KSZ8995FQI - Micrel - Datasheet.Live

May 2005 1 M9999-051305

KS8995MA Micrel, Inc.

KS8995MA

Integrated 5-Port 10/100 Managed Switch

Rev 2.4

General Description

The KS8995MA is a highly integrated Layer 2 managed

switch with optimized bill of materials (BOM) cost for low port

count, cost-sensitive 10/100Mbps switch systems. It also

provides an extensive feature set such as tag/port-based

VLAN, quality of service (QoS) priority, management, MIB

counters, dual MII interfaces and CPU control/data interfaces

to effectively address both current and emerging Fast Ether-

net applications.

The KS8995MA contains five 10/100 transceivers with pat-

ented mixed-signal low-power technology, five media access

control (MAC) units, a high-speed non-blocking switch fabric,

a dedicated address lookup engine, and an on-chip frame

buffer memory.

All PHY units support 10BASE-T and 100BASE-TX.

In addition, two of the PHY units support 100BASE-FX

(ports 4 and 5).

Features

•Integrated switch with five MACs and five Fast Ethernet

transceivers fully compliant to IEEE 802.3u standard

•Shared memory based switch fabric with fully non-

blocking configuration

•1.4Gbps high-performance memory bandwidth

•10BASE-T, 100BASE-TX, and 100BASE-FX modes

(FX in ports 4 and 5)

•Dual MII configuration: MII-Switch (MAC or PHY mode

MII) and MII-P5 (PHY mode MII)

•IEEE 802.1q tag-based VLAN (16 VLANs, full-range

VID) for DMZ port, WAN/LAN separation or inter-VLAN

switch links

•VLAN ID tag/untag options, per-port basis

•Programmable rate limiting 0Mbps to 100Mbps, ingress

and egress port, rate options for high and low priority,

per-port basis in 32Kbps increments

•Flow control or drop packet rate limiting (ingress port)

•Integrated MIB counters for fully compliant statistics

gathering, 34 MIB counters per port

Micrel, Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com

Functional Diagram

1K Look-Up

Engine

Queue

Mgmnt

10/100

MAC 1

Buffer

Mgmnt

Frame

Buffers

FIFO, Flow Control, VLAN Tagging, Priority

10/100

MAC 2

10/100

MAC 3

10/100

MAC 4

10/100

MAC 5

SNI

10/100

T/Tx 1

10/100

T/Tx 2

10/100

T/Tx 3

10/100

T/Tx/Fx 4

10/100

T/Tx/Fx 5

SPI

EEPROM

I/F

LED I/F

Auto

MDI/MDI-X

Control Reg I/F

KS8995MA

MIB

Counters

MII-SW or SNI

LED0[5:1]

LED1[5:1]

LED2[5:1]

Control

Registers

MII-P5

MDC, MDI/O

Auto

MDI/MDI-X

Auto

MDI/MDI-X

Auto

MDI/MDI-X

Auto

MDI/MDI-X

KS8995MA Micrel, Inc.

M9999-051305 2May 2005

Features (continued)

•Enable/Disable option for huge frame size up to 1916

bytes per frame

•IGMP v1/v2 snooping for multicast packet filtering

•Special tagging mode to send CPU info on ingress

packet’s port value

•SPI slave (complete) and MDIO (MII PHY only) serial

management interface for control of register configura-

tion

•MAC-id based security lock option

•Control registers configurable on-the-fly (port-priority,

802.1p/d/q, AN...)

•CPU read access to MAC forwarding table entries

•802.1d Spanning Tree Protocol

•Port mirroring/monitoring/sniffing: ingress and/or egress

traffic to any port or MII

•Broadcast storm protection with % control – global and

per-port basis

•Optimization for fiber-to-copper media conversion

•Full-chip hardware power-down support (register

configuration not saved)

•Per-port based software power-save on PHY (idle link

detection, register configuration preserved)

•QoS/CoS packets prioritization supports: per port,

802.1p and DiffServ based

•802.1p/q tag insertion or removal on a per-port basis

(egress)

•MDC and MDI/O interface support to access the MII

PHY control registers (not all control registers)

•MII local loopback support

•On-chip 64Kbyte memory for frame buffering (not

shared with 1K unicast address table)

•Wire-speed reception and transmission

•Integrated look-up engine with dedicated 1K MAC

addresses

•Full duplex IEEE 802.3x and half-duplex back pressure

flow control

•Comprehensive LED support

•7-wire SNI support for legacy MAC interface

•Automatic MDI/MDI-X crossover for plug-and-play

•Disable automatic MDI/MDI-X option

•Low power:

Core: 1.8V

I/O: 2.5V or 3.3V

•0.18µm CMOS technology

•Commercial temperature range: 0°C to +70°C

•Industrial temperature range: –40°C to +85°C

•Available in 128-pin PQFP package

Applications

•Broadband gateway/firewall/VPN

•Integrated DSL or cable modem multi-port router

•Wireless LAN access point plus gateway

•Home networking expansion

•Standalone 10/100 switch

•Hotel/campus/MxU gateway

•Enterprise VoIP gateway/phone

•FTTx customer premise equipment

•Managed Media converter

Ordering Information

Part Number Temp. Range Package Lead Finish

KS8995MA 0°C to +70°C128-Pin PQFP Standard

KSZ8995MA 0°C to +70°C128-Pin PQFP Lead-Free

KS8995MAI –40°C to +85°C128-Pin PQFP Standard

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Revision History

Revision Date Summary of Changes

2.0 10/10/03 Created.

2.1 10/30/03 Editorial changes on electrical characteristics.

2.2 4/1/04 Editorial changes on the TTL input and output electrical characteristics.

2.3 1/19/05 Insert recommended reset circuit., Pg. 70. Editorial, Pg. 36

2.4 4/13/05 Changed VDDIO to 3.3V.

Changed Jitter to 16 ns Max.

KS8995MA Micrel, Inc.

M9999-051305 4May 2005

Table of Contents

System Level Applications ......................................................................................................................................... 7

Pin Description by Number ........................................................................................................................................ 9

Pin Description by Name .......................................................................................................................................... 15

Pin Configuration ...................................................................................................................................................... 21

Introduction ........................................................................................................................................................... 22

Functional Overview: Physical Layer Transceiver ............................................................................................... 22

100BASE-TX Transmit ........................................................................................................................................ 22

100BASE-TX Receive ......................................................................................................................................... 22

PLL Clock Synthesizer......................................................................................................................................... 22

Scrambler/De-scrambler (100BASE-TX only) ..................................................................................................... 22

100BASE-FX Operation....................................................................................................................................... 22

100BASE-FX Signal Detection ............................................................................................................................ 22

100BASE-FX Far End Fault ................................................................................................................................ 23

10BASE-T Transmit ............................................................................................................................................. 23

10BASE-T Receive .............................................................................................................................................. 23

Power Management ............................................................................................................................................. 23

MDI/MDI-X Auto Crossover ................................................................................................................................. 23

Auto-Negotiation .................................................................................................................................................. 23

Functional Overview: Switch Core ......................................................................................................................... 24

Address Look-Up ................................................................................................................................................. 24

Learning ........................................................................................................................................................... 24

Migration ........................................................................................................................................................... 24

Aging ........................................................................................................................................................... 24

Forwarding ........................................................................................................................................................... 24

Switching Engine ................................................................................................................................................. 24

MAC Operation .................................................................................................................................................... 24

Inter-Packet Gap (IPG) ................................................................................................................................ 24

Backoff Algorithm ......................................................................................................................................... 24

Late Collision................................................................................................................................................ 26

Illegal Frames .............................................................................................................................................. 26

Flow Control ................................................................................................................................................. 26

Half-Duplex Back Pressure .......................................................................................................................... 26

Broadcast Storm Protection ......................................................................................................................... 26

MII Interface Operation ........................................................................................................................................ 26

SNI Interface Operation ....................................................................................................................................... 28

Advanced Functionality............................................................................................................................................ 28

Spanning Tree Support ........................................................................................................................................ 28

Special Tagging Mode ......................................................................................................................................... 29

IGMP Support ...................................................................................................................................................... 30

Port Mirroring Support ......................................................................................................................................... 31

VLAN Support ...................................................................................................................................................... 31

Rate Limit Support ............................................................................................................................................... 32

Configuration Interface ........................................................................................................................................ 33

I2C Master Serial Bus Configuration ............................................................................................................ 35

SPI Slave Serial Bus Configuration ............................................................................................................. 35

MII Management Interface (MIIM) ....................................................................................................................... 38

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Register Description ................................................................................................................................................. 39

Global Registers .................................................................................................................................................. 39

Register 0 (0x00): Chip ID0 ......................................................................................................................... 39

Register 1 (0x01): Chip ID1/Start Switch ..................................................................................................... 39

Register 2 (0x02): Global Control 0 ............................................................................................................. 40

Register 3 (0x03): Global Control 1 ............................................................................................................. 40

Register 4 (0x04): Global Control 2 ............................................................................................................. 41

Register 5 (0x05): Global Control 3 ............................................................................................................. 42

Register 6 (0x06): Global Control 4 ............................................................................................................. 42

Register 7 (0x07): Global Control 5 ............................................................................................................. 43

Register 8 (0x08): Global Control 6 ............................................................................................................. 43

Register 9 (0x09): Global Control 7 ............................................................................................................. 43

Register 10 (0x0A): Global Control 8 ........................................................................................................... 43

Register 11 (0x0B): Global Control 9 ........................................................................................................... 43

Port Registers ...................................................................................................................................................... 44

Register 16 (0x10): Port 1 Control 0 ........................................................................................................... 44

Register 17 (0x11): Port 1 Control 1 ........................................................................................................... 44

Register 18 (0x12): Port 1 Control 2 ........................................................................................................... 45

Register 19 (0x13): Port 1 Control 3 ........................................................................................................... 46

Register 20 (0x14): Port 1 Control 4 ........................................................................................................... 46

Register 21 (0x15): Port 1 Control 5 ........................................................................................................... 46

Register 22 (0x16): Port 1 Control 6 ........................................................................................................... 46

Register 23 (0x17): Port 1 Control 7 ........................................................................................................... 46

Register 24 (0x18): Port 1 Control 8 ........................................................................................................... 47

Register 25 (0x19): Port 1 Control 9 ........................................................................................................... 47

Register 26 (0x1A): Port 1 Control 10 ......................................................................................................... 47

Register 27 (0x1B): Port 1 Control 11 ......................................................................................................... 47

Register 28 (0x1C): Port 1 Control 12 ......................................................................................................... 48

Register 29 (0x1D): Port 1 Control 13 ......................................................................................................... 49

Register 30 (0x1E): Port 1 Status 0 ............................................................................................................ 49

Register 31 (0x1F): Port 1 Control 14 ......................................................................................................... 50

Advanced Control Registers ................................................................................................................................ 50

Register 96 (0x60): TOS Priority Control Register 0 ................................................................................... 50

Register 97 (0x61): TOS Priority Control Register 1 ................................................................................... 50

Register 98 (0x62): TOS Priority Control Register 2 ................................................................................... 50

Register 99 (0x63): TOS Priority Control Register 3 ................................................................................... 50

Register 100 (0x64): TOS Priority Control Register 4 ................................................................................. 50

Register 101 (0x65): TOS Priority Control Register 5 ................................................................................. 50

Register 102 (0x66): TOS Priority Control Register 6 ................................................................................. 50

Register 103 (0x67): TOS Priority Control Register 7 ................................................................................. 50

Register 104 (0x68): MAC Address Register 0 ........................................................................................... 50

Register 105 (0x69): MAC Address Register 1 ........................................................................................... 50

Register 106 (0x6A): MAC Address Register 2 .......................................................................................... 51

Register 107 (0x6B): MAC Address Register 3 .......................................................................................... 51

Register 108 (0x6C): MAC Address Register 4 .......................................................................................... 51

Register 109 (0X6D): MAC Address Register 5 .......................................................................................... 51

Register 110 (0x6E): Indirect Access Control 0 .......................................................................................... 51

Register 111 (0x6F): Indirect Access Control 1 .......................................................................................... 51

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Register 112 (0x70): Indirect Data Register 8 ............................................................................................. 51

Register 113 (0x71): Indirect Data Register 7 ............................................................................................. 51

Register 114 (0x72): Indirect Data Register 6 ............................................................................................. 51

Register 115 (0x73): Indirect Data Register 5 ............................................................................................. 51

Register 116 (0x74): Indirect Data Register 4 ............................................................................................. 51

Register 117 (0x75): Indirect Data Register 3 ............................................................................................. 51

Register 118 (0x76): Indirect Data Register 2 ............................................................................................. 51

Register 119 (0x77): Indirect Data Register 1 ............................................................................................. 51

Register 120 (0x78): Indirect Data Register 0 ............................................................................................. 51

Register 121 (0x79): Digital Testing Status 0 ............................................................................................. 52

Register 122 (0x7A): Digital Testing Status 1 ............................................................................................. 52

Register 123 (0x7B): Digital Testing Control 0 ............................................................................................ 52

Register 124 (0x7C): Digital Testing Control 1............................................................................................ 52

Register 125 (0x7D): Analog Testing Control 0 .......................................................................................... 52

Register 126 (0x7E): Analog Testing Control 1 ........................................................................................... 52

Register 127 (0x7F): Analog Testing Status ............................................................................................... 52

Static MAC Address .................................................................................................................................................. 53

VLAN Address ........................................................................................................................................................... 55

Dynamic MAC Address ............................................................................................................................................. 56

MIB Counters ........................................................................................................................................................... 57

MIIM Registers ........................................................................................................................................................... 60

Register 0: MII Control ................................................................................................................................. 60

Register 1: MII Status .................................................................................................................................. 61

Register 2: PHYID HIGH ............................................................................................................................. 61

Register 3: PHYID LOW .............................................................................................................................. 61

Register 4: Advertisement Ability ................................................................................................................. 61

Register 5: Link Partner Ability .................................................................................................................... 62

Absolute Maximum Ratings ..................................................................................................................................... 63

Operating Ratings ..................................................................................................................................................... 63

Electrical Characteristics ......................................................................................................................................... 63

Timing Diagrams ....................................................................................................................................................... 65

Selection of Isolation Transformers........................................................................................................................ 72

Qualified Magnetic Lists ........................................................................................................................................... 72

Package Information ................................................................................................................................................. 73

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KS8995MA Micrel, Inc.

System Level Applications

Ethernet

MAC

CPU

Switch Controller

On-Chip Frame Buffers

MII-SW

10/100

PHY 5

4-port

LAN

MII-P5

1-port

WAN I/F

10/100

MAC 1

10/100

MAC 2

10/100

MAC 3

10/100

MAC 4

10/100

MAC 5

10/100

PHY 1

10/100

PHY 2

10/100

PHY 3

10/100

PHY 4

SPI/GPIO

SPI

Ethernet

MAC

External WAN port PHY not required.

Figure 1. Broadband Gateway

Ethernet

MAC

CPU

Switch Controller

On-Chip Frame Buffers

MII-SW

10/100

PHY 5

4-port

LAN

MII-P5

10/100

MAC 1

10/100

MAC 2

10/100

MAC 3

10/100

MAC 4

10/100

MAC 5

10/100

PHY 1

10/100

PHY 2

10/100

PHY 3

10/100

PHY 4

WAN PHY & AFE

(xDSL, CM...)

SPISPI/GPIO

Figure 2. Integrated Broadband Router

KS8995MA Micrel, Inc.

M9999-051305 8May 2005

Switch Controller

On-Chip Frame Buffers

10/100

PHY 5

5-port

LAN

10/100

MAC 1

10/100

MAC 2

10/100

MAC 3

10/100

MAC 4

10/100

MAC 5

10/100

PHY 1

10/100

PHY 2

10/100

PHY 3

10/100

PHY 4

Figure 3. Standalone Switch

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Pin Description (by Number)

Pin Number Pin Name Type(1) Port Pin Function(2)

1MDI-XDIS Ipd 1-5 Disable auto MDI/MDI-X.

PD (default) = normal operation.

PU = disable auto MDI/MDI-X on all ports.

2GNDA Gnd Analog ground.

3VDDAR P 1.8V analog VDD.

4RXP1 I 1 Physical receive signal + (differential).

5RXM1 I 1 Physical receive signal – (differential).

6GNDA Gnd Analog ground.

7TXP1 O 1 Physical transmit signal + (differential).

8TXM1 O 1 Physical transmit signal – (differential).

9VDDAT P 2.5V or 3.3V analog VDD.

10 RXP2 I 2 Physical receive signal + (differential).

11 RXM2 I 2 Physical receive signal - (differential).

12 GNDA Gnd Analog ground.

13 TXP2 O 2 Physical transmit signal + (differential).

14 TXM2 O 2 Physical transmit signal – (differential).

15 VDDAR P 1.8V analog VDD.

16 GNDA Gnd Analog ground.

17 ISET Set physical transmit output current. Pull-down with a 3.01kΩ 1%

resistor.

