write to reg. IADR2 (static MAC table bits 47-32) Write to reg. IADR5 (static MAC table bits 31-16) Write to reg. IADR4 (static MAC table bits 15-0) Write to reg. IACR with 0x0007 (set indirect address and trigger a write static MAC table operation) August 2010 106 M9999-081310-3.1
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Dynamic MAC Address Table
The Dynamic MAC address is a read only table.
Bit 71 Default Value R/W RO Description Data not ready 1: specifies that the entry is not ready, continue retrying until bit is set to 0 0: specifies that the entry is ready Reserved MAC empty 1: specifies that there is no valid entry in the table 0: specifies that there are valid entries in the table No of valid entries Indicates how many valid entries in the table 0x3ff means 1 K entries 0x001 means 2 entries 0x000 and bit 66 = 0 means 1 entry 0x000 and bit 66 = 1 means 0 entry Time Stamp Specifies the 2-bit counter for internal aging. Source port Identifies the source port where FID+MAC is learned: 00: port 1 01: port 2 10: port 3 FID Specifies the filter ID. MAC Address Specifies the 48-bit MAC address.
70-67 66 1
RO RO
65-56
0x000
RO
55-54 53-52 00
RO RO
51-48 47-0
0x0 0x0000_0000_0000
RO RO
Table 19. Dynamic MAC Address Table Format (1024 Entries)
Dynamic MAC Address Lookup Example: Dynamic MAC Address Table Read (read the first entry at indirect address offset 0 and retrieve the MAC table size) W rite to reg. IACR with 0x1800 (set indirect address and trigger a read dynamic MAC table operation) Then Read reg. IADR1 (dynamic MAC table bits 71-64) // If bit 71 = 1, restart (reread) from this register Read reg. IADR3 (dynamic MAC table bits 63-48) Read reg. IADR2 (dynamic MAC table bits 47-32) Read reg. IADR5 (dynamic MAC table bits 31-16) Read reg. IADR4 (dynamic MAC table bits 15-0)
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VLAN Table
The KSZ8862M uses the VLAN table to perform look-ups. If 802.1Q VLAN mode is enabled (SGCR2[15]), this table will be used to retrieve the VLAN information that is associated with the ingress packet. This information includes FID (filter ID), VID (VLAN ID), and VLAN membership as described in Table 20:
Bit 19 Default Value 1 R/W RW Description Valid 1: specifies that this entry is valid, the look up result will be used 0: specifies that this entry is not valid Membership Specifies which ports are members of the VLAN. If a DA look up fails (no match in both static and dynamic tables), the packet associated with this VLAN will be forwarded to ports specified in this field. For example: 101 means port 3 and 1 are in this VLAN. FID Specifies the Filter ID. The KSZ8862M supports 16 active VLANs represented by these four bit fields. The FID is the mapped ID. If 802.1Q VLAN is enabled, the look up will be based on FID+DA and FID+SA. VID Specifies the IEEE 802.1Q 12 bits VLAN ID. Table 20. VLAN Table Format (16 Entries)
18-16
111
R/W
15-12
0x0
R/W
11-0
0x001
R/W
If 802.1Q VLAN mode is enabled, then the KSZ8862M will assign a VID to every ingress packet. If the packet is untagged or tagged with a null VID, then the packet is assigned with the default port VID of the ingress port. If the packet is tagged with non null VID, the VID in the tag will be used. The look up process will start from the VLAN table look up. If the VID is not valid, the packet will be dropped and no address learning will take place. If the VID is valid, the FID is retrieved. The FID+DA and FID+SA lookups are performed. The FID+DA look up determines the forwarding ports. If FID+DA fails, the packet will be broadcast to all the members (excluding the ingress port) of the VLAN. If FID+SA fail, the FID+SA will be learned. VLAN Table Lookup Examples: Examples: 1. VLAN Table Read (read the third entry, at the indirect address offset 0x02) W rite to reg. IACR with 0x1402 (set indirect address and trigger a read VLAN table operation) Then Read reg. IADR5 (VLAN table bits 19-16) Read reg. IADR4 (VLAN table bits 15-0) 2. VLAN Table Write (write the seventh entry, at the indirect address offset 0x06) W rite to reg. IADR5 (VLAN table bits 19-16) Write to reg. IADR4 (VLAN table bits 15-0) Write to reg. IACR with 0x1406 (set indirect address and trigger a read VLAN table operation)
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Absolute Maximum Ratings(1)
Description Supply Voltage Input Voltage Output Voltage Lead Temperature (soldering, 10 sec) Storage Temperature (Ts) Pins VDDATX, VDDARX, VDDIO All Inputs All Outputs N/A N/A Value –0.5V to 4.0V –0.5V to 5V –0.5V to 4.0V 270°C –55°C to 150°C Table 21. Maximum Ratings
Note: Exceeding the absolute maximum rating may damage the device. Stresses greater than those listed in the table above may cause permanent damage to the device. Operation of the device at these or any other conditions above those specified in the operating sections of this specification is not implied. Maximum conditions for extended periods may affect reliability. Unused inputs must always be tied to an appropriate logic voltage level.