18 VDDAT P 2.5V or 3.3V analog VDD.

19 RXP3 I 3 Physical receive signal + (differential).

20 RXM3 I 3 Physical receive signal – (differential).

21 GNDA Gnd Analog ground.

22 TXP3 O 3 Physical transmit signal + (differential).

23 TXM3 O 3 Physical transmit signal – (differential).

24 VDDAT P 2.5V or 3.3V analog VDD.

25 RXP4 I 4 Physical receive signal + (differential).

26 RXM4 I 4 Physical receive signal – (differential).

27 GNDA Gnd Analog ground.

28 TXP4 O 4 Physical transmit signal + (differential).

29 TXM4 O 4 Physical transmit signal – (differential).

30 GNDA Gnd Analog ground.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

2. PU = Strap pin pull-up.

PD = Strap pin pull-down.

KS8995MA Micrel, Inc.

M9999-051305 10 May 2005

Pin Number Pin Name Type(1) Port Pin Function

31 VDDAR P 1.8V analog VDD.

32 RXP5 I 5 Physical receive signal + (differential).

33 RXM5 I 5 Physical receive signal – (differential).

34 GNDA Gnd Analog ground.

35 TXP5 O 5 Physical transmit signal + (differential).

36 TXM5 O 5 Physical transmit signal – (differential).

37 VDDAT P 2.5V or 3.3V analog VDD.

38 FXSD5 I 5 Fiber signal detect/factory test pin.

39 FXSD4 I 4 Fiber signal detect/factory test pin.

40 GNDA Gnd Analog ground.

41 VDDAR P 1.8V analog VDD.

42 GNDA Gnd Analog ground.

43 VDDAR P 1.8V analog VDD.

44 GNDA Gnd Analog ground.

45 MUX1 NC Factory test pins. MUX1 and MUX2 should be left unconnected for

46 MUX2 NC normal operation.

Mode MUX1 MUX2

Normal Operation NC NC

47 PWRDN_N Ipu Full-chip power down. Active low.

48 RESERVE NC Reserved pin. No connect.

49 GNDD Gnd Digital ground.

50 VDDC P 1.8V digital core VDD.

51 PMTXEN Ipd 5 PHY[5] MII transmit enable.

52 PMTXD3 Ipd 5 PHY[5] MII transmit bit 3.

53 PMTXD2 Ipd 5 PHY[5] MII transmit bit 2.

54 PMTXD1 Ipd 5 PHY[5] MII transmit bit 1.

55 PMTXD0 Ipd 5 PHY[5] MII transmit bit 0.

56 PMTXER Ipd 5 PHY[5] MII transmit error.

57 PMTXC O 5 PHY[5] MII transmit clock. PHY mode MII.

58 GNDD Gnd Digital ground.

59 VDDIO P 3.3V digital VDD for digital I/O circuitry.

60 PMRXC O 5 PHY[5] MII receive clock. PHY mode MII.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

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Pin Number Pin Name Type(1) Port Pin Function(2)

61 PMRXDV Ipd/O 5 PHY[5] MII receive data valid.

62 PMRXD3 Ipd/O 5 PHY[5] MII receive bit 3. Strap option: PD (default) = enable flow

control; PU = disable flow control.

63 PMRXD2 Ipd/O 5 PHY[5] MII receive bit 2. Strap option: PD (default) = disable back

pressure; PU = enable back pressure.

64 PMRXD1 Ipd/O 5 PHY[5] MII receive bit 1. Strap option: PD (default) = drop excessive

collision packets; PU = does not drop excessive collision packets.

65 PMRXD0 Ipd/O 5 PHY[5] MII receive bit 0. Strap option: PD (default) = disable

aggressive back-off algorithm in half-duplex mode; PU = enable for

performance enhancement.

66 PMRXER Ipd/O 5 PHY[5] MII receive error. Strap option: PD (default) = 1522/1518 bytes;

PU = packet size up to 1536 bytes.

67 PCRS Ipd/O 5 PHY[5] MII carrier sense/force duplex mode. See “Register 76” for

port 4 only. PD (default) = force half-duplex if auto-negotiation is

disabled or fails. PU = force full-duplex if auto-negotiation is disabled

or fails.

68 PCOL Ipd/O 5 PHY[5] MII collision detect/force flow control. See “Register 66” for

port 4 only. PD (default) = no force flow control. normal operation. PU =

force flow control.

69 SMTXEN Ipd Switch MII transmit enable.

70 SMTXD3 Ipd Switch MII transmit bit 3.

71 SMTXD2 Ipd Switch MII transmit bit 2.

72 SMTXD1 Ipd Switch MII transmit bit 1.

73 SMTXD0 Ipd Switch MII transmit bit 0.

74 SMTXER Ipd Switch MII transmit error.

75 SMTXC I/O Switch MII transmit clock. Input in MAC mode, output in PHY mode MII.

76 GNDD Gnd Digital ground.

77 VDDIO P 3.3V digital VDD for digital I/O circuitry

78 SMRXC I/O Switch MII receive clock. Input in MAC mode, output in PHY mode MII.

79 SMRXDV Ipd/O Switch MII receive data valid

80 SMRXD3 Ipd/O Switch MII receive bit 3. Strap option: PD (default) = Disable Switch MII

full-duplex flow control; PU = enable switch MII full-duplex flow control.

81 SMRXD2 Ipd/O Switch MII receive bit 2. Strap option: PD (default) = switch MII in full

duplex mode; PU = switch MII in half-duplex mode.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

2. PU = Strap pin pull-up.

PD = Strap pin pull-down.

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M9999-051305 12 May 2005

Pin Number Pin Name Type(1) Port Pin Function(2)

82 SMRXD1 Ipd/O Switch MII receive bit 1. Strap option: PD (default) = switch MII in

100Mbps mode; PU = switch MII in 10Mbps mode.

83 SMRXD0 Ipd/O Switch MII receive bit 0. Strap option: LED mode

PD (default) = mode 0; PU = mode 1. See “Register 11.”

Mode 0 Mode 1

LEDX_2 Lnk/Act 100Lnk/Act

LEDX_1 Fulld/Col 10Lnk/Act

LEDX_0 Speed Full duplex

84 SCOL Ipd/O Switch MII collision detect.

85 SCRS Ipd/O Switch MII carrier sense.

86 SCONF1 Ipd Dual MII configuration pin.

Pin (91, 86, 87): Switch MII PHY [5] MII

000 Disable, Otri Disable, Otri

001 PHY Mode MII Disable, Otri

010 MAC Mode MII Disable, Otri

011 PHY Mode SNI Disable, Otri

100 Disable Disable

101 PHY Mode MII PHY Mode MII

110 MAC Mode MII PHY Mode MII

111 PHY Mode SNI PHY Mode MII

87 SCONF0 Ipd Dual MII configuration pin.

88 GNDD Gnd Digital ground.

89 VDDC P 1.8V digital core VDD.

90 LED5-2 Ipu/O 5 LED indicator 2. Strap option: aging setup. See “Aging” section.

PU (default) = aging enable; PD = aging disable.

91 LED5-1 Ipu/O 5 LED indicator 1. Strap option: PU (default) = enable PHY MII I/F.

PD: tristate all PHY MII output. See “Pin 86 SCONF1.”

92 LED5-0 Ipu/O 5 LED indicator 0

93 LED4-2 Ipu/O 4 LED indicator 2

94 LED4-1 Ipu/O 4 LED indicator 1

95 LED4-0 Ipu/O 4 LED indicator 0

96 LED3-2 Ipu/O 3 LED indicator 2

97 LED3-1 Ipu/O 3 LED indicator 1

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

2. PU = Strap pin pull-up. Otri = Output tristated.

PD = Strap pin pull-down. Fulld = Full duplex.

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Pin Number Pin Name Type(1) Port Pin Function

98 LED3-0 Ipu/O 3 LED indicator 0.

99 GNDD Gnd Digital ground.

100 VDDIO P 3.3V digital VDD for digital I/O.

101 LED2-2 Ipu/O 2 LED indicator 2.

102 LED2-1 Ipu/O 2 LED indicator 1.

103 LED2-0 Ipu/O 2 LED indicator 0.

104 LED1-2 Ipu/O 1 LED indicator 2.

105 LED1-1 Ipu/O 1 LED indicator 1.

106 LED1-0 Ipu/O 1 LED indicator 0.

107 MDC Ipu All Switch or PHY[5] MII management data clock.

108 MDIO I/O All Switch or PHY[5] MII management data I/O.

Features internal pull down to define pin state when not driven.

109 SPIQ Otri All (1) SPI serial data output in SPI slave mode; (2) not used in I2C master

mode. See “Pin 113.”

110 SPIC/SCL I/O All (1) Input clock up to 5MHz in SPI slave mode; (2) output clock at

81kHz in I2C master mode. See “Pin 113.”

111 SPID/SDA I/O All (1) Serial data input in SPI slave mode; (2) serial data input/output in

I2C master mode. See “Pin 113.”

112 SPIS_N Ipu All Active low. (1) SPI data transfer start in SPI slave mode. When SPIS_N

is high, the KS8995MA is deselected and SPIQ is held in high

impedance state, a high-to-low transition to initiate the SPI data transfer;

(2) not used in I2C master mode.

113 PS1 Ipd Serial bus configuration pin.

For this case, if the EEPROM is not present, the KS8995MA will start

itself with the PS[1:0] = 00 default register values .

Pin Configuration Serial Bus Configuration

PS[1:0]=00 I2C Master Mode for EEPROM

PS[1:0]=01 Reserved

PS[1:0]=10 SPI Slave Mode for CPU Interface

PS[1:0]=11 Factory Test Mode (BIST)

114 PS0 Ipd Serial bus configuration pin. See “Pin 113.”

115 RST_N Ipu Reset the KS8995MA. Active low.

116 GNDD Gnd Digital ground.

117 VDDC P 1.8V digital core VDD.

118 TESTEN Ipd NC for normal operation. Factory test pin.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

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M9999-051305 14 May 2005

Pin Number Pin Name Type(1) Port Pin Function

119 SCANEN Ipd NC for normal operation. Factory test pin.

120 NC NC No connect.

121 X1 I 25MHz crystal clock connection/or 3.3V tolerant oscillator input.

Oscillator should be ±100ppm.

122 X2 O 25MHz crystal clock connection.

123 VDDAP P 1.8V analog VDD for PLL.

124 GNDA Gnd Analog ground.

125 VDDAR P 1.8V analog VDD.

126 GNDA Gnd Analog ground.

127 GNDA Gnd Analog ground.

128 TEST2 NC NC for normal operation. Factory test pin.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

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Pin Description (by Name)

Pin Number Pin Name Type(1) Port Pin Function

39 FXSD4 I 4 Fiber signal detect/factory test pin.

38 FXSD5 I 5 Fiber signal detect/factory test pin.

124 GNDA Gnd Analog ground.

42 GNDA Gnd Analog ground.

44 GNDA Gnd Analog ground.

2GNDA Gnd Analog ground.

16 GNDA Gnd Analog ground.

30 GNDA Gnd Analog ground.

6GNDA Gnd Analog ground.

12 GNDA Gnd Analog ground.

21 GNDA Gnd Analog ground.

27 GNDA Gnd Analog ground.

34 GNDA Gnd Analog ground.

40 GNDA Gnd Analog ground.

120 NC NC No connect.

127 GNDA Gnd Analog ground.

126 GNDA Gnd Analog ground.

49 GNDD Gnd Digital ground.

88 GNDD Gnd Digital ground.

116 GNDD Gnd Digital ground.

58 GNDD Gnd Digital ground.

76 GNDD Gnd Digital ground.

99 GNDD Gnd Digital ground.

17 ISET Set physical transmit output current. Pull-down with a 3.01kΩ 1%

resistor.

106 LED1-0 Ipu/O 1 LED indicator 0.

105 LED1-1 Ipu/O 1 LED indicator 1.

104 LED1-2 Ipu/O 1 LED indicator 2.

103 LED2-0 Ipu/O 2 LED indicator 0.

102 LED2-1 Ipu/O 2 LED indicator 1.

101 LED2-2 Ipu/O 2 LED indicator 2.

98 LED3-0 Ipu/O 3 LED indicator 0.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

KS8995MA Micrel, Inc.

M9999-051305 16 May 2005

Pin Number Pin Name Type(1) Port Pin Function(2)

97 LED3-1 Ipu/O 3 LED indicator 1.

96 LED3-2 Ipu/O 3 LED indicator 2.

95 LED4-0 Ipu/O 4 LED indicator 0.

94 LED4-1 Ipu/O 4 LED indicator 1.

93 LED4-2 Ipu/O 4 LED indicator 2.

92 LED5-0 Ipu/O 5 LED indicator 0.

91 LED5-1 Ipu/O 5 LED indicator 1. Strap option: PU (default) = enable PHY MII I/F

PD: tristate all PHY MII output. See “Pin 86 SCONF1.”

90 LED5-2 Ipu/O 5 LED indicator 2. Strap option: aging setup. See “Aging” section.

(default) = aging enable; PD = aging disable.

107 MDC Ipu All Switch or PHY[5] MII management data clock.

108 MDIO I/O All Switch or PHY[5] MII management data I/O.

1MDI-XDIS Ipd 1-5 Disable auto MDI/MDI-X.

45 MUX1 NC Factory test pins. MUX1 and MUX2 should be left unconnected for

46 MUX2 NC normal operation.

Mode MUX1 MUX2

Normal Operation NC NC

68 PCOL Ipd/O 5 PHY[5] MII collision detect/force flow control. See “Register 18.”

For port 4 only. PD (default) = no force flow control. PU = force flow

control.

67 PCRS Ipd/O 5 PHY[5] MII carrier sense/force duplex mode. See “Register 28.”

For port 4 only. PD (default) = force half-duplex if auto-negotiation is

disabled or fails. PU = force full-duplex if auto-negotiation is disabled

or fails.

60 PMRXC O 5 PHY[5] MII receive clock. PHY mode MII.

65 PMRXD0 Ipd/O 5 PHY[5] MII receive bit 0. Strap option: PD (default) = disable

aggressive back-off algorithm in half-duplex mode; PU = enable for

performance enhancement.

64 PMRXD1 Ipd/O 5 PHY[5] MII receive bit 1. Strap option: PD (default) = drop excessive

collision packets; PU = does not drop excessive collision packets.

63 PMRXD2 Ipd/O 5 PHY[5] MII receive bit 2. Strap option: PD (default) = disable back

pressure; PU = enable back pressure.

62 PMRXD3 Ipd/O 5 PHY[5] MII receive bit 3. Strap option: PD (default) = enable flow

control; PU = disable flow control.

61 PMRXDV Ipd/O 5 PHY[5] MII receive data valid.

66 PMRXER Ipd/O 5 PHY[5] MII receive error. Strap option: PD (default) = 1522/1518 bytes;

PU = packet size up to 1536 bytes.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

2. PU = Strap pin pull-up.

PD = Strap pin pull-down.

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KS8995MA Micrel, Inc.

Pin Number Pin Name Type(1) Port Pin Function

57 PMTXC O 5 PHY[5] MII transmit clock. PHY mode MII.

55 PMTXD0 Ipd 5 PHY[5] MII transmit bit 0.

54 PMTXD1 Ipd 5 PHY[5] MII transmit bit 1.

53 PMTXD2 Ipd 5 PHY[5] MII transmit bit 2.

52 PMTXD3 Ipd 5 PHY[5] MII transmit bit 3.

51 PMTXEN Ipd 5 PHY[5] MII transmit enable.

56 PMTXER Ipd 5 PHY[5] MII transmit error.

114 PS0 Ipd Serial bus configuration pin. See “Pin 113.”

113 PS1 Ipd Serial bus configuration pin.

If EEPROM is not present, the KS8995MA will start itself with chip

default (00)...

Pin Configuration Serial Bus Configuration

PS[1:0]=00 I2C Master Mode for EEPROM

PS[1:0]=01 Reserved

PS[1:0]=10 SPI Slave Mode for CPU Interface

PS[1:0]=11 Factory Test Mode (BIST)

47 PWRDN_N Ipu Full-chip power down. Active low.

48 RESERVE NC Reserved pin. No connect.

115 RST_N Ipu Reset the KS8995MA. Active low.

5RXM1 I 1 Physical receive signal – (differential).

11 RXM2 I 2 Physical receive signal – (differential).

20 RXM3 I 3 Physical receive signal – (differential).

26 RXM4 I 4 Physical receive signal – (differential).

33 RXM5 I 5 Physical receive signal – (differential).

4RXP1 I 1 Physical receive signal + (differential).