Operating Ratings(1)
Parameter Supply Voltages Ambient Operating Temperature Maximum Junction Temperature Thermal Resistance Junction to (2) Ambient Thermal Resistance Junction to (2) Case Symbol VDDATX,VDDARX VDDIO TA TJ θJA θJC Table 22. Operating Ratings
Notes: 1. The device is not guaranteed to function outside its operating rating. Unused inputs must always be tied to an appropriate logic voltage level (Ground to VDD). 2. No (HS) heat spreader in this package. The θJC/θJA is under air velocity 0 m/s.
Min 3.1V 3.1V 0 °C
Typ 3.3V 3.3V
Max 3.5V 3.5V +70°C +125°C
42.91 °C/W 19.6 °C/W
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Electrical Characteristics(1)
Parameter 100BASE-TX /SX/FX (analog core + PLL + digital core + transceiver + digital I/O) 10BASE-T/FL (analog core + PLL + digital core + transceiver + digital I/O) TTL Inputs Input High Voltage Input Low Voltage Input Current TTL Outputs Output High Voltage Output Low Voltage Output Tri-state Leakage Voh Vol |Ioz| Vo Vimb Tr/Tf 100Ω termination on the differential output. 100Ω termination on the differential output 3ns 0ns +0.95V Ioh = -8 mA Iol = 8 mA 2.4V 0.4V 10µA +1.05V 2% 5ns 0.5ns +0.25ns 5% Vset Peak to peak Vo 100Ω termination on the differential output Peak to peak IFO (+/- 5%) V10FL V100SX Vsq VDDATX, VDDARX, VDDIO = 3.3V RMS RMS 5MHz square wave 40mA 2.5mV 16mV 400mV 0.5V 0.7ns 2.4V 1.8ns 60mA 3.5ns 97mA 1.4ns Vih V
il
Symbol
Condition
Min
Typ
Max
Supply Current for 100BASE-SX/FX and 100BASE-TX Operation (All Ports@ Full Duplex and 100% Utilization) Iddxio VDDATX, VDDARX, VDDIO = 3.3V 153mA
Supply Current for 10BASE-FL and 10BASE-T Operation (All Ports@Full Duplex and 100% Utilization) Iddxio VDDATX, VDDARX, VDDIO = 3.3V 97mA
2.0V 0.8V Vin = GND ~ VDDIO -10µA 10µA
Iin
100Base-TX Transmit (measured differentially after 1:1 transformer) Peak Differential Output Voltage Output Voltage Imbalance Rise/Fall Time Rise/Fall Time Imbalance Duty Cycle Distortion Overshoot Reference Voltage of ISET Output Jitter Peak Differential Output Voltage Output Jitter 10Base-FL/100Base-SX Transmit Transmit ouput current on pin TXM1 10Base-FL Receive on pin RXM1 Signal detect assertion threshold 100Base-SX Receive on pin RXM1 Signal detect assertion threshold 10Base-T Receive Squelch Threshold
10Base-T Transmit (measured differentially after 1:1 transformer)
Note 1: TA = 25°C, specification for packaged product only. Note 2: Port 2’s transformer consumes an additional 45mA @ 3.3V for 100BASE-TX and 70mA @ 3.3V for 10BASE-T.