10 RXP2 I 2 Physical receive signal + (differential).

19 RXP3 I 3 Physical receive signal + (differential).

25 RXP4 I 4 Physical receive signal + (differential).

32 RXP5 I 5 Physical receive signal + (differential).

119 SCANEN Ipd NC for normal operation. Factory test pin.

84 SCOL Ipd/O Switch MII collision detect.

87 SCONF0 Ipd Dual MII configuration pin.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

NC = No connect.

KS8995MA Micrel, Inc.

M9999-051305 18 May 2005

Pin Number Pin Name Type(1) Port Pin Function(2)

86 SCONF1 Ipd Dual MII configuration pin.

Pin (91, 86, 87): Switch MII PHY [5] MII

000 Disable, Otri Disable, Otri

001 PHY Mode MII Disable, Otri

010 MAC Mode MII Disable, Otri

011 PHY Mode SNI Disable, Otri

100 Disable Disable

101 PHY Mode MII PHY Mode MII

110 MAC Mode MII PHY Mode MII

111 PHY Mode SNI PHY Mode MII

85 SCRS Ipd/O Switch MII carrier sense.

78 SMRXC I/O Switch MII receive clock. Input in MAC mode, output in PHY mode MII.

83 SMRXD0 Ipd/O Switch MII receive bit 0; strap option: LED mode

PD (default) = mode 0; PU = mode 1. See “Register 11.”

Mode 0 Mode 1

LEDX_2 Lnk/Act 100Lnk/Act

LEDX_1 Fulld/Col 10Lnk/Act

LEDX_0 Speed Full duplex

82 SMRXD1 Ipd/O Switch MII receive bit 1. Strap option: PD (default) = switch MII in

100Mbps mode; PU = switch MII in 10Mbps mode.

81 SMRXD2 Ipd/O Switch MII receive bit 2. Strap option: PD (default) = switch MII in

full-duplex mode; PU = switch MII in half-duplex mode.

80 SMRXD3 Ipd/O Switch MII receive bit 3. Strap option: PD (default) = disable switch

MII full-duplex flow control; PU = enable switch MII full-duplex flow control.

79 SMRXDV Ipd/O Switch MII receive data valid.

75 SMTXC I/O Switch MII transmit clock. Input in MAC mode, output in PHY mode MII.

73 SMTXD0 Ipd Switch MII transmit bit 0.

72 SMTXD1 Ipd Switch MII transmit bit 1.

71 SMTXD2 Ipd Switch MII transmit bit 2.

70 SMTXD3 Ipd Switch MII transmit bit 3.

69 SMTXEN Ipd Switch MII transmit enable.

74 SMTXER Ipd Switch MII transmit error.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

Otri = Output tristated.

NC = No connect.

2. PU = Strap pin pull-up.

PD = Strap pin pull-down.

Fulld = Full duplex.

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Pin Number Pin Name Type(1) Port Pin Function

110 SPIC/SCL I/O All (1) Input clock up to 5MHz in SPI slave mode; (2) Output clock at 81kHz

in I2C master mode. See “Pin 113.”

111 SPID/SDA I/O All (1) Serial data input in SPI slave mode; (2) Serial data input/output in

I2C master mode. See “Pin 113.”

109 SPIQ Otri All (1) SPI serial data output in SPI slave mode; (2) Not used in I2C master

mode. See “Pin 113.”

112 SPIS_N Ipu All Active low. (1) SPI data transfer start in SPI slave mode. When SPIS_N

is high, the KS8995MA is deselected and SPIQ is held in high

impedance state, a high-to-low transition to initiate the SPI data

transfer; (2) Not used in I2C master mode.

128 TEST2 NC No connect for normal operation. Factory test pin.

118 TESTEN Ipd No connect for normal operation. Factory test pin.

8TXM1 O 1 Physical transmit signal – (differential).

14 TXM2 O 2 Physical transmit signal – (differential).

23 TXM3 O 3 Physical transmit signal – (differential).

29 TXM4 O 4 Physical transmit signal – (differential).

36 TXM5 O 5 Physical transmit signal – (differential).

7TXP1 O 1 Physical transmit signal + (differential).

13 TXP2 O 2 Physical transmit signal + (differential).

22 TXP3 O 3 Physical transmit signal + (differential).

28 TXP4 O 4 Physical transmit signal + (differential).

35 TXP5 O 5 Physical transmit signal + (differential).

123 VDDAP P 1.8V analog VDD for PLL.

41 VDDAR P 1.8V analog VDD.

43 VDDAR P 1.8V analog VDD.

3VDDAR P 1.8V analog VDD.

15 VDDAR P 1.8V analog VDD.

31 VDDAR P 1.8V analog VDD.

125 VDDAR P 1.8V analog VDD.

18 VDDAT P 2.5V or 3.3V analog VDD.

9VDDAT P 2.5V or 3.3V analog VDD.

24 VDDAT P 2.5V or 3.3V analog VDD.

37 VDDAT P 2.5V or 3.3V analog VDD.

50 VDDC P 1.8V digital core VDD.

Note:

1. P = Power supply.

I = Input.

O = Output.

I/O = Bidirectional.

Gnd = Ground.

Ipu = Input w/ internal pull-up.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

Otri = Output tristated.

NC = No connect.

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M9999-051305 20 May 2005

Pin Number Pin Name Type(1) Port Pin Function

89 VDDC P 1.8V digital core VDD.

117 VDDC P 1.8V digital core VDD.

59 VDDIO P 3.3V digital VDD for digital I/O circuitry.

77 VDDIO P 3.3V digital VDD for digital I/O circuitry.

100 VDDIO P 3.3V digital VDD for digital I/O circuitry.

121 X1 I 25MHz crystal clock connection/or 3.3V tolerant oscillator input.

Oscillator should be ±100ppm.

122 X2 O 25MHz crystal clock connection.

Note:

1. P = Power supply.

I = Input.

O = Output.

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Pin Configuration

MDIXDIS

GNDA

VDDAR

RXP1

RXM1

GNDA

TXP1

TXM1

VDDAT

RXP2

RXM2

GNDA

TXP2

TXM2

VDDAR

GNDA

ISET

VDDAT

RXP3

RXM3

GNDA

TXP3

TXM3

VDDAT

RXP4

RXM4

GNDA

TXP4

TXM4

GNDA

VDDAR

RXP5

RXM5

GNDA

TXP5

TXM5

VDDAT

FXSD5

LED2-1

LED2-2

VDDIO

GNDD

LED3-0

LED3-1

LED3-2

LED4-0

LED4-1

LED4-2

LED5-0

LED5-1

LED5-2

VDDC

GNDD

SCONF0

SCONF1

SCRS

SCOL

SMRXD0

SMRXD1

SMRXD2

SMRXD3

SMRXDV

SMRXC

VDDIO

GNDD

SMTXC

SMTXER

SMTXD0

SMTXD1

SMTXD2

SMTXD3

SMTEXN

PCOL

PCRS

PMRXER

PMRXD0

PMRXD1

PMRXD2

PMRXD3

PMRXDV

PMRXC

VDDIO

GNDD

PMTXC

PMTXER

PMTXD0

PMTXD1

PMTXD2

PMTXD3

PMTXEN

VDDC

GNDD

RESERVE

PWRDN_N

MUX2

MUX1

GNDA

VDDAR

GNDA

VDDAR

GNDA

FXSD4

LED2-0

LED1-2

LED1-1

LED1-0

MDC

MDIO

SPIQ

SPIC/SCL

SPID/SDA

SPIS_N

PS1

PS0

RST_N

GNDD

VDDC

TESTEN

SCANEN

VDDAP

GNDA

VDDAR

GNDA

TEST2

103

128-Pin PQFP (PQ)

KS8995MA Micrel, Inc.

M9999-051305 22 May 2005

Introduction

The KS8995MA contains five 10/100 physical layer transceivers and five media access control (MAC) units with an integrated

Layer 2 managed switch. The device runs in three modes. The first mode is as a five-port integrated switch. The second is

as a five-port switch with the fifth port decoupled from the physical port. In this mode, access to the fifth MAC is provided through

a media independent interface (MII) . This is useful for implementing an integrated broadband router. The third mode uses the

dual MII feature to recover the use of the fifth PHY. This allows the additional broadband gateway configuration, where the fifth

PHY may be accessed through the MII-P5 port.

The KS8995MA has the flexibility to reside in a managed or unmanaged design. In a managed design, a host processor has

complete control of the KS8995MA via the SPI bus, or partial control via the MDC/MDIO interface. An unmanaged design is

achieved through I/O strapping or EEPROM programming at system reset time.

On the media side, the KS8995MA supports IEEE 802.3 10BASE-T, 100BASE-TX on all ports, and 100BASE-FX on ports 4

and 5. The KS8995MA can be used as two separate media converters.

Physical signal transmission and reception are enhanced through the use of patented analog circuitry that makes the design

more efficient and allows for lower power consumption and smaller chip die size.

The major enhancements from the KS8995E to the KS8995MA are support for host processor management, a dual MII

interface, tag as well as port based VLAN, spanning tree protocol support, IGMP snooping support, port mirroring support and

rate limiting functionality.

Functional Overview: Physical Layer Transceiver

100BASE-TX Transmit

The 100BASE-TX transmit function performs parallel-to-serial conversion, 4B/5B coding, scrambling, NRZ-to-NRZI conver-

sion, MLT3 encoding and transmission. The circuit 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 external 1% 3.01kΩ resistor for the 1:1 transformer ratio. It 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 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

starts 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 length of the cable, the equalizer has to adjust its characteristics to

optimize the performance. In this design, the variable equalizer will make an initial estimation based on comparisons of

incoming signal strength against some known cable characteristics, then tunes itself for optimization. This is an ongoing

process and can self-adjust against environmental changes such as temperature variations.

The equalized signal then goes through a DC restoration and data conversion block. The DC restoration circuit is used to

compensate for the effect of baseline wander and 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. The signal is then 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.

PLL Clock Synthesizer

The KS8995MA generates 125MHz, 42MHz, 25MHz, and 10MHz clocks for system timing. Internal clocks are generated from

an external 25MHz crystal or oscillator.

Scrambler/De-scrambler (100BASE-TX only)

The purpose of the scrambler is to spread the power spectrum of the signal in order to reduce EMI and baseline wander. The

data is scrambled through the use of an 11-bit wide linear feedback shift register (LFSR). This can generate a 2047-bit non-

repetitive sequence. The receiver will then de-scramble the incoming data stream with the same sequence at the transmitter.

100BASE-FX Operation

100BASE-FX operation is very similar to 100BASE-TX operation except that the scrambler/de-scrambler and MLT3 encoder/

decoder are bypassed on transmission and reception. In this mode the auto-negotiation feature is bypassed since there is no

standard that supports fiber auto-negotiation.

100BASE-FX Signal Detection

The physical port runs in 100BASE-FX mode if FXSDx >0.6V for ports 4 and 5 only. This signal is internally referenced to 1.25V.

The fiber module interface should be set by a voltage divider such that FXSDx ‘H’ is above this 1.25V reference, indicating signal

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KS8995MA Micrel, Inc.

detect, and FXSDx ‘L’ is below the 1.25V reference to indicate no signal. When FXSDx is below 0.6V then 100BASE-FX mode

is disabled. Since there is no auto-negotiation for 100BASE-FX mode, ports 4 and 5 must be forced to either full or half-duplex.

Note that strap-in options exist to set duplex mode for port 4, but not for port 5.

100BASE-FX Far End Fault

Far end fault occurs when the signal detection is logically false from the receive fiber module. When this occurs, the

transmission side signals the other end of the link by sending 84 1s followed by a zero in the idle period between frames. The

far end fault may be disabled through register settings.

10BASE-T Transmit

The output 10BASE-T driver is incorporated into the 100BASE-T driver to allow transmission with the same magnetics. They

are internally wave-shaped and pre-emphasized into outputs with a typical 2.3V amplitude. The harmonic contents are at least

27dB below the fundamental when driven by an all-ones Manchester-encoded signal.

10BASE-T Receive

On the receive side, input buffer and level detecting squelch circuits are employed. A differential input receiver circuit and a

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 pulsewidths in order to prevent noises 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 KS8995MA decodes a data frame. The receiver clock is maintained active during idle periods in between data

reception.

Power Management

The KS8995MA features a per port power down mode. To save power the user can power down ports that are not in use by

setting port control registers or MII control registers. In addition, it also supports full chip power down mode. When activated,

the entire chip will be shutdown.

MDI/MDI-X Auto Crossover

The KS8995MA supports MDI/MDI-X auto crossover. This facilitates the use of either a straight connection CAT-5 cable or

a crossover CAT-5 cable. The auto-sense function will detect remote transmit and receive pairs, and correctly assign the

transmit and receive pairs from the Micrel device. This can be highly useful when end users are unaware of cable types and

can also save on an additional uplink configuration connection. The auto crossover feature may be disabled through the port

control registers.

Auto-Negotiation

The KS8995MA conforms to the auto-negotiation protocol as described by the 802.3 committee. 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 KS8995MA

is forced to bypass auto-negotiation, then 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 flow for the link setup is shown in Figure 4.

Start

Auto Negotiation

Force Link Setting

Listen for 10BASE-T

Link Pulses

Listen for

100BASE-TX Idles

Attempt

Auto-Negotiation

Link Mode Set

Bypass

Auto-Negotiation

and Set Link Mode

Link Mode Set ?

Parallel

Operation

Join Flow

Ye s

Figure 4. Auto-Negotiation

KS8995MA Micrel, Inc.

M9999-051305 24 May 2005

Functional Overview: Switch Core

Address Look-Up

The internal look-up table stores MAC addresses and their associated information. It contains a 1K unicast address table plus

switching information. The KS8995MA is guaranteed to learn 1K addresses and distinguishes itself from a hash-based look-

up table, which depending on the operating environment and probabilities, may not guarantee the absolute number of

addresses it can learn.

Learning

The internal look-up engine updates its table with a new entry if the following conditions are met:

•The received packet’s source address (SA) does not exist in the look-up table.

•The received packet is good; the packet has no receiving errors and is of legal length.

The look-up engine inserts the qualified SA into the table, along with the port number and time stamp. If the table is full, the

last entry of the table is deleted first to make room for the new entry.

Migration

The internal look-up engine also monitors whether a station is moved. If this occurs, it updates the table accordingly. Migration

happens when the following conditions are met:

•The received packet’s SA is in the table but the associated source port information is different.

•The received packet is good; the packet has no receiving errors and is of legal length.

The look-up engine will update the existing record in the table with the new source port information.

Aging

The look-up engine will update 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 will remove the record from the

table. The look-up engine constantly performs the aging process and will continuously remove aging records. The aging period

is 300 + 75 seconds. This feature can be enabled or disabled through Register 3 or by external pull-up or pull-down resistors

on LED[5][2]. See “Register 3” section.

Forwarding

The KS8995MA will forward packets using an algorithm that is depicted in the following flowcharts. Figure 5 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 the spanning tree, IGMP snooping,

port mirroring, and port VLAN processes to come up with “port to forward 2” (PTF2), as shown in Figure 6. This is where the

packet will be sent.

KS8995MA will not forward the following packets:

•Error packets. These include framing errors, FCS errors, alignment errors, and illegal size packet errors.

•802.3x pause frames. The KS8995MA will intercept these packets and perform the appropriate actions.

•“Local” packets. Based on destination address (DA) look-up. If the destination port from the look-up table matches

the port where the packet was from, the packet is defined as “local”.

Switching Engine

The KS8995MA 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 KS8995MA has a 64kB internal frame buffer. This resource is shared between all five ports. The buffer sharing mode can

be programmed through Register 2. See “Register 2.” In one mode, ports are allowed to use any free buffers in the buffer pool.

In the second mode, each port is only allowed to use 1/5 of the total buffer pool. There are a total of 512 buffers available. Each

buffer is sized at 128B.

Media Access Controller (MAC) Operation

The KS8995MA strictly abides by IEEE 802.3 standards to maximize compatibility.

Inter Packet Gap (IPG)

If a frame is successfully transmitted, the 96-bit time IPG is measured between the two consecutive MTXEN. If the current

packet is experiencing collision, the 96-bit time IPG is measured from MCRS and the next MTXEN.

Backoff Algorithm

The KS8995MA implements the IEEE Std 802.3 binary exponential back-off algorithm, and optional “aggressive mode” back

off. After 16 collisions, the packet will be optionally dropped depending on the chip configuration in Register 3. See “Register

3.”

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Spanning Tree

Process

PTF1

IGMP Process

Port Mirror

Process

Port VLAN

Membership

Check

PTF2

-Check receiving port's receive enable bit

-Check destination port's transmit enable bit

-Check whether packets are special (BPDU

or specified)

-Applied to MAC #1 to #4

-MAC#5 is reserved for microprocessor

-IGMP will be forwarded to port 5

-RX Mirror

-TX Mirror

-RX or TX Mirror

-RX and TX Mirror

Figure 6. DA Resolution Flowchart–Stage 2

Start

VLAN ID

VALID?

PTF1=NULL

Search Static

Table

Search complete.

Get PTF1 from

static table.

Dynamic

Table

Search complete.

Get PTF1 from

VLAN table.

Search complete.

Get PTF1 from

dynamic table.

PTF1

-Search VLAN table.

-Ingress VLAN filtering

-Discard NPVID check

YES

FOUND

NOT

FOUND

NOT

FOUND

Search based on

DA or DA+FID

This search is based on

DA+FID

Figure 5. DA Look-Up Flowchart–Stage 1

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Late Collision

If a transmit packet experiences collisions after 512-bit times of the transmission, the packet is dropped.

Illegal Frames

The KS8995MA discards frames of less than 64 bytes and can be programmed to accept frames up to 1536 bytes in Register

4. For special applications, the KS8995MA can also be programmed to accept frames up to 1916 bytes in Register 4. Since

the KS8995MA supports VLAN tags, the maximum size is adjusted when these tags are present.

Flow Control

The KS8995MA supports standard 802.3x flow control frames on both transmit and receive sides.

On the receive side, if the KS8995MA receives a pause control frame, the KS8995MA 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 given in the second pause frame. During this period of flow control, only flow

controlled packets from the KS8995MA are transmitted.

On the transmit side, the KS8995MA 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 KS8995MA flow controls a port that has just received a packet if the destination port resource is busy. The KS8995MA

issues a flow control frame (XOFF), containing the maximum pause time defined in IEEE standard 802.3x. Once the resource

is freed up, the KS8995MA 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 also provided to prevent over-activation and deactivation of the flow control

mechanism.

The KS8995MA flow controls all ports if the receive queue becomes full.

Half-Duplex Back Pressure

The KS8995MA also provides a half-duplex back pressure option (note: this is not in IEEE 802.3 standards). The activation

and deactivation conditions are the same as the ones given for full-duplex mode. If back pressure is required, the KS8995MA

sends preambles to defer the other station's transmission (carrier sense deference). To avoid jabber and excessive deference

as defined in IEEE 802.3 standard, after a certain period of time, the KS8995MA discontinues carrier sense but raises it quickly

after it drops packets to inhibit other transmissions. This short silent time (no carrier sense) is to prevent other stations from

sending out packets and keeps other stations in a carrier sense deferred state. If the port has packets to send during a back

pressure situation, the carrier-sense-type back pressure is interrupted and those packets are transmitted instead. If there are

no more packets to send, carrier-sense-type back pressure becomes active again until switch resources are free. If a collision

occurs, the binary exponential backoff algorithm is skipped and carrier sense is generated immediately, reducing the chance

of further colliding and maintaining carrier sense to prevent reception of packets.

To ensure no packet loss in 10BASE-T or 100BASE-TX half-duplex modes, the user must enable the following:

•Aggressive backoff (Register 3, bit 0)

•No excessive collision drop (Register 4, bit 3)

•Back pressure (Register 4, bit 5)

These bits are not set as the default because this is not the IEEE standard.

Broadcast Storm Protection

The KS8995MA has an intelligent option to protect the switch system from receiving too many broadcast packets. Broadcast

packets are normally forwarded to all ports except the source port and thus use too many switch resources (bandwidth and

available space in transmit queues). The KS8995MA 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. The rate is based

on a 50ms interval for 100BT and a 500ms 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 Registers

6 and 7. The default setting for Registers 6 and 7 is 0x4A (74 decimal). This is equal to a rate of 1%, calculated as follows:

148,800 frames/sec ¥ 50ms/interval ¥ 1% = 74 frames/interval (approx.) = 0x4A

MII Interface Operation

The media independent interface (MII) is specified by the IEEE 802.3 committee and provides a common interface between

physical layer and MAC layer devices. The KS8995MA provides two such interfaces. The MII-P5 interface is used to connect

to the fifth PHY, whereas the MII-SW interface is used to connect to the fifth MAC. Each of these MII interfaces contains two

distinct groups of signals, one for transmission and the other for receiving. Table 1 describes the signals used in the MII-P5

interface.

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PHY Mode Connection MAC Mode Connection

External KS8995MA External KS8995MA

MAC Signal Description PHY Signal

MTXEN SMTXEN Transmit enable MTXEN SMRXDV

MTXER SMTXER Transmit error MTXER Not used

MTXD3 SMTXD[3] Transmit data bit 3 MTXD3 SMRXD[3]

MTXD2 SMTXD[2] Transmit data bit 2 MTXD2 SMRXD[2]

MTXD1 SMTXD[1] Transmit data bit 1 MTXD1 SMRXD[1]

MTXD0 SMTXD[0] Transmit data bit 0 MTXD0 SMRXD[0]

MTXC SMTXC Transmit clock MTXC SMRXC

MCOL SCOL Collision detection MCOL SCOL

MCRS SCRS Carrier sense MCRS SCRS

MRXDV SMRXDV Receive data valid MRXDV SMTXEN

MRXER Not used Receive error MRXER SMTXER

MRXD3 SMRXD[3] Receive data bit 3 MRXD3 SMTXD[3]

MRXD2 SMRXD[2] Receive data bit 2 MRXD2 SMTXD[2]

MRXD1 SMRXD[1] Receive data bit 1 MRXD1 SMTXD[1]

MRXD0 SMRXD[0] Receive data bit 0 MRXD0 SMTXD[0]

MRXC SMRXC Receive clock MRXC SMTXC

Table 2. MII – SW Signals

SNI Signal Description KS8995MA Signal

MTXEN Transmit enable PMTXEN

MTXER Transmit error PMTXER

MTXD3 Transmit data bit 3 PMTXD[3]

MTXD2 Transmit data bit 2 PMTXD[2]

MTXD1 Transmit data bit 1 PMTXD[1]

MTXD0 Transmit data bit 0 PMTXD[0]

MTXC Transmit clock PMTXC

MCOL Collision detection PCOL

MCRS Carrier sense PCRS

MRXDV Receive data valid PMRXDV

MRXER Receive error PMRXER

MRXD3 Receive data bit 3 PMRXD[3]

MRXD2 Receive data bit 2 PMRXD[2]

MRXD1 Receive data bit 1 PMRXD[1]

MRXD0 Receive data bit 0 PMRXD[0]

MRXC Receive clock PMRXC

MDC Management data clock MDC

MDIO Management data I/O MDIO

Table 1. MII – P5 Signals (PHY Mode)

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The MII-P5 interface operates in PHY mode only, while the MII-SW interface operates in either MAC mode or PHY mode. These

interfaces are nibble-wide data interfaces and therefore run at 1/4 the network bit rate (not encoded). Additional signals on the

transmit side indicate when data is valid or when an error occurs during transmission. Likewise, the receive side has indicators

that convey when the data is valid and without physical layer errors. For half-duplex operation there is a signal that indicates

a collision has occurred during transmission.

Note that the signal MRXER is not provided on the MII-SW interface for PHY mode operation and the signal MTXER is not

provided on the MII-SW interface for MAC mode operation. Normally MRXER would indicate a receive error coming from the

physical layer device. MTXER would indicate a transmit error from the MAC device. These signals are not appropriate for this

configuration. For PHY mode operation, if the device interfacing with the KS8995MA has an MRXER pin, it should be tied low.

For MAC mode operation, if the device interfacing with the KS8995MA has an MTXER pin, it should be tied low.

SNI Interface Operation

The serial network interface (SNI) is compatible with some controllers used for network layer protocol processing. This interface

can be directly connected to these types of devices. The signals are divided into two groups, one for transmission and the other

for reception. The signals involved are described in Table 3.

SNI Signal Description KS8995MA Signal

TXEN Transmit enable SMTXEN

TXD Serial transmit data SMTXD[0]

TXC Transmit clock SMTXC

COL Collision detection SCOL

CRS Carrier sense SMRXDV

RXD Serial receive data SMRXD[0]

RXC Receive clock SMRXC

Table 3. SNI Signals

This interface is a bit-wide data interface and therefore runs at the network bit rate (not encoded). An additional signal on the

transmit side indicates when data is valid. Likewise, the receive side also has an indicator that shows if the data it is receiving

is valid.

For half-duplex operation, there is a signal that indicates if a collision has occurred during transmission.

Advanced Functionality

Spanning Tree Support

Port 5 is the designated port for spanning tree support.

The other ports (port 1 – port 4) can be configured in one of the five spanning tree states via “transmit enable,” “receive enable,”

and “learning disable” register settings in Registers 18, 34, 50, and 66 for ports 1, 2, 3, and 4, respectively. The following

description 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.

Port setting: "transmit enable = 0, receive enable = 0, learning disable = 1."

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 table with “overriding bit” set) and the processor should discard those

packets. Note: processor is connected to port 5 via MII interface. Address learning is disabled on the port in this state.

Blocking state: only packets to the processor are forwarded. Learning is disabled.

Port setting: "transmit enable = 0, receive enable = 0, learning disable = 1"

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 (e.g., 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.

Listening state: only packets to and from the processor are forwarded. Learning is disabled.

Port setting: "transmit enable = 0, receive enable = 0, learning disable = 1."

Software action: The processor should program the static MAC table with the entries that it needs to receive (e.g. 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, see “Special Tagging Mode” section for details. Address learning is disabled on

the port in this state.

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Learning state: only packets to and from the processor are forwarded. Learning is enabled.

Port setting: “transmit enable = 0, receive enable = 0, learning disable = 0.”

Software action: The processor should program the static MAC table with the entries that it needs to receive (e.g., 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, see “Special Tagging Mode” section for details. Address learning is enabled on

the port in this state.

Forwarding state: packets are forwarded and received normally. Learning is enabled.

Port setting: “transmit enable = 1, receive enable = 1, learning disable = 0.”

Software action: The processor should program the static MAC table with the entries that it needs to receive (e.g., 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, see “Special Tagging Mode” section for details. Address learning is enabled on

the port in this state.

Special Tagging Mode

The special tagging mode is designed for spanning tree protocol IGMP snooping and is flexible for use in other applications.

The special tagging mode, similar to 802.1q, requires software to change network drivers to insert/modify/strip/interpret the

special tag. This mode is enabled by setting both Register 11 bit 0 and Register 80 bit 2.

802.1q Tag Format Special Tag Format

TPID (tag protocol identifier, 0x8100) + TCI STPID (special tag identifier, 0x8100) + TCI 0x810 + 4 bit for “port mask”) + TCI

Table 4. Special Tagging Mode Format

The STPID will only be seen and used on the port 5 interface, which should be connected to a processor. Packets from the

processor to the switch should be tagged with STPID and the port mask defined as below:

“0001” packet to port 1 only

“0010” packet to port 2 only

“0100” packet to port 3 only

“1000” packet to port 4 only

“0011” packet broadcast to port 1 and port 2.

.....

“1111” packet broadcast to port 1, 2, 3 and 4.

“0000” normal tag, will use the KS8995MA internal look-up result. Normal packets should use this setting. If packets from the

processors do not have a tag, the KS8995MA will treat them as normal packets and an internal look-up will be performed.

The KS8995MA uses a non-zero “port mask” to bypass the look-up result and override any port setting, regardless of port states

(blocking, disable, listening, learning). Table 5 shows the egress rules when dealing with STPID.

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Tx Port Tx Port

Ingress Tag Field “Tag Insertion” “Tag Removal” Egress Action to Tag Field

(0x810+ port mask) 0 0 • Modify tag field to 0x8100.

•Recalculate CRC.

•No change to TCI if not null VID.

•Replace VID with ingress (port 5) port VID if null VID.

(0x810+ port mask) 0 1 • (STPID + TCI) will be removed.

•Padding to 64 bytes if necessary.

•Recalculate CRC.

(0x810+ port mask) 1 0 • Modify tag field to 0x8100.

•Recalculate CRC.

•No change to TCI if not null VID.

•Replace VID with ingress (port 5) port VID if null VID.

(0x810+ port mask) 1 1 • Modify tag field to 0x8100.

•Recalculate CRC.

•No change to TCI if not null VID.

•Replace VID with ingress (port 5) port VID if null VID.

Not tagged Don’t care Don’t care Determined by the dynamic MAC address table.

Table 5. STPID Egress Rules (Processor to Switch Port 5)

For packets from regular ports (port 1 - port 4) to port 5, the port mask is used to tell the processor which port the packet was

received on, defined as:

“0001” from port 1,

“0010” from port 2,

“0100” from port 3,

“1000” from port 4

No values other than the previous four defined should be received in this direction in the special mode. Table 6 shows the egress

rule for this direction.

Ingress Packets Egress Action to Tag Field

Tagged with 0x8100 + TCI • Modify TPID to 0x810 + “port mask,” which indicates source port.

•No change to TCI, if VID is not null.

•Replace null VID with ingress port VID.

•Recalculate CRC.

Not tagged • Insert TPID to 0x810 + “port mask,” which indicates source port.

•Insert TCI with ingress port VID.

•Recalculate CRC.

Table 6. STPID Egress Rules (Switch to Processor)

IGMP Support

There are two parts involved to support IGMP in Layer 2. The first part is “IGMP” snooping. The switch will trap IGMP packets

and forward them only to the processor port. The IGMP packets are identified as IP packets (either Ethernet IP packets or IEEE

802.3 SNAP IP packets) AND IP version = 0x4 AND protocol number = 0x2. The second part is “multicast address insertion”

in the static MAC table. Once the multicast address is programmed in the static MAC table, the multicast session will be trimmed

to the subscribed ports, instead of broadcasting to all ports. To enable this feature, set Register 5 bit 6 to 1. Also “special tag

mode” needs to be enabled, so that the processor knows which port the IGMP packet was received on. Enable “special tag

mode” by setting both Register 11 bit 0 and Register 80 bit 2.

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Port Mirroring Support

KS8995MA supports “port mirror” comprehensively as:

1. “Receive Only” mirror on a port. All the packets received on the port will be mirrored on the sniffer port. For example,

port 1 is programmed to be “rx sniff,” and port 5 is programmed to be the “sniffer port.” A packet, received on port

1, is destined to port 4 after the internal look-up. The KS8995MA will forward the packet to both port 4 and port 5.

KS8995MA can optionally forward even “bad” received packets to port 5.

2. “Transmit Only” mirror on a port. All the packets transmitted on the port will be mirrored on the sniffer port. For

example, port 1 is programmed to be “tx sniff,” and port 5 is programmed to be the “sniffer port.” A packet, received

on any of the ports, is destined to port 1 after the internal look-up. The KS8995MA will forward the packet to both

ports 1 and 5.

3. “Receive and Transmit” mirror on two ports. All the packets received on port A AND transmitted on port B will be

mirrored on the sniffer port. To turn on the “AND” feature, set Register 5 bit 0 to 1. For example, port 1 is programmed

to be “rx sniff,” port 2 is programmed to be “transmit sniff,” and port 5 is programmed to be the “sniffer port.” A packet,

received on port 1, is destined to port 4 after the internal look-up. The KS8995MA will forward the packet to port 4

only, since it does not meet the “AND” condition. A packet, received on port 1, is destined to port 2 after the internal

look-up. The KS8995MA will forward the packet to both port 2 and port 5.

Multiple ports can be selected to be “rx sniffed” or “tx sniffed.” And any port can be selected to be the “sniffer port.” All these

per port features can be selected through Register 17.

VLAN Support

KS8995MA supports 16 active VLANs out of 4096 possible VLANs specified in IEEE 802.1q. KS8995MA provides a 16-entry

VLAN table, which converts VID (12 bits) to FID (4 bits) for address look-up. If a non-tagged or null-VID-tagged packet is

received, the ingress port VID is used for look-up. In the VLAN mode, the look-up process starts with VLAN table look-up to

determine whether the VID is valid. If the VID is not valid, the packet will be dropped and its address will not be learned. If the

VID is valid, FID is retrieved for further look-up. FID+DA is used to determine the destination port. FID+SA is used for learning

purposes.

DA found in DA+FID found in

Static MAC table USE FID Flag? FID Match? Dynamic MAC table Action

No Don’t care Don’t care No Broadcast to the membership ports defined in the

VLAN table bit [20:16].

No Don’t care Don’t care Yes Send to the destination port defined in the

dynamic MAC table bit [54:52].

Yes 0 Don’t care Don’t care Send to the destination port(s) defined in the

static MAC table bit [52:48].

Yes 1 No No Broadcast to the membership ports defined in

the VLAN table bit [20:16].

Yes 1 No Yes Send to the destination port defined in the

dynamic MAC table bit [54:52].

Yes 1 Yes Don’t care Send to the destination port(s) defined in the

static MAC table bit [52:48].

Table 7. FID+DA Look-Up in the VLAN Mode

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SA+FID found in

Dynamic MAC table Action

No The SA+FID will be learned into the dynamic table.

Yes Time stamp will be updated.