Table 23. Electrical Characteristics
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Timing Specifications
Asynchronous Timing without using Address Strobe (ADSN = 0)
t2 Addr, AEN, BExN ADSN t3 Read Data t1 RDN, WRN t6 W rite Data t7 ARDY (Read Cycle) ARDY ( W rite Cycle) t9 t8 t10
valid valid valid
t4
t5
Figure 14. Asynchronous Cycle – ADSN = 0
Symbol t1 t2
Parameter A1-A15, AEN, BExN[3:0] valid to RDN, WRN active A1-A15, AEN, BExN[3:0] hold after RDN inactive (assume ADSN tied Low) A1-A15, AEN, BExN[3:0] hold after WRN inactive (assume ADSN tied Low)
Min 0 0 1
Typ
Max
Unit ns ns ns
t3 t4 t5 t6 t7 t8 t9
Read data valid to ARDY rising Read data to hold RDN inactive Write data setup to WRN inactive Write data hold after WRN inactive Read active to ARDY Low Write inactive to ARDY Low ARDY low (wait time) in read cycle (Note1) (It is 0ns to read bank select register and 40ns to read QMU data register in turbo mode) (Note2) ARDY low (wait time) in read cycle (Note1) (It is 0ns to read bank select register and 80ns to read QMU data register in normal mode) 0 40 4 4 2
0.8
ns ns ns ns
8 8
ns ns ns
0
80
ns
t10
ARDY low (wait time) in write cycle (Note1) (It is 0ns to write bank select register) (It is 36ns to write QMU data register)
0
50
ns
Note1: When CPU finished current Read or Write operation, it can do next Read or Write operation even the ARDY is low. During Read or Write operation if the ADRY is low, the CPU has to keep the RDN/WRN low until the ARDY returns to high. Note2: In order to speed up the ARDY low time to 40 ns, user has to use the turbo software driver which is only supported in the A6 device. Please refer to the “KSZ88xx Programmer's Guide” for detail.
Table 24. Asynchronous Cycle (ADSN = 0) Timing Parameters
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t8 Addr, AEN, BExN
valid
KSZ8862-16/32MQL
t6 ADSN Read Data t1 RDN, WRN t5 W rite Data t7 ARDY (Read Cycle) ARDY ( W rite Cycle) t10 t9 t11
valid valid
t4
t3
t2
Figure 15. Asynchronous Cycle – Using ADSN
Symbol t1 t2 t3 t4 t5 t6 t7 t8 t9 t10
Parameter A1-A15, AEN, BExN[3:0] valid to RDN, WRN active Read data valid to ARDY rising Read data hold to RDN inactive Write data setup to WRN inactive Write data hold after WRN inactive A1-A15, AEN, nBE[3:0] setup to ADSN rising Read active to ARDY Low A1-A15, AEN, BExN[3:0] hold after ADSN rising Write inactive to ARDY Low ARDY low (wait time) in read cycle (Note1) (It is 0ns to read bank select register and 40ns to read QMU data register in turbo mode) (Note2) ARDY low (wait time) in read cycle (Note1) (It is 0ns to read bank select register and 80ns to read QMU data register in normal mode) ARDY low (wait time) in write cycle (Note1) (It is 0ns to write bank select register) (It is 36ns to write QMU data register)
Min 0
Typ
Max 0.8
Unit ns ns ns ns ns ns
4 4 2 4 8 2 8 0 40
ns ns ns ns
0
80
ns
t11
0
50
ns
Note1: When CPU finished current Read or Write operation, it can do next Read or Write operation even the ARDY is low. During Read or Write operation if the ADRY is low, the CPU has to keep the RDN/WRN low until the ARDY returns to high. Note2: In order to speed up the ARDY low time to 40 ns, user has to use the turbo software driver which is only supported in the A6 device. Please refer to the “KSZ88xx Programmer's Guide” for detail.
Table 25. Asynchronous Cycle using ADSN Timing Parameters
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Asynchronous Timing Using DATACSN
t2 DATACSN Read Data t1 RDN, WRN t6 W rite Data t7 ARDY (Read Cycle) ARDY ( W rite Cycle) t9 t8 t10 t3
valid valid
t5
t4
Figure 16. Asynchronous Cycle – Using DATACSN
Symbol t1 t2 t3 t4 t5 t6 t7 t8 t9
Parameter DATACSN setup to RDN, WRN active DATACSN hold after RDN, WRN inactive (assume ADSN tied Low) Read data hold to ARDY rising Read data to RDN hold Write data setup to WRN inactive Write data hold after WRN inactive Read active to ARDY Low Write inactive to ARDY Low ARDY low (wait time) in read cycle (Note1) (It is 0ns to read bank select register and 40ns to read QMU data register in turbo mode) (Note2) ARDY low (wait time) in read cycle (Note1) (It is 0ns to read bank select register and 80ns to read QMU data register in normal mode) ARDY low (wait time) in write cycle (Note1) (It is 0ns to write bank select register) (It is 36ns to write QMU data register)
Min 2 0
Typ
Max
Unit ns ns
0.8 4 4 2 8 8 0 40
ns ns ns ns ns ns ns
0
80
ns
t10
0
50
ns
Note 1: When CPU finished current Read or Write operation, it can do next Read or Write operation even the ARDY is low. During Read or Write operation if the ADRY is low, the CPU has to keep the RDN/WRN low until the ARDY returns to high. Note2: In order to speed up the ARDY low time to 40 ns, user has to use the turbo software driver which is only supported in the A6 device. Please refer to the “KSZ88xx Programmer's Guide” for detail.
Table 26. Asynchronous Cycle using DATACSN Timing Parameters
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Address Latching Timing for All Modes
t1 ADSN t2 Address, AEN, BExN t3 LDEVN
Figure 17. Address Latching Cycle for All Modes
Symbol t1 t2 t3
Parameter A1-A15, AEN, BExN[3:0] setup to ADSN A1-A15, AEN, BExN[3:0] hold after ADSN rising A4-A15, AEN to LDEVN delay
Min 4 2
Typ
Max
Unit ns ns
5
ns
Table 27. Address Latching Timing Parameters
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�Micrel, Inc. Synchronous Timing in Burst Write (VLBUSN = 1)
KSZ8862-16/32MQL
Figure 18. Synchronous Burst Write Cycles – VLBUSN = 1
Symbol t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 t12
Parameter SWR setup to BCLK falling DATDCSN setup to BCLK rising CYCLEN setup to BCLK rising Write data setup to BCLK rising Write data hold to BCLK rising RDYRTNN setup to BCLK falling RDYRTNN hold to BCLK falling SRDYN setup to BCLK rising SRDYN hold to BCLK rising DATACSN hold to BCLK rising SWR hold to BCLK falling CYCLEN hold to BCLK rising
Min 4 4 4 6 2 5 3 4 3 2 2 2
Typ
Max
Unit ns ns ns ns ns ns ns ns ns ns ns ns
Table 28. Synchronous Burst Write Timing Parameters
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BCLK t2 DATACSN t1 SWR t3 CYCLEN t5 t4 Read Data
data0 data1 data2 data3
KSZ8862-16/32MQL
t10
t11 t12
t7 t6 RDYRTNN t8 SRDYN t9
Figure 19. Synchronous Burst Read Cycles – VLBUSN = 1
Symbol t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 t12
Parameter SWR setup to BCLK falling DATDCSN setup to BCLK rising CYCLEN setup to BCLK rising Read data setup to BCLK rising Read data hold to BCLK rising RDYRTNN setup to BCLK falling RDYRTNN hold to BCLK falling SRDYN setup to BCLK rising SRDYN hold to BCLK rising DATACSN hold to BCLK rising SWR hold to BCLK falling CYCLEN hold to BCLK rising
Min 4 4 4 6 2 5 3 4 3 2 2 2
Typ
Max
Unit ns ns ns ns ns ns ns ns ns ns ns ns
Table 29. Synchronous Burst Read Timing Parameters
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�Micrel, Inc. Synchronous Write Timing (VLBUSN = 0)
BCLK t2 Address, AEN, BExN
valid
KSZ8862-16/32MQL
t1 ADSN t5 SWR t4 t3 CYCLEN t7 Write Data t9 SRDYN t11 RDYRTNN t12
valid
t6
t8
t10
Figure 20. Synchronous Write Cycle – VLBUSN = 0
Symbol t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 t12
Parameter A1-A15, AEN, BExN[3:0] setup to ADSN rising A1-A15, AEN, BExN[3:0] hold after ADSN rising CYCLEN setup to BCLK rising CYCLEN hold after BCLK rising (non-burst mode) SWR setup to BCLK SWR hold after BCLK rising with SRDYN active Write data setup to BCLK rising Write data hold from BCLK rising SRDYN setup to BCLK SRDYN hold to BCLK RDYRTNN setup to BCLK RDYRTNN hold to BCLK
Min 4 2 4 2 4 0 5 1 8 1 4 1
Typ
Max
Unit ns ns ns ns ns ns ns ns ns ns ns ns
Table 30. Synchronous Write (VLBUSN = 0) Timing Parameters
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BCLK t2 Address, AEN, BExN
valid
KSZ8862-16/32MQL
t1 ADSN t5 SWR t4 t3 CYCLEN t7 Read Data
valid
t6
t8 SRDYN t10 RDYRTNN
t9
t11
Figure 21. Synchronous Read Cycle – VLBUSN = 0
Symbol t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11
Parameter A1-A15, AEN, BExN[3:0] setup to ADSN rising A1-A15, AEN, BExN[3:0] hold after ADSN rising CYCLEN setup to BCLK rising CYCLEN hold after BCLK rising (non-burst mode) SWR setup to BCLK Read data hold from BCLK rising Read data setup to BCLK SRDYN setup to BCLK SRDYN hold to BCLK RDYRTNN setup to BCLK rising RDYRTNN hold after BCLK rising