Table 8. FID+SA Look-Up in the VLAN Mode

Advanced VLAN features are also supported in KS8995MA, such as “VLAN ingress filtering” and “discard non PVID” defined

in Register 18 bit 6 and bit 5. These features can be controlled on a port basis.

Rate Limit Support

KS8995MA supports hardware rate limiting on “receive” and “transmit” independently on a per port basis. It also supports rate

limiting in a priority or non-priority environment. The rate limit starts from 0Kbps and goes up to the line rate in steps of 32Kbps.

The KS8995MA uses one second as an interval. 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 this interval.

For receive, if the number of bytes exceeds the programmed limit, the switch will stop receiving packets on the port until the

“one second” interval expires. There is an option provided for flow control to prevent packet loss. If the rate limit is programmed

greater than or equal to 128Kbps and the byte counter is 8K bytes below the limit, the flow control will be triggered. If the rate

limit is programmed lower than 128Kbps and the byte counter is 2K bytes below the limit, the flow control will be triggered.

For transmit, if the number of bytes exceeds the programmed limit, the switch will stop transmitting packets on the port until

the “one second” interval expires.

If priority is enabled, the KS8995MA can support different rate controls for both high priority and low priority packets. This can

be programmed through Registers 21–27.

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Configuration Interface

The KS8995MA can function as a managed switch or unmanaged switch. If no EEPROM or micro-controller exists, the

KS8995MA will operate from its default setting. Some default settings are configured via strap in options as indicated in the

table below.

Pin # Pin Name PU/PD(1) Description(1)

1MDI-XDIS Ipd Disable auto MDI/MDI-X.

PD = (default) = normal operation.

PU = disable auto MDI/MDI-X on all ports.

45 MUX1 NC Factory test pins. MUX1 and MUX2 should be left unconnected for normal operation.

46 MUX2 NC

Mode MUX1 MUX2

Normal Operation NC NC

62 PMRXD3 Ipd/O PHY[5] MII receive bit 3. Strap option: PD (default) = enable flow control;

PU = disable flow control.

63 PMRXD2 Ipd/O PHY[5] MII receive bit 2. Strap option: PD (default) = disable back pressure;

PU = enable back pressure.

64 PMRXD1 Ipd/O PHY[5] MII receive bit 1. Strap option: PD (default) = drop excessive collision

packets; PU = does not drop excessive collision packets.

65 PMRXD0 Ipd/O PHY[5] MII receive bit 0. Strap option: PD (default) = disable aggressive back-off

algorithm in half-duplex mode; PU = enable for performance enhancement.

66 PMRXER Ipd/O PHY[5] MII receive error. Strap option: PD (default) = 1522/1518 bytes;

PU = packet size up to 1536 bytes.

67 PCRS Ipd/O PHY[5] MII carrier sense/force duplex mode. See “Register 76” for port 4 only.

PD (default) = force half-duplex if auto-negotiation is disabled or fails. PU = force

full-duplex if auto-negotiation is disabled or fails.

68 PCOL Ipd/O PHY[5] MII collision detect/force flow control. See “Register 66” for port 4 only.

PD (default) = no force flow control. PU = force flow control.

80 SMRXD3 Ipd/O Switch MII receive bit 3. Strap option: PD (default) = disable switch MII full-duplex

flow control; PU = enable switch MII full-duplex flow control.

81 SMRXD2 Ipd/O Switch MII receive bit 2. Strap option: PD (default) = switch MII in full-duplex mode;

PU = switch MII in half-duplex mode.

82 SMRXD1 Ipd/O Switch MII receive bit 1. Strap option: PD (default) = switch MII in 100Mbps mode;

PU = switch MII in 10Mbps mode.

83 SMRXD0 Ipd/O Switch MII receive bit 0; Strap option: LED mode PD (default) = mode 0;

PU = mode 1. See “Register 11.”

Mode 0 Mode 1

LEDX_2 Lnk/Act 100Lnk/Act

LEDX_1 Fulld/Col 10Lnk/Act

LEDX_0 Speed Fulld

Note:

1. NC = No connect.

Ipd = Input w/ internal pull-down.

Ipd/O = Input w/ internal pull-down during reset, output pin otherwise.

Fulld = Full duplex.

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Pin # Pin Name PU/PD(1) Description1)

86 SCONF1 Ipd Dual MII configuration pin.

Pins 91, 86, 87 Switch MII PHY [5] MII

000 Disable, Otri Disable, Otri

001 PHY Mode MII Disable, Otri

010 MAC Mode MII Disable, Otri

011 PHY Mode SNI Disable, Otri

100 Disable Disable

101 PHY Mode MII PHY Mode MII

110 MAC Mode MII PHY Mode MII

111 PHY Mode SNI PHY Mode MII

87 SCONF0 Ipd Dual MII configuration pin.

90 LED5-2 Ipu/O LED indicator 2. Strap option: Aging setup. See “Aging” section

PU (default) = aging enable; PD = aging disable.

91 LED5-1 Ipu/O LED indicator 1. Strap option: PU (default): enable PHY MII I/F. PD: tristate all PHY

MII output. See “Pin 86 SCONF1.”

113 PS1 Ipd Serial bus configuration pin.

For this case, if the EEPROM is not present, the KS8995MA will start

itself with the PS[1:0] = 00 default register values .

Pin Configuration Serial Bus Configuration

PS[1:0]=00 I2C Master Mode for EEPROM

PS[1:0]=01 Reserved

PS[1:0]=10 SPI Slave Mode for CPU Interface

PS[1:0]=11 Factory Test Mode (BIST)

114 PS0 Ipd Serial bus configuration pin. See “Pin 113.”

128 TEST2 NC NC for normal operation. Factory test pin.

Note:

1. NC = No connect.

Ipd = Input w/ internal pull-down.

Ipu/O = Input w/ internal pull-up during reset, output pin otherwise.

Otri = Output tristated.

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I2C Master Serial Bus Configuration

If a 2-wire EEPROM exists, the KS8995MA can perform more advanced features like broadcast storm protection and rate

control. The EEPROM should have the entire valid configuration data from Register 0 to Register 109 defined in the “Memory

Map,” except the status registers. After reset, the KS8995MA will start to read all 110 registers sequentially from the EEPROM.

The configuration access time (tprgm) is less than 15ms as shown in Figure 7.

....

RST_N

SCL

SDA

prgm

<15 ms

Figure 7. KS8995MA EEPROM

Configuration Timing Diagram

To configure the KS8995MA with a pre-configured EEPROM use the following steps:

1. At the board level, connect pin 110 on the KS8995MA to the SCL pin on the EEPROM. Connect pin 111 on the

KS8995MA to the SDA pin on the EEPROM.

2. Set the input signals PS[1:0] (pins 113 and 114, respectively) to “00.” This puts the KS8995MA serial bus

configuration into I2C master mode.

3. Be sure the board-level reset signal is connected to the KS8995MA reset signal on pin 115 (RST_N).

4. Program the contents of the EEPROM before placing it on the board with the desired configuration data. Note that

the first byte in the EEPROM must be “95” for the loading to occur properly. If this value is not correct, all other data

will be ignored.

5. Place EEPROM on the board and power up the board. Assert the active-low board level reset to RST_N on the

KS8995MA. After the reset is de-asserted, the KS8995MA will begin reading configuration data from the EEPROM.

The configuration access time (tprgm) is less than 15ms.

Note: For proper operation, make sure that pin 47 (PWRDN_N) is not asserted during the reset operation.

SPI Slave Serial Bus Configuration

The KS8995MA can also act as an SPI slave device. Through the SPI, the entire feature set can be enabled, including “VLAN,”

“IGMP snooping,” “MIB counters,” etc. The external master device can access any register from Register 0 to Register 127

randomly. The system should configure all the desired settings before enabling the switch in the KS8995MA. To enable the

switch, write a "1" to Register 1 bit 0.

Two standard SPI commands are supported (00000011 for “READ DATA,” and 00000010 for “WRITE DATA”). To speed

configuration time, the KS8995MA also supports multiple reads or writes. After a byte is written to or read from the KS8995MA,

the internal address counter automatically increments if the SPI Slave Select Signal (SPIS_N) continues to be driven low. If

SPIS_N is kept low after the first byte is read, the next byte at the next address will be shifted out on SPIQ. If SPIS_N is kept

low after the first byte is written, bits on the Master Out Slave Input (SPID) line will be written to the next address. Asserting

SPIS_N high terminates a read or write operation. This means that the SPIS_N signal must be asserted high and then low again

before issuing another command and address. The address counter wraps back to zero once it reaches the highest address.

Therefore the entire register set can be written to or read from by issuing a single command and address.

The KS8995MA is able to support a 5MHz SPI bus. A high performance SPI master is recommended to prevent internal counter

overflow.

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To use the KS8995MA SPI:

1. At the board level, connect KS8995MA pins as follows:

KS8995MA KS8995MA Microprocessor Signal

Pin Number Signal Name Description

112 SPIS_N SPI Slave Select

110 SPIC SPI Clock

111 SPID Master Out Slave Input

109 SPIQ Master In Slave Output

Table 9. SPI Connections

2. Set the input signals PS[1:0] (pins 113 and 114, respectively) to “10” to set the serial configuration to SPI slave mode.

3. Power up the board and assert a reset signal. After reset wait 100µs, the start switch bit in Register 1 will be set to

‘0’. Configure the desired settings in the KS8995MA before setting the start register to ‘1.'

4. Write configuration to registers using a typical SPI write data cycle as shown in Figure 8 or SPI multiple write as shown

in Figure 10. Note that data input on SPID is registered on the rising edge of SPIC.

5. Registers can be read and configuration can be verified with a typical SPI read data cycle as shown in Figure 9 or

a multiple read as shown in Figure 11. Note that read data is registered out of SPIQ on the falling edge of SPIC.

6. After configuration is written and verified, write a ‘1’ to Register 1 bit 0 to begin KS8995MA operation.

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SPIQ

SPIC

SPID

SPIS_N

00000010X A7 A6 A5 A4 A3 A2 A1 A0

WRITE COMMAND WRITE ADDRESS WRITE DATA

D2 D0D1D3D4D5D6D7

Figure 8. SPI Write Data Cycle

SPIQ

SPIC

SPID

SPIS_N

00000011XA7 A6 A5 A4 A3 A2 A1 A0

D7 D6 D5 D4 D3 D2 D1 D0

READ COMMAND READ ADDRESS READ DATA

Figure 9. SPI Read Data Cycle

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SPIQ

SPIC

SPID

SPIS_N

00000010X A7 A6 A5 A4 A3 A2 A1 A0

WRITE COMMAND WRITE ADDRESS Byte 1

D2 D0D1D3D4D5D6D7

SPIQ

SPIC

SPID

SPIS_N

D7 D6 D5 D4 D4 D2 D1 D0 D7 D6 D5 D4 D3 D2 D1 D0

Byte 2 Byte 3 ... Byte N

D2 D0D1D3D4D5D6D7

Figure 10. SPI Multiple Write

SPIQ

SPIC

SPID

SPIS_N

00000011XA7 A6 A5 A4 A3 A2 A1 A0

D7 D6 D5 D4 D3 D2 D1 D0

READ COMMAND READ ADDRESS Byte 1

XXXXXXXXXXXXXXXX

Byte 2 Byte 3 ... Byte N

X X X X X X X X

XXXXXXXX

D7 D6 D5 D4 D3 D2 D1 D0

D7 D6 D5 D4 D3 D2 D1 D0 D7 D6 D5 D4 D3 D2 D1 D0

SPIQ

SPIC

SPID

SPIS_N

Figure 11. SPI Multiple Read

MII Management Interface (MIIM)

A standard MIIM interface is provided for all five PHY devices in the KS8995MA. An external device with MDC/MDIO capability

is able to read PHY status or to configure PHY settings. For details on the MIIM interface standard please reference the IEEE

802.3 specification (section 22.2.4.5). The MIIM interface does not have access to all the configuration registers in the

KS8995MA. It can only access the standard MII registers. See “MIIM Registers.” The SPI interface, on the other hand, can

be used to access the entire KS8995MA feature set.

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Offset

Decimal Hex Description

0-1 0x00-0x01 Chip ID Registers

2-11 0x02-0x0B Global Control Registers

12-15 0x0C-0x0F Reserved

16-29 0x10-0x1D Port 1 Control Registers

30-31 0x1E-0x2F Port 1 Status Registers

32-45 0x20-0x2D Port 2 Control Registers

46-47 0x2E-0x2F Port 2 Status Registers

48-61 0x30-0x3D Port 3 Control Registers

62-63 0x3E-0x3F Port 3 Status Registers

64-77 0x40-0x4D Port 4 Control Registers

78-79 0x4E-0x4F Port 4 Status Registers

80-93 0x50-0x5D Port 5 Control Registers

94-95 0x5E-0x5F Port 5 Status Registers

96-103 0x60-0x67 TOS Priority Control Registers

104-109 0x68-0x6D MAC Address Registers

110-111 0x6E-0x6F Indirect Access Control Registers

112-120 0x70-0x78 Indirect Data Registers

121-122 0x79-0x7A Digital Testing Status Registers

123-124 0x7B-0x7C Digital Testing Control Registers

125-126 0x7D-0x7E Analog Testing Control Registers

127 0x7F Analog Testing Status Register

Global Registers

Address Name Description Mode Default

7-0 Family ID Chip family. RO 0x95

7-4 Chip ID 0x0 is assigned to M series. (95MA) RO 0x0

3-1 Revision ID Revision ID RO 0x2

0Start Switch 1, start the chip when external pins (PS1, PS0) = (1,0) RW —

or (0,1). Note: in (PS1,PS0) = (0,0) mode, the chip will

start automatically, after trying to read the external

EEPROM. If EEPROM does not exist, the chip will use

default values for all internal registers. If EEPROM is

present, the contents in the EEPROM will be checked.

The switch will check: (1) Register 0 = 0x95,

(2) Register 1 [7:4] = 0x0. If this check is OK, the

contents in the EEPROM will override chip register

default values =0, chip will not start when external pins

(PS1, PS0) = (1,0) or (0,1).

Note: (PS1, PS0) = (1,1) for factory test only.

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Address Name Description Mode Default

7Reserved Reserved. R/W 0x0

6-4 802.1p Base Priority Used to classify priority for incoming 802.1q packets R/W 0x4

“User priority” is compared against this value

⊕ : classified as high priority.

< : classified as low priority.

3Enable PHY MII 1, enable PHY MII interface. R/W Pin LED[5][1]

Note: if not enabled, the switch will tri-state all outputs. strap option.

Pull-down (0):

isolate. Pull-up

(1): Enable.

Note: LED[5][1]

has internal

pull-up.

2Buffer Share Mode 1, buffer pool is shared by all ports. A port can use R/W 0x1

more buffer when other ports are not busy.

0, a port is only allowed to use 1/5 of the buffer pool.

1UNH Mode 1, the switch will drop packets with 0x8808 in T/L R/W 0

filed, or DA=01-80-C2-00-00-01.

0, the switch will drop packets qualified as “flow control”

packets.

0Link Change Age 1, link change from “link” to “no link” will cause fast R/W 0

aging (<800µs) to age address table faster. After an

age cycle is complete, the age logic will return to

normal (300 + 75 seconds ). Note: If any port is

unplugged, all addresses will be automatically aged

out.

7Pass All Frames 1, switch all packets including bad ones. Used solely R/W 0

for debugging purpose. Works in conjunction with

sniffer mode.

6Reserved Reserved. R/W 0

5IEEE 802.3x Transmit 0, will enable transmit flow control based on AN result. R/W Pin PMRXD3

Flow Control Disable 1, will not enable transmit flow control regardless of strap option.

AN result. Pull-down(0):

Enable Tx flow

control. Pull-up(1):

Disable Tx/Rx

flow control.

Note: PMRXD3

has internal pull-

down.

4IEEE 802.3x Receive 0, will enable receive flow control based on AN result. R/W Pin PMRXD3 strap

Flow Control Disable 1, will not enable receive flow control regardless of option. Pull-down

AN result. (0): Enable Rx flow

control. Pull-up (1):

Note: Bit 5 and bit 4 default values are controlled by Disable Tx/Rx flow

the same pin, but they can be programmed control.

independently. Note: PMRXD3

has internal pull-

down.

3Frame Length Field Check 1, will check frame length field in the IEEE packets R/W 0

If the actual length does not match, the packet will be

dropped (for L/T <1500) .

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Address Name Description Mode Default

2Aging Enable 1, Enable age function in the chip. R/W Pin LED[5][2] strap

0, Disable aging function. option. Pull-down

(0): Aging disable

Pull-up (1): Aging

enable.

Note: LED[5][2]

has internal pull

up.