Min 4 2 4 2 4 1 8 8 1 4 1
Typ
Max
Unit ns ns ns ns ns ns ns ns ns ns ns
Table 31. Synchronous Read (VLBUSN = 0) Timing Parameters
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EEPROM Timing
EECS *1 EESK 1
tcyc
EEDO
11 High-Z
0
An
A0
ts
th
EEDI
D15
D14
D13
D1
D0
*1 Start bit
Figure 22. EEPROM Read Cycle Timing Diagram
Timing Parameter tcyc
Description Clock cycle
Min
Typ 4 (OBCR[1:0]=11 on-chip bus speed @ 25 MHz) or 0.8 (OBCR[1:0]=00 on-chip bus speed @ 125 MHz)
Max
Unit μs
ts th
Setup time Hold time
20 20 Table 32. EEPROM Timing Parameters
ns ns
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Auto Negotiation Timing
Figure 23. Auto-Negotiation Timing
Timing Parameter tBTB tFLPW tPW tCTD tCTC
Description FLP burst to FLP burst FLP burst width Clock/Data pulse width Clock pulse to data pulse Clock pulse to clock pulse Number of Clock/Data pulses per burst
Min 8
Typ 16 2 100
Max 24
Unit ms ms ns
55.5 111 17
64 128
69.5 139 33
µs µs
Table 33. Auto Negotiation Timing Parameters
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Reset Timing As long as the stable supply voltages to reset High timing (minimum of 10ms) are met, there is no power-sequencing requirement for the KSZ8862M supply voltage (3.3V). The reset timing requirement is summarized in the Figure 26 and Table 34.
Figure 24. Reset Timing
Symbol tsr
Parameter Stable supply voltages to reset High
Min 10
Max
Unit ms
Table 34. Reset Timing Parameters
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Selection of Isolation Transformers
A 1:1 isolation transformer is required at the line interface. An isolation transformer with integrated common-mode choke is recommended to exceed FCC requirements. Table 35 gives recommended transformer characteristics.
Parameter Turns ratio Open-circuit inductance (min) Leakage inductance (max) Inter-winding capacitance (max) D.C. resistance (max) Insertion loss (max) HIPOT (min) Value 1 CT : 1 CT 350μH 0.4μH 12pF 0.9Ω 1.0dB 1500Vrms Table 35. Transformer Selection Criteria 0MHz – 65MHz 100mV, 100kHz, 8mA 1MHz (min) Test Condition
Magnetic Manufacturer Pulse Pulse (low cost) Transpower Bel Fuse Delta LanKom
Part Number H1102 H1260 HB726 S558-5999-U7 LF8505 LF-H41S
Auto MDI-X Yes Yes Yes Yes Yes Yes
Number of Port 1 1 1 1 1 1
Table 36. Qualified Single Port Magnetic
Selection of Reference Crystal
Chacteristics Frequency Frequency tolerance (max) Load capacitance (max) Series resistance Value 25 ±50 20 25 Units MHz ppm pF Ω
Table 37. Typical Reference Crystal Characteristics
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Package Information
Figure 25. 128-Pin PQFP Package
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Acronyms and Glossary
BIU Bus Interface Unit BPDU Bridge Protocol Data Unit CMOS The host interface function that performs code conversion, buffering, and the like required for communications to and from a network. A packet containing ports, addresses, etc. to make sure data being passed through a bridged network arrives at its proper destination. Complementary Metal Oxide Semiconductor A common semiconductor manufacturing technique in which positive and negative types of transistors are combined to form a current gate that in turn forms an effective means of controlling electrical current through a chip. A common technique for detecting data transmission errors. CRC for
CRC Cyclic Redundancy Check Cut-through switch
Ethernet is 32 bits long.