1Fast age Enable 1 = Turn on fast age (800µs). R/W 0

0Aggressive Back 1 = Enable more aggressive back-off algorithm in half R/W Pin PMRXD0 strap

Off Enable duplex mode to enhance performance. This is not an option. Pull-down

IEEE standard. (0): Disable

aggressive back

off. Pull-up (1):

Aggressive back

off.

Note: PMRXD0

has internal pull

down.

7Unicast Port-VLAN This feature is used for port VLAN R/W 1

Mismatch Discard (described in Register 17, Register 33...).

1, all packets can not cross VLAN boundary.

0, unicast packets (excluding unknown/

multicast/broadcast) can cross VLAN boundary.

6Multicast Storm 1, “Broadcast Storm Protection” does not include R/W 1

Protection Disable multicast packets. Only DA=FFFFFFFFFFFF packets

will be regulated.

0, “Broadcast Storm Protection” includes DA =

FFFFFFFFFFFF and DA[40] = 1 packets.

5Back Pressure Mode 1, carrier sense based backpressure is selected. R/W 1

0, collision based backpressure is selected.

4Flow Control and Back 1, fair mode is selected. In this mode, if a flow control R/W 1

Pressure Fair Mode port and a non-flow control port talk to the same

destination port, packets from the non-flow control port

may be dropped. This is to prevent the flow control port

from being flow controlled for an extended period of time.

0, in this mode, if a flow control port and a non-flow

control port talk to the same destination port, the flow

control port will be flow controlled. This may not be “fair”

to the flow control port.

3No Excessive Collision Drop 1, the switch will not drop packets when 16 or more R/W Pin PMRXD1 strap

collisions occur. option. Pull-down

0, the switch will drop packets when 16 or more (0): Drop

collisions occur. excessive collision

packets. Pull-up (1):

Don’t drop

excessive collision

packets.

Note: PMRXD1

has internal pull

down.

2Huge Packet Support 1, will accept packet sizes up to 1916 bytes (inclusive). R/W 0

This bit setting will override setting from bit 1 of the

same register.

0, the max packet size will be determined by bit 1 of this

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Address Name Description Mode Default

1Legal Maximum Packet 1, will accept packet sizes up to 1536 bytes (inclusive). R/W Pin PMRXER

Size Check Disable 0, 1522 bytes for tagged packets (not including packets strap option.

with STPID from CPU to ports 1-4), 1518 bytes for Pull-down (0):

untagged packets. Any packets larger than the specified 1518/1522 byte

value will be dropped. packets. Pull-up

(1): 1536 byte

packets.

Note: PMRXER

has internal pull-

down.

0Priority Buffer Reserve 1, each output queue is pre-allocated 48 buffers, R/W 0

used exclusively for high priority packets. It is

recommended to enable this when priority queue

feature is turned on.

0, no reserved buffers for high priority packets.

7802.1q VLAN Enable 1, 802.1q VLAN mode is turned on. VLAN table needs R/W 0

to set up before the operation.

0, 802.1q VLAN is disabled.

6IGMP Snoop Enable on 1, IGMP snoop enabled. All the IGMP packets will be R/W 0

Switch MII Interface forwarded to Switch MII port.

0, IGMP snoop disabled.

5Enable Direct Mode on 1, direct mode on port 5. This is a special mode for the R/W 0

Switch MII Interface Switch MII interface. Using preamble before MRXDV to

direct switch to forward packets, bypassing internal

look-up.

0, normal operation.

4Enable Pre-Tag on 1, packets forwarded to Switch MII interface will be R/W 0

Switch MII Interface pre-tagged with the source port number (preamble

before MRXDV).

0, normal operation.

3-2 Priority Scheme Select 00 = always deliver high priority packets first. R/W 00

01 = deliver high/low packets at ratio 10/1.

10 = deliver high/low packets at ratio 5/1.

11 = deliver high/low packets at ratio 2/1.

1Enable “Tag” Mask 1, the last 5 digits in the VID field are used as a mask R/W 0

to determine which port(s) the packet should be

forwarded to.

0, no tag masks.

0Sniff Mode Select 1, will do Rx AND Tx sniff (both source port and R/W 0

destination port need to match).

0, will do Rx OR Tx sniff (Either source port or destination

port needs to match).

This is the mode used to implement Rx only sniff.

7Switch MII Back 1, enable half-duplex back pressure on switch MII R/W 0

Pressure Enable interface.

0, disable back pressure on switch MII interface.

6Switch MII Half-Duplex 1, enable MII interface half-duplex mode. R/W Pin SMRXD2 strap

Mode 0, enable MII interface full-duplex mode. option. Pull-down

(0): Full-duplex

mode. Pull-up

(1): Half-duplex

mode. Note:

SMRXD2 has

internal pull-down.

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Address Name Description Mode Default(1)

5Switch MII Flow 1, enable full-duplex flow control on switch MII interface. R/W Pin SMRXD3 strap

Control Enable 0, disable full-duplex flow control on switch MII interface. option. Pull-down

(0): disable flow

control. Pull-up(1):

enable flow control.

Note: SMRXD3

has internal pull-

down.

4Switch MII 10BT 1, the switch interface is in 10Mbps mode. R/W Pin SMRXD1 strap

0, the switch interface is in 100Mbps mode. option. Pull-down

(0): Enable

100Mbps. Pull-up

(1): Enable

10Mpbs.

Note: SMRXD1

has internal pull-

down.

3Null VID Replacement 1, will replace null VID with port VID (12 bits). R/W 0

0, no replacement for null VID.

2-0 Broadcast Storm This along with the next register determines how many R/W 000

Protection Rate Bit [10:8] “64 byte blocks” of packet data allowed on an input port

in a preset period. The period is 50ms for 100BT or

500ms for 10BT. The default is 1%.

7-0 Broadcast Storm This along with the previous register determines how R/W 0x4A(1)

Protection Rate Bit [7:0] many “64 byte blocks” of packet data are allowed on an

input port in a preset period. The period is 50ms for

100BT or 500ms for 10BT. The default is 1%.

Note:

1. 148,800 frames/sec × 50ms/interval × 1% = 74 frames/interval (approximately) = 0x4A.

7-0 Factory Testing Reserved. R/W 0x24

7-0 Factory Testing Reserved. R/W 0x28

7-0 Factory Testing Reserved. R/W 0x24

7-4 Reserved N/A 0

3PHY Power 0 = disable PHY power save mode. R/W 0

Save 1 = enable PHY power save mode.

2Factory Setting Reserved. R/W 0

1LED Mode 0 = led mode 0. R/W Pin SMRXD0 strap

1 = led mode 1. option. Pull-down(0):

Enabled led mode 0.

Pull-up(1):

Enabled led mode 1.

Note: SMRXD0 has

internal pull-down 0.

Mode 0 Mode 1

LEDX_2 Lnk/Act 100Lnk/Act

LEDX_1 Fulld/Col 10Lnk/Act

LEDX_0 Speed Fulld

0Special TPID Mode Used for direct mode forwarding from port 5. R/W 0

See “Spanning Tree” functional description.

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Port Registers

The following registers are used to enable features that are assigned on a per port basis. The register bit assignments are the

same for all ports, but the address for each port is different, as indicated.

Address Name Description Mode Default

7Broadcast Storm 1, enable broadcast storm protection for ingress packets R/W 0

Protection Enable on the port.

0, disable broadcast storm protection.

6DiffServ Priority 1, enable DiffServ priority classification for ingress R/W 0

Classification Enable packets on port.

0, disable DiffServ function.

5802.1p Priority 1, enable 802.1p priority classification for ingress R/W 0

Classification Enable packets on port.

0, disable 802.1p.

4Port-Based Priority 1, ingress packets on the port will be classified as high R/W 0

Classification Enable priority if “DiffServ” or “802.1p” classification is not

enabled or fails to classify.

0, ingress packets on port will be classified as low priority

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.

3Reserved Reserved. R/W 0

2Tag Insertion 1, when packets are output on the port, the switch will R/W 0

add 802.1q tags to packets without 802.1q 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.

1Tag Removal 1, when packets are output on the port, the switch will R/W 0

remove 802.1q tags from packets with 802.1q tags

when received. The switch will not modify packets

received without tags.

0, disable tag removal.

0Priority Enable 1, the port output queue is split into high and low R/W 0

priority queues.

0, single output queue on the port. There is no priority

differentiation even though packets are classified into

high or low priority.

Address Name Description Mode Default

7Sniffer Port 1, port is designated as sniffer port and will transmit R/W 0

packets that are monitored.

0, Port is a normal port.

6Receive Sniff 1, all the packets received on the port will be marked R/W 0

as “monitored packets” and forwarded to the designated

“sniffer port.”

0, no receive monitoring.

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Address Name Description Mode Default

5Transmit Sniff 1, All the packets transmitted on the port will be marked R/W 0

as “monitored packets” and forwarded to the designated

“sniffer port.”

0, no transmit monitoring.

4-0 Port VLAN Membership Define the port’s “Port VLAN membership.” Bit 4 stands R/W 0x1f

for port 5, bit 3 for port 4...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

membership.

Address Name Description Mode Default

7Reserved Reserved. 0x0

6Ingress VLAN Filtering. 1, the switch will discard packets whose VID port R/W 0

membership in VLAN table bit[20:16] does not include

the ingress port.

0, no ingress VLAN filtering.

5Discard Non-PVID Packets. 1, the switch will discard packets whose VID does not R/W 0

match ingress port default VID.

0, no packets will be discarded.

4Force Flow Control 1, will always enable Rx and Tx flow control on the port, R/W 0

regardless of AN result. For port 4 only,

0, the flow control is enabled based on AN result. there is a special

Note: Setting a port for both half-duplex and forced configuration pin

flow control is an illegal configuration. For half-duplex to set the default,

enable back pressure. Pin PCOL strap

option. Pull-down

(0): No Force flow

control. Pull-up

(1): Force flow

control.

Note: PCOL has

internal pull-down.

3Back Pressure Enable 1, enable port’s half-duplex back pressure. R/W Pin PMRXD2 strap

0, disable port’s half-duplex back pressure. option. Pull-down

(0): disable back

pressure. Pull-up

(1): enable back

pressure.

Note: PMRXD2 has

internal pull-down.

2Transmit Enable 1, enable packet transmission on the port. R/W 1

0, disable packet transmission on the port.

1Receive Enable 1, enable packet reception on the port. R/W 1

0, disable packet reception on the port.

0Learning Disable 1, disable switch address learning capability. R/W 0

0, enable switch address learning.

Note:

Bits 2-0 are used for spanning tree support. See “Spanning Tree Support” section.

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Address Name Description Mode Default

7-0 Default Tag [15:8] Port’s default tag, containing: R/W 0

7-5: user priority bits

4: CFI bit

3-0 : VID[11:8]

Address Name Description Mode Default

7-0 Default Tag [7:0] Default port 1’s tag, containing: R/W 1

7-0: VID[7:0]

Note:

Registers 19 and 20 (and those corresponding to other ports) serve 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 look-up.

Address Name Description Mode Default

7-0 Transmit High Priority This along with port control 7, bits [3:0] form a 12-bit R/W 0

Rate Control [7:0] field to determine how many “32Kbps” high priority

blocks can be transmitted (in a unit of 4K bytes in a

one second period).

Address Name Description Mode Default

7-0 Transmit Low Priority This along with port control 7, bits [7:4] form a 12-bit R/W 0

Rate Control [7:0] field to determine how many “32Kbps” low priority

blocks can be transmitted (in a unit of 4K bytes in a

one second period).

Address Name Description Mode Default

7-4 Transmit Low Priority This along with port control 6, bits [7:0] form a 12-bit R/W 0

Rate Control [11:8] field to determine how many “32Kbps” low priority

blocks can be transmitted (in a unit of 4K bytes in a

one second period).

3-0 Transmit High Priority This along with port control 5, bits [7:0] form a 12-bit R/W 0

Rate Control [11:8] field to determine how many “32Kbps” high priority

blocks can be transmitted (in unit of 4K bytes in a

one second period).

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Address Name Description Mode Default

7-0 Receive High Priority This along with port control 10, bits [3:0] form a 12-bit R/W 0

Rate Control [7:0] field to determine how many “32Kbps” high priority

blocks can be received (in a unit of 4K bytes in a one

second period).

Address Name Description Mode Default

7-0 Receive Low Priority This along with port control 10, bits [7:4] form a 12-bit R/W 0

Rate Control [7:0] field to determine how many “32Kbps” low priority

blocks can be received (in a unit of 4K bytes in a one

second period).

Address Name Description Mode Default

7-4 Receive Low Priority This along with port control 9, bits [7:0] form a 12-bit R/W 0

Rate Control [11:8] field to determine how many “32Kbps” low priority

blocks can be received (in a unit of 4K bytes in a one

second period).

3-0 Receive High Priority This along with port control 8, bits [7:0] form a 12-bit R/W 0

Rate Control [11:8] field to determine how many “32Kbps” high priority

blocks can be received (in a unit of 4K bytes in a one

second period).

Address Name Description Mode Default

7Receive Differential 1, If bit 6 is also ‘1’ this will enable receive rate control R/W 0

Priority Rate Control for this port on low priority packets at the low priority

rate. If bit 5 is also ‘1’, this will enable receive rate

control on high priority packets at the high priority rate.

0, receive rate control will be based on the low priority

rate for all packets on this port.

6Low Priority Receive 1, enable port’s low priority receive rate control feature. R/W 0

Rate Control Enable 0, disable port’s low priority receive rate control.

5High Priority Receive 1, If bit 7 is also ‘1’ this will enable the port’s high R/W 0

Rate Control Enable priority receive rate control feature. If bit 7 is a ‘0’ and

bit 6 is a ‘1’, all receive packets on this port will be rate

controlled at the low priority rate.

0, disable port’s high priority receive rate control feature.

4Low Priority Receive Rate 1, flow control may be asserted if the port’s low priority R/W 0

Flow Control Enable receive rate is exceeded.

0, flow control is not asserted if the port’s low priority

receive rate is exceeded.

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Address Name Description Mode Default

3High Priority Receive 1, flow control may be asserted if the port’s high R/W 0

Rate Flow Control Enable priority receive rate is exceeded (to use this, differential

receive rate control must be on).

0, flow control is not asserted if the port’s high priority

receive rate is exceeded.

2Transmit Differential 1, will do transmit rate control on both high and low R/W 0

Priority Rate Control priority packets based on the rate counters defined by

the high and low priority packets respectively.

0, will do transmit rate control on any packets.

The rate counters defined in low priority will be used.

1Low Priority Transmit 1, enable the port’s low priority transmit rate control R/W 0

Rate Control Enable feature.

0, disable the port’s low priority transmit rate control

feature.

0High Priority Transmit 1, enable the port’s high priority transmit rate control R/W 0

Rate Control Enable feature

0, disable the port’s high priority transmit rate control

feature.

Address Name Description Mode Default

7Disable Auto-Negotiation 1, disable auto-negotiation, speed and duplex are R/W 0

decided by bit 6 and 5 of the same register.

0, auto-negotiation is on.

6Forced Speed 1, forced 100BT if AN is disabled (bit 7). R/W 1

0, forced 10BT if AN is disabled (bit 7).

5Forced Duplex 1, forced full-duplex if (1) AN is disabled or (2) AN is R/W 0

enabled but failed. For port 4 only,

0, forced half-duplex if (1) AN is disabled or (2) AN is there is a special

enabled but failed. configure pin to set

the default,

Pin PCRS strap

option.

Pull-down (0):

Force half-duplex.

Pull-up (1):

Force full-duplex.

Note: PCRS has

internal pull down.

4Advertised Flow 1, advertise flow control capability. R/W 1

Control Capability 0, suppress flow control capability from transmission

to link partner.

3Advertised 100BT 1, advertise 100BT full-duplex capability. R/W 1

Full-Duplex Capability 0, suppress 100BT full-duplex capability from

transmission to link partner.

2Advertised 100BT 1, advertise 100BT half-duplex capability. R/W 1

Half-Duplex Capability 0, suppress 100BT half-duplex capability from

transmission to link partner.

1Advertised 10BT 1, advertise 10BT full-duplex capability. R/W 0

Full-Duplex Capability 0, suppress 10BT full-duplex capability from

transmission to link partner.

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Address Name Description Mode Default

0Advertised 10BT 1, advertise 10BT half-duplex capability. R/W 1

Half-Duplex Capability 0, suppress 10BT half-duplex capability from

transmission to link partner.

Note:

Port Control 12 and 13, and Port Status 0 contents can be accessed by MIIM (MDC/MDIO) interface via the standard MIIM register definition.

Address Name Description Mode Default

7LED Off 1, Turn off all port’s LEDs (LEDx_2, LEDx_1, LEDx_0, R/W 0

where “x” is the port number). These pins will be driven

high if this bit is set to one.

0, normal operation.

6Txids 1, disable port’s transmitter. R/W 0

0, normal operation.

5Restart AN 1, restart auto-negotiation. R/W 0

0, normal operation.

4Disable Far End Fault 1, disable far end fault detection and pattern transmission. R/W 0

0, enable far end fault detection and pattern transmission.

3Power Down 1, power down. R/W 0

0, normal operation.

2Disable Auto MDI/MDI-X 1, disable auto MDI/MDI-X function. R/W 0

0, enable auto MDI/MDI-X function.

1Forced MDI 1, If auto MDI/MDI-X is disabled, force PHY into R/W 0

MDI mode.

0, Do not force PHY into MDI mode.

0MAC Loopback 1, Perform MAC loopback. R/W 0

0, normal operation.

Address Name Description Mode Default

7MDI-X Status 1, MDI. RO 0

0, MDI-X.

6AN Done 1, AN done. RO 0

0, AN not done.

5Link Good 1, link good. RO 0

0, link not good.

4Partner Flow 1, link partner flow control capable. RO 0

Control Capability 0, link partner not flow control capable.

3Partner 100BT 1, link partner 100BT full-duplex capable. RO 0

Full-Duplex Capability 0, link partner not 100BT full-duplex capable.

2Partner 100BT 1, link partner 100BT half-duplex capable. RO 0

Half-Duplex Capability 0, link partner not 100BT half-duplex capable.

1Partner 10BT 1, link partner 10BT full-duplex capable. RO 0

Full-Duplex Capability 0, link partner not 10BT full-duplex capable.

0Partner 10BT 1, link partner 10BT half-duplex capable. RO 0

Half-Duplex Capability 0, link partner not 10BT half-duplex capable.

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Address Name Description Mode Default

7PHY Loopback 1, perform PHY loopback, i.e. loopback MAC’s Tx R/W 0

back to Rx.

0, normal operation.

6Remote Loopback 1, perform remote loopback, i.e. loopback PHY’s Rx R/W 0

back to Tx.

0, normal operation.

5PHY Isolate 1, electrical isolation of PHY from MII and Tx+/Tx-. R/W 0

0, normal operation.

4Soft Reset 1, PHY soft reset. R/W 0

0, normal operation.

3Force Link 1, Force link in the PHY. R/W 0

0, normal operation.

2-1 Reserved N/A RO 0

0Far End Fault 1, Far end fault status detected. RO 0

0, no far end fault status detected.

Advanced Control Registers

The IPv4 TOS priority control registers implement a fully decoded 64 bit differentiated services code point (DSCP) register used

to determine priority from the 6 bit TOS field in the IP header. The most significant 6 bits of the TOS field are fully decoded into

64 possibilities, and the singular code that results is compared against the corresponding bit in the DSCP register. If the register

bit is a 1, the priority is high; if the register bit is a 0, the priority is low.

Address Name Description Mode Default

7-0 DSCP[63:56] R/W 00000000

7-0 DSCP[55:48] R/W 00000000

7-0 DSCP[47:40] R/W 00000000

7-0 DSCP[39:32] R/W 00000000

7-0 DSCP[31:24] R/W 00000000

7-0 DSCP[23:16] R/W 00000000

7-0 DSCP[15:8] R/W 00000000

7-0 DSCP[7:0] R/W 00000000

Registers 104 to 109 define the switching engine’s MAC address. This 48-bit address is used as the source address in MAC pause control frames.

7-0 MACA[47:40] R/W 0x00

7-0 MACA[39:32] R/W 0x10

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Address Name Description Mode Default

7-0 MACA[31:24] R/W 0xA1

7-0 MACA[23:16] R/W 0xff

7-0 MACA[15:8] R/W 0xff

7-0 MACA[7:0] R/W 0xff

Use registers 110 and 111 to read or write data to the static MAC address table, VLAN table, dynamic address table, or the MIB counters.

Address Name Description Mode Default

7-5 Reserved Reserved. R/W 000

4Read High Write Low 1, read cycle. R/W 0

0, write cycle.

3-2 Table Select 00 = static mac address table selected. R/W 0

01 = VLAN table selected.

10 = dynamic address table selected.

11 = MIB counter selected.

1-0 Indirect Address High Bit 9-8 of indirect address. R/W 00

7-0 Indirect Address Low Bit 7-0 of indirect address. R/W 00000000

Note:

Write to Register 111 will actually trigger a command. Read or write access will be decided by bit 4 of Register 110.

Address Name Description Mode Default

68-64 Indirect Data Bit 68-64 of indirect data. R/W 00000

63-56 Indirect Data Bit 63-56 of indirect data. R/W 00000000

55-48 Indirect Data Bit 55-48 of indirect data. R/W 00000000

47-40 Indirect Data Bit 47-40 of indirect data. R/W 00000000

39-32 Indirect Data Bit 39-32 of indirect data. R/W 00000000

31-24 Indirect Data Bit of 31-24 of indirect data R/W 00000000

23-16 Indirect Data Bit 23-16 of indirect data. R/W 00000000

15-8 Indirect Data Bit 15-8 of indirect data. R/W 00000000

7-0 Indirect Data Bit 7-0 of indirect data. R/W 00000000

Do not write or read to/from Register isters 121 to 127. Doing so may prevent proper operation. Micrel internal testing only.

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Address Name Description Mode Default

7-0 Factory Testing Reserved. RO 0x0

Qm_split status

7-0 Factory Testing Reserved. RO 0x0

Dbg[7:0]

7-0 Factory Testing Reserved. R/W 0x0

Dbg[12:8]

7-0 Factory Testing Reserved. R/W 0x0

7-0 Factory Testing Reserved. RO 0x0

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Static MAC Address

KS8995MA has a static and a dynamic address table. When a DA look-up is requested, both tables will be searched to make

a packet forwarding decision. When an SA look-up is requested, only the dynamic table is searched for aging, migration, and

learning purposes. The static DA look-up result will have precedence over the dynamic DA look-up result. If there are DA

matches in both tables, the result from the static table will be used. The static table can only be accessed and controlled by

an external SPI master (usually a processor). The entries in the static table will not be aged out by KS8995MA. An external

device does all addition, modification and deletion.

Note:

Register bit assignments are different for static MAC table reads and static MAC table write, as shown in the two tables below.

Address Name Description Mode Default

Format of Static MAC Table for Reads (8 entries)

60-57 FID Filter VLAN ID, representing one of the 16 active VLANs. RO 0000

56 Use FID 1, use (FID+MAC) to look-up in static table. RO 0

0, use MAC only to look-up in static table.

55 Reserved Reserved. RO N/A

54 Override 1, override spanning tree “transmit enable = 0” or RO 0

“receive enable = 0” setting. This bit is used for

spanning tree implementation.

0, no override.

53 Valid 1, this entry is valid, the look-up result will be used. RO 0

0, this entry is not valid.

52-48 Forwarding Ports The 5 bits control the forward ports, example: RO 00000

00001, forward to port 1

00010, forward to port 2

.....

10000, forward to port 5

00110, forward to port 2 and port 3

11111, broadcasting (excluding the ingress port)

47-0 MAC Address 48 bit MAC address. RO 0x0

Format of Static MAC Table for Writes (8 entries)

59-56 FID Filter VLAN ID, representing one of the 16 active VLANs. W 0000

55 Use FID 1, use (FID+MAC) to look-up in static table.

0, use MAC only to look-up in static table. W 0

54 Override 1, override spanning tree “transmit enable = 0” or W 0

“receive enable = 0” setting. This bit is used for

spanning tree implementation.

0, no override.

53 Valid 1, this entry is valid, the look-up result will be used. W 0

0, this entry is not valid.

52-48 Forwarding Ports The 5 bits control the forward ports, example: W 00000

00001, forward to port 1

00010, forward to port 2

.....

10000, forward to port 5

00110, forward to port 2 and port 3

11111, broadcasting (excluding the ingress port)

47-0 MAC Address 48-bit MAC address. W 0x0

Table 12. Static MAC Address Table

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Examples:

(1) Static Address Table Read (read the 2nd entry)

Write to Register 110 with 0x10 (read static table selected)

Write to Register 111 with 0x1 (trigger the read operation)

Then

Read Register 113 (60-56)

Read Register 114 (55-48)

Read Register 115 (47-40)

Read Register 116 (39-32)

Read Register 117 (31-24)

Read Register 118 (23-16)

Read Register 119 (15-8)

Read Register 120 (7-0)

(2) Static Address Table Write (write the 8th entry)

Write Register 113 (59-56)

Write Register 114 (55-48)

Write Register 115 (47-40)

Write Register 116 (39-32)

Write Register 117 (31-24)

Write Register 118 (23-16)

Write Register 119 (15-8)

Write Register 120 (7-0)

Write to Register 110 with 0x00 (write static table selected)

Write to Register 111 with 0x7 (trigger the write operation)

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Address Name Description Mode Default

Format of Static VLAN Table (16 entries)

21 Valid 1, the entry is valid. R/W 1

0, entry is invalid.

20-16 Membership Specify which ports are members of the VLAN. R/W 11111

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.

E.g., 11001 means port 5, 4, and 1 are in this VLAN.

15-12 FID Filter ID. KS8995MA supports 16 active VLANs R/W 0

represented by these four bit fields. FID is the mapped

ID. If 802.1q VLAN is enabled, the look-up will be based

on FID+DA and FID+SA.

11-0 VID IEEE 802.1q 12 bit VLAN ID. R/W 1

Table 13. VLAN Table

VLAN Address

The VLAN table is used for VLAN table look-up. If 802.1q VLAN mode is enabled (Register 5 bit 7 =1), this table is used to

retrieve VLAN information that is associated with the ingress packet. The information includes FID (filter ID), VID (VLAN ID),

and VLAN membership described below:

If 802.1q VLAN mode is enabled, KS8995MA assigns a VID to every ingress packet. If the packet is untagged or tagged with

a null VID, 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 is used. The look-up process starts from the VLAN table look-up. If the VID is not valid, the packet is dropped

and no address learning occurs. 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 is broadcast to all the members (excluding the

ingress port) of the VLAN. If FID+SA fails, the FID+SA is learned.

Examples:

(1) VLAN Table Read (read the 3rd entry)

Write to Register 110 with 0x14 (read VLAN table selected)

Write to Register 111 with 0x2 (trigger the read operation)

Then

Read Register 118 (VLAN table bits 21-16)

Read Register 119 (VLAN table bits 15-8)

Read Register 120 (VLAN table bits 7-0)

(2) VLAN Table Write (write the 7th entry)

Write to Register 118 (VLAN table bits 21-16)

Write to Register 119 (VLAN table bits 15-8)

Write to Register 120 (VLAN table bits 7-0)

Write to Register 110 with 0x04 (write static table selected)

Write to Register 111 with 0x6 (trigger the write operation)

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Address Name Description Mode Default

Format of Dynamic MAC Address Table (1K entries)

68 MAC Empty 1, there is no valid entry in the table. RO 1

0, there are valid entries in the table.

67-58 No of Valid Entries Indicates how many valid entries in the table. RO 0

0x3ff means 1K entries

0x1 means 2 entries

0x0 and bit 68 = 0: means 1 entry

0x0 and bit 68 = 1: means 0 entry

57-56 Time Stamp 2-bit counters for internal aging RO

55 Data Ready 1, The entry is not ready, retry until this bit is set to 0. RO

0, The entry is ready.

54-52 Source Port The source port where FID+MAC is learned. RO 0x0

000 port 1

001 port 2

010 port 3

011 port 4

100 port 5

51-48 FID Filter ID. RO 0x0

47-0 MAC Address 48-bit MAC address. RO 0x0

Table 14. Dynamic MAC Address Table

Examples:

(1) Dynamic MAC Address Table Read (read the 1st entry), and retrieve the MAC table size

Write to Register 110 with 0x18 (read dynamic table selected)

Write to Register 111 with 0x0 (trigger the read operation )

Then

Read Register 112 (68-64)

Read Register 113 (63-56); // the above two registers show # of entries

Read Register 114 (55-48) // if bit 55 is 1, restart (reread) from this register

Read Register 115 (47-40)

Read Register 116 (39-32)

Read Register 117 (31-24)

Read Register 118 (23-16)

Read Register 119 (15-8)

Read Register 120 (7-0)

(2) Dynamic MAC Address Table Read (read the 257th entry), without retrieving # of entries information

Write to Register 110 with 0x19 (read dynamic table selected)

Write to Register 111 with 0x1 (trigger the read operation)

Then

Read Register 114 (55-48) // if bit 55 is 1, restart (reread) from this register ister

Read Register 115 (47-40)

Read Register 116 (39-32)

Read Register 117 (31-24)

Read Register 118 (23-16)

Read Register 119 (15-8)

Read Register 120 (7-0)

Dynamic MAC Address

This table is read only. The contents are maintained by the KS8995MA only.

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MIB Counters

The MIB counters are provided on per port basis. The indirect memory is as below:

For port 1

Offset Counter Name Description

0x0 RxLoPriorityByte Rx lo-priority (default) octet count including bad packets.

0x1 RxHiPriorityByte Rx hi-priority octet count including bad packets.

0x2 RxUndersizePkt Rx undersize packets w/good CRC.

0x3 RxFragments Rx fragment packets w/bad CRC, symbol errors or alignment errors.

0x4 RxOversize Rx oversize packets w/good CRC (max: 1536 or 1522 bytes).

0x5 RxJabbers Rx packets longer than 1522B w/either CRC errors, alignment errors, or symbol errors

(depends on max packet size setting).

0x6 RxSymbolError Rx packets w/ invalid data symbol and legal packet size.

0x7 RxCRCerror Rx packets within (64,1522) bytes w/an integral number of bytes and a bad CRC

(upper limit depends on max packet size setting).

0x8 RxAlignmentError 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).

0x9 RxControl8808Pkts The number of MAC control frames received by a port with 88-08h in EtherType field.

0xA RxPausePkts The 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.

0xB RxBroadcast Rx good broadcast packets (not including errored broadcast packets or valid multicast

packets).

0xC RxMulticast Rx good multicast packets (not including MAC control frames, errored multicast packets or

valid broadcast packets).

0xD RxUnicast Rx good unicast packets.

0xE Rx64Octets Total Rx packets (bad packets included) that were 64 octets in length.

0xF Rx65to127Octets Total Rx packets (bad packets included) that are between 65 and 127 octets in length.

0x10 Rx128to255Octets Total Rx packets (bad packets included) that are between 128 and 255 octets in length.

0x11 Rx256to511Octets Total Rx packets (bad packets included) that are between 256 and 511 octets in length.

0x12 Rx512to1023Octets Total Rx packets (bad packets included) that are between 512 and 1023 octets in length.

0x13 Rx1024to1522Octets Total Rx packets (bad packets included) that are between 1024 and 1522 octets in length

(upper limit depends on max packet size setting).

0x14 TxLoPriorityByte Tx lo-priority good octet count, including PAUSE packets.

0x15 TxHiPriorityByte Tx hi-priority good octet count, including PAUSE packets.

0x16 TxLateCollision The number of times a collision is detected later than 512 bit-times into the Tx of a packet.

0x17 TxPausePkts The number of PAUSE frames transmitted by a port.

0x18 TxBroadcastPkts Tx good broadcast packets (not including errored broadcast or valid multicast packets).

0x19 TxMulticastPkts Tx good multicast packets (not including errored multicast packets or valid broadcast

packets).

0x1A TxUnicastPkts Tx good unicast packets.

0x1B TxDeferred Tx packets by a port for which the 1st Tx attempt is delayed due to the busy medium.

0x1C TxTotalCollision Tx total collision, half-duplex only.

0x1D TxExcessiveCollision A count of frames for which Tx fails due to excessive collisions.

0x1E TxSingleCollision Successfully Tx frames on a port for which Tx is inhibited by exactly one collision.

0x1F TxMultipleCollision Successfully Tx frames on a port for which Tx is inhibited by more than one collision.

Table 15. Port-1 MIB Counter Indirect Memory Offsets

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For port 2, the base is 0x20, same offset definition (0x20-0x3f)

For port 3, the base is 0x40, same offset definition (0x40-0x5f)

For port 4, the base is 0x60, same offset definition (0x60-0x7f)

For port 5, the base is 0x80, same offset definition (0x80-0x9f)

Address Name Description Mode Default

Format of Per Port MIB Counters (16 entries)

31 Overflow 1, Counter overflow. RO 0

0, No Counter overflow.

30 Count Valid 1, Counter value is valid. RO 0

0, Counter value is not valid.

29-0 Counter Values Counter value. RO 0

Offset Counter Name Description

0x100 Port1 Tx Drop Packets Tx packets dropped due to lack of resources.

0x101 Port2 Tx Drop Packets Tx packets dropped due to lack of resources.

0x102 Port3 Tx Drop Packets Tx packets dropped due to lack of resources.

0x103 Port4 Tx Drop Packets Tx packets dropped due to lack of resources.