A switch typically processes received packets by reading in the full packet (storing), then processing the packet to determine where it needs to go, then forwarding it. A cut-through switch simply reads in the first bit of an incoming packet and forwards the packet. Cut-through switches do not store the packet. The address to send packets. A design in which memory on a chip is controlled independently of the CPU. A design in which memory on a chip can be erased by exposing it to an electrical charge. A bus architecture designed for PCs using 80x86 processors, or an Intel 80386, 80486 or Pentium microprocessor. EISA buses are 32 bits wide and support multiprocessing. A naturally occurring phenomena when the electromagnetic field of one device disrupts, impedes or degrades the electromagnetic field of another device by coming into proximity with it. In computer technology, computer devices are susceptible to EMI because electromagnetic fields are a byproduct of passing electricity through a wire. Data lines that have not been properly shielded are susceptible to data corruption by EMI. See CRC. Specifies the frame identifier. Alternately is the filter identifier. The protocol defined by RFC 1112 for IP multicast transmissions. A time delay between successive data packets mandated by the network standard for protocol reasons. In Ethernet, the medium has to be "silent" (i.e., no data transfer) for a short period of time before a node can consider the network idle and start to transmit. IPG is used to correct timing differences between a transmitter and receiver. During the IPG, no data is transferred, and information in the gap can be discarded or additions inserted without impact on data integrity. The disruption of transmitted code caused by adjacent pulses affecting or interfering with each other. A bus architecture used in the IBM PC/XT and PC/AT. A packet larger than the standard Ethernet packet (1500 bytes). Large packet sizes allow for more efficient use of bandwidth, lower overhead, less processing, etc. An Ethernet port connection that allows network hubs or switches to connect to other hubs or switches without a null-modem, or crossover, cable. MDI provides the standard interface to a particular media (copper or fiber) and is therefore 'media dependent.'
DA
Destination Address
DMA Direct Memory Access EEPROM Electronically Erasable Programmable Read-only Memory EISA Extended Industry Standard Architecture
EMI
Electro-Magnetic Interference
FCS FID IGMP IPG
Frame Check Sequence Frame or Filter ID Internet Group Management Protocol Inter-Packet Gap
ISI
Inter-Symbol Interference
ISA Industry Standard Architecture Jumbo Packet
MDI
Medium Dependent Interface
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MDI-X Medium Dependent Interface Crossover
KSZ8862-16/32MQL
An Ethernet port connection that allows networked end stations (i.e., PCs or workstations) to connect to each other using a null-modem, or crossover, cable. For 10/100 full-duplex networks, an end point (such as a computer) and a switch are wired so that each transmitter connects to the far end receiver. When connecting two computers together, a cable that crosses the TX and RX is required to do this. With auto MDI-X, the PHY senses the correct TX and RX roles, eliminating any cable confusion. The MIB comprises the management portion of network devices. This can include things like monitoring traffic levels and faults (statistical), and can also change operating parameters in network nodes (static forwarding addresses). The MII accesses PHY registers as defined in the IEEE 802.3 specification. An expansion board inserted into a computer to allow it to be connected to a network. Most NICs are designed for a particular type of network, protocol, and media, although some can serve multiple networks. The Port VLAN ID value is used as a VLAN reference. An electronic circuit that controls an oscillator so that it maintains a constant phase angle (i.e., lock) on the frequency of an input, or reference, signal. A PLL ensures that a communication signal is locked on a specific frequency and can also be used to generate, modulate, and demodulate a signal and divide a frequency. An occurrence that affects the directing of power to different components of a system. Manages packet traffic between MAC/PHY interface and the system host. The QMU has built-in packet memories for receive and transmit functions called TXQ (Transmit Queue) and RXQ (Receive Queue). The address from which information has been sent. TDR is used to pinpoint flaws and problems in underground and aerial wire, cabling, and fiber optics. They send a signal down the conductor and measure the time it takes for the signal -- or part of the signal -- to return. Commonly a cable containing 4 twisted pairs of wires. The wires are twisted in such a manner as to cancel electrical interference generated in each wire, therefore shielding is not required. A configuration of computers that acts as if all computers are connected by the same physical network but which may be located virtually anywhere.
MIB
Management Information Base
MII NIC
Media Independent Interface Network Interface Card
NPVID Non Port VLAN ID PLL Phase-Locked Loop
PME Power Management Event QMU Queue Management Unit
SA Source Address TDR Time Domain Reflectometry
UTP
Unshielded Twisted Pair
VLAN Virtual Local Area Network
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http://www.micrel.com
The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer. Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. © 2006 Micrel, Incorporated.
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