0x104 Port5 Tx Drop Packets Tx packets dropped due to lack of resources.

0x105 Port1 Rx Drop Packets Rx packets dropped due to lack of resources.

0x106 Port2 Rx Drop Packets Rx packets dropped due to lack of resources.

0x107 Port3 Rx Drop Packets Rx packets dropped due to lack of resources.

0x108 Port4 Rx Drop Packets Rx packets dropped due to lack of resources.

0x109 Port5 Rx Drop Packets Rx packets dropped due to lack of resources.

Table 16. All Port Dropped Packet MIB Counters

Address Name Description Mode Default

Format of All Port Dropped Packet MIB Counters

30-16 Reserved Reserved. N/A N/A

15-0 Counter Values Counter value. RO 0

Note:

All port dropped packet MIB counters do not indicate overflow or validity; therefore the application must keep track of overflow and valid conditions.

Examples:

(1) MIB counter read (read port 1 rx 64 counter)

Write to Register 110 with 0x1c (read MIB counters

selected)

Write to Register 111 with 0xe (trigger the read operation)

Then

Read Register 117 (counter value 31-24)

// If bit 31 = 1, there was a counter overflow

// If bit 30 = 0, restart (reread) from this register

Read Register 118 (counter value 23-16)

Read Register 119 (counter value 15-8)

Read Register 120 (counter value 7-0)

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(2) MIB counter read (read port 2 rx 64 counter)

Write to Register 110 with 0x1c

(read MIB counter selected)

Write to Register 111 with 0x2e

(trigger the read operation )

Then

Read Register 117 (counter value 31-24)

// If bit 31 = 1, there was a counter overflow

// If bit 30 = 0, restart (reread) from this register

Read Register 118 (counter value 23-16)

Read Register 119 (counter value 15-8)

Read Register 120 (counter value 7-0)

(3) MIB counter read (read port 1 tx drop packets)

Write to Register 110 with 0x1d

Write to Register 111 with 0x00

Then

Read Register 119 (counter value 15-8)

Read Register 120 (counter value 7-0)

Note:

To read out all the counters, the best performance over the SPI bus is (160+3) ×8×200 = 260ms, where there are 160 registers, 3 overhead, 8 clocks per

access, at 5MHz. In the heaviest condition, the byte counter will overflow in 2 minutes. It is recommended that the software read all the counters at least

every 30 seconds. The per port MIB counters are designed as “read clear.” A per port MIB counter will be cleared after it is accessed. All port 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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Address Name Description Mode Default

15 Soft Reset 1, PHY soft reset. R/W 0

0, Normal operation.

14 Loop Back 1, Loop back mode (loopback at MAC). R/W 0

0, Normal operation.

13 Force 100 1, 100Mbps. R/W 1

0, 10Mbps.

12 AN Enable 1, Auto-negotiation enabled. R/W 1

0, Auto-negotiation disabled.

11 Power Down 1, Power down. R/W 0

0, Normal operation.

10 PHY Isolate 1, Electrical PHY isolation of PHY from Tx+/Tx-. R/W 0

0, Normal operation.

9Restart AN 1, Restart Auto-negotiation. R/W 0

0, Normal operation.

8Force Full Duplex 1, Full duplex. R/W 0

0, Half duplex.

7Collision Test Not supported. RO 0

6Reserved RO 0

5Reserved RO 0

4Force MDI 1, Force MDI. R/W 0

0, Normal operation.

3Disable Auto MDI/MDI-X 1, Disable auto MDI/MDI-X. R/W 0

0, Normal operation.

2Disable Far End Fault 1, Disable far end fault detection. R/W 0

0, Normal operation.

1Disable Transmit 1, Disable transmit. R/W 0

0, Normal operation.

0Disable LED 1, Disable LED. R/W 0

0, Normal operation.

MIIM Registers

All the registers defined in this section can be also accessed via the SPI interface. Note: different mapping mechanisms used

for MIIM and SPI. The “PHYAD” defined in IEEE is assigned as “0x1” for port 1, “0x2” for port 2, “0x3” for port 3, “0x4” for port

4, and “0x5” for port 5. The “REGAD” supported are 0,1,2,3,4,5.

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Address Name Description Mode Default

15 T4 Capable 0, Not 100 BASET4 capable. RO 0

14 100 Full Capable 1, 100BASE-TX full-duplex capable. RO 1

0, Not capable of 100BASE-TX full-duplex.

13 100 Half Capable 1, 100BASE-TX half-duplex capable. RO 1

0, Not 100BASE-TX half-duplex capable.

12 10 Full Capable 1, 10BASE-T full-duplex capable. RO 1

0, Not 10BASE-T full-duplex capable.

11 10 Half Capable 1, 10BASE-T half-duplex capable. RO 1

0, 10BASE-T half-duplex capable.

10-7 Reserved RO 0

6Preamble Suppressed Not supported. RO 0

5AN Complete 1, Auto-negotiation complete. RO 0

0, Auto-negotiation not completed.

4Far End Fault 1, Far end fault detected. RO 0

0, No far end fault detected.

3AN Capable 1, Auto-negotiation capable. RO 1

0, Not auto-negotiation capable.

2Link Status 1, Link is up. RO 0

0, Link is down.

1Jabber Test Not supported. RO 0

0Extended Capable 0, Not extended register capable. RO 0

15-0 Phyid High High order PHYID bits. RO 0x0022

15-0 Phyid Low Low order PHYID bits. RO 0x1450

15 Next Page Not supported. RO 0

14 Reserved RO 0

13 Remote Fault Not supported. RO 0

12-11 Reserved RO 0

10 Pause 1, Advertise pause ability. R/W 1

0, Do not advertise pause ability.

9Reserved R/W 0

8Adv 100 Full 1, Advertise 100 full-duplex ability. R/W 1

0, Do not advertise 100 full-duplex ability.

7Adv 100 Half 1, Advertise 100 half-duplex ability. R/W 1

0, Do not advertise 100 half-duplex ability.

6Adv 10 Full 1, Advertise 10 full-duplex ability. R/W 1

0, Do not advertise 10 full-duplex ability.

5Adv 10 Half 1, Advertise 10 half-duplex ability. R/W 1

0, Do not advertise 10 half-duplex ability.

4-0 Selector Field 802.3 RO 00001

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Address Name Description Mode Default

15 Next Page Not supported. RO 0

14 LP ACK Not supported. RO 0

13 Remote Fault Not supported. RO 0

12-11 Reserved RO 0

10 Pause Link partner pause capability. RO 0

9Reserved RO 0

8Adv 100 Full Link partner 100 full capability. RO 0

7Adv 100 Half Link partner 100 half capability. RO 0

6Adv 10 Full Link partner 10 full capability. RO 0

5Adv 10 Half Link partner 10 half capability. RO 0

4-0 Reserved RO 00001

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Absolute Maximum Ratings(1)

Supply Voltage

(VDDAR, VDDAP, VDDC)............................. –0.5V to +2.4V

(VDDAT, VDDIO)........................................ –0.5V to +4.0V

Input Voltage ............................................... –0.5V to +4.0V

Output Voltage ............................................ –0.5V to +4.0V

Lead Temperature (soldering, 10 sec.) ..................... 270°C

Storage Temperature (TS) ....................... –55°C to +150°C

Operating Ratings(2)

Supply Voltage

(VDDAR, VDDAP, VDDC)............................. +1.7V to +1.9V

(VDDAT)................... +3.15V to +3.45V or +2.4V to +2.6V

(VDDIO)................................................ +3.15V to +3.45V

Ambient Temperature (TA)

Commercial .............................................. –0°C to +70°C

Industrial ................................................. –40°C to +85°C

Package Thermal Resistance(3)

PQFP (θJA) No Air Flow ................................. 59.47°C/W

Electrical Characteristics(4, 5)

Symbol Parameter Condition Min Typ Max Units

100BASE-TX Operation — All Ports 100% Utilization

IDX 100BASE-TX (Transmitter) VDDAT 229 250 mA

IDDC

100BASE-TX (Digital Core/PLL + Analog Rx)

VDDC, VDDAP, VDDAR 157 230 mA

IDDIO 100BASE-TX (Digital IO) VDDIO 17 30 mA

10BASE-TX Operation — All Ports 100% Utilization

IDX 10BASE-TX (Transmitter) VDDAT 350 375 mA

IDDC

10BASE-TX (Digital Core + Analog Rx)

VDDC, VDDAP 102 180 mA

IDDIO 10BASE-TX (Digital IO) VDDIO 615mA

Auto-Negotiation Mode

IDX 10BASE-TX (Transmitter) VDDAT 25 40 mA

IDDC 10BASE-TX (Digital Core + Analog Rx) VDDC, VDDAP 108 180 mA

IDDIO 10BASE-TX (Digital IO) VDDIO 17 20 mA

TTL Inputs

VIH Input High Voltage +2.0 V

VIL Input Low Voltage +0.8 V

IIN Input Current VIN = GND ~ VDDIO –10 10 V

(Excluding Pull-up/Pull-down)

TTL Outputs

VOH Output High Voltage IOH = –8mA +2.4 V

VOL Output Low Voltage IOL = 8mA +0.4 V

|IOZ|Output Tri-State Leakage VIN = GND ~ VDDIO 10 µA

100BASE-TX Transmit (measured differentially after 1:1 transformer)

VOPeak Differential Output Voltage 100Ω termination on the differential output 0.95 1.05 V

VIMB Output Voltage Imbalance 100Ω termination on the differential output 2 %

tr, ttRise/Fall Time 35ns

Rise/Fall Time Imbalance 0 0.5 ns

Notes:

1. Exceeding the absolute maximum rating may damage the device.

2. 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).

3. No heat spreader in package.

4. Specification for packaged product only.

5. Measurements were taken within operating ratings.

KS8995MA Micrel, Inc.

M9999-051305 64 May 2005

Symbol Parameter Condition Min Typ Max Units

100BASE-TX Transmit (measured differentially after 1:1 transformer)

Duty Cycle Distortion ±0.5 ns

Overshoot 5%

VSET Reference Voltage of ISET 0.5 V

Output Jitters Peak-to-peak 0.7 1.4 ns

10BASE-TX Receive

VSQ Squelch Threshold 5MHz square wave 400 mV

10BASE-T Transmit (measured differentially after 1:1 transformer) VDDAT = 2.5V

VPPeak Differential Output Voltage 100Ω termination on the differential output 2.3 V

Jitters Added 100Ω termination on the differential output 16 ns

Rise/Fall Times 28 30 ns

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KS8995MA Micrel, Inc.

Timing Diagrams

SCL

SDA

tcyc1ts1 th1

Receive Timing

Figure 12. EEPROM Interface Input Receive Timing Diagram

SCL

SDA

tcyc1

Tr a n s m it Timing

tov1

Figure 13. EEPROM Interface Output Transmit Timing Diagram

Symbol Parameter Min Typ Max Units

tCYC1 Clock Cycle 16384 ns

tS1 Set-Up Time 20 ns

tH1 Hold Time 20 ns

tOV1 Output Valid 4096 4112 4128 ns

Table 17. EEPROM Timing Parameters

KS8995MA Micrel, Inc.

M9999-051305 66 May 2005

tcyc2ts2 th2

MTXC

MTXEN

MTXD[0]

Receive Timing

Figure 14. SNI Input Timing

MRXC

MRXDV

tcyc2

Tr a nsmit Timing

tov2

MRXD[0]

MCOL

Figure 15. SNI Output Timing

Symbol Parameter Min Typ Max Units

tCYC2 Clock Cycle 100 ns

tS2 Set-Up Time 10 ns

tH2 Hold Time 0ns

tO2 Output Valid 036ns

Table 18. SNI Timing Parameters

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KS8995MA Micrel, Inc.

MRXCLK

MTXEN

MTXER

MTXD[3:0]

tcyc3ts3 th3

Receive Timing

Figure 16. MAC Mode MII Timing – Data Received from MII

MTXCLK

MRXDV

MRXD[3:0]

tcyc3

Tr a nsmit Timing

tov3

Figure 17. MAC Mode MII Timing – Data Transmitted from MII

Symbol Parameter Min Typ Max Units

tCYC3 Clock Cycle (100BASE-T) 40 ns

tCYC3 Clock Cycle (10BASE-T) 400 ns

tS3 Set-Up Time 10 ns

tH3 Hold Time 5ns

tOV3 Output Valid 71116ns

Table 19. MAC Mode MII Timing Parameters

KS8995MA Micrel, Inc.

M9999-051305 68 May 2005

MTXCLK

MTXEN

MTXER

MTXD[3:0]

tcyc4ts4 th4

Receive Timing

Figure 18. PHY Mode MII Timing – Data Received from MII

MRXCLK

MRXDV

MRXD[3:0]

tcyc4

Transmit Timing

tov4

Figure 19. PHY Mode MII Timing – Data Transmitted from MII

Symbol Parameter Min Typ Max Units

tCYC4 Clock Cycle (100BASE-T) 40 ns

tCYC4 Clock Cycle (10BASE-T) 400 ns

tS4 Set-Up Time 10 ns

tH4 Hold Time 0ns

tOV4 Output Valid 18 25 28 ns

Table 20. PHY Mode MII Timing Parameters

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KS8995MA Micrel, Inc.

SPIQ

SPIC

SPID

SPIS_N

High Impedance

MSB

tCHSL tSLCH

tDVCH

tCHDX

tDLDH

tDHDL

LSB

tCLCH

tCHCL

tSHCH

tCHSH

tSHSL

Figure 20. SPI Input Timing

Symbol Parameter Min Typ Max Units

fCClock Frequency 5MHz

tCHSL SPIS_N Inactive Hold Time 90 ns

tSLCH SPIS_N Active Set-Up Time 90 ns

tCHSH SPIS_N Active Hold Time 90 ns

tSHCH SPIS_N Inactive Set-Up Time 90 ns

tSHSL SPIS_N Deselect Time 100 ns

tDVCH Data Input Set-Up Time 20 ns

tCHDX Data Input Hold Time 30 ns

tCLCH Clock Rise Time 1µs

tCHCL Clock Fall Time 1µs

tDLDH Data Input Rise Time 1µs

tDHDL Data Input Fall Time 1µs

Table 21. SPI Input Timing Parameters

KS8995MA Micrel, Inc.

M9999-051305 70 May 2005

SPID

SPIC

SPIQ

SPIS_N

tQLQH

tQHQL

LSB

tCH

tCL tSHQZtCLQV

tCLQX

Figure 21. SPI Output Timing

Symbol Parameter Min Typ Max Units

fCClock Frequency 5MHz

tCLQX SPIQ Hold Time 00ns

tCLQV Clock Low to SPIQ Valid 60 ns

tCH Clock High Time 90 ns

tCL Clock Low Time 90 ns

tQLQH SPIQ Rise Time 50 ns

tQHQL SPIQ Fall Time 50 ns

tSHQZ SPIQ Disable Time 100 ns

Table 22. SPI Output Timing Parameters

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tsr

tcs tch

trc

Supply

Voltage

RST_N

Strap-In

Value

Strap-In /

Output Pin

Figure 22. Reset Timing

Symbol Parameter Min Typ Max Units

tSR Stable Supply Voltages to Reset High 10 ms

tCS Configuration Set-Up Time 50 ns

tCH Configuration Hold Time 50 ns

tRC Reset to Strap-In Pin Output 50 ns

Table 23. Reset Timing Parameters

Reset Circuit Diagram

Micrel recommendeds the following discrete reset circuit as shown in Figure 23 when powering up the KS8895MA device. For

the application where the reset circuit signal comes from another device (e.g., CPU, FPGA, etc), we recommend the reset circuit

as shown in Figure 24.

VCC

10k

10µF

D1 CPU/FPGA

RST_OUT_n

KS8995MA

RST

D1, D2: 1N4148

Figure 23. Recommended Reset Circuit.

VCC

10k

10µF

KS8995MA

RST

D1: 1N4148

Figure 24. Recommended Circuit for Interfacing with CPU/FPGA Reset

At power-on-reset, R, C, and D1 provide the necessary ramp rise time to reset the Micrel device. The reset out from CPU/FPGA

provides warm reset after power up. It is also recommended to power up the VDD core voltage earlier than VDDIO voltage.

At worst case, the both VDD core and VDDIO voltages should come up at the same time.

KS8995MA Micrel, Inc.

M9999-051305 72 May 2005

Selection of Isolation Transformer(1)

One simple 1:1 isolation transformer is needed at the line interface. An isolation transformer with integrated common-mode

choke is recommended for exceeding FCC requirements. The following table gives recommended transformer characteristics.

Characteristics Name Value Test Condition

Turns Ratio 1 CT : 1 CT

Open-Circuit Inductance (min.) 350µH100mV, 100kHz, 8mA

Leakage Inductance (max.) 0.4µH1MHz (min.)

Inter-Winding Capacitance (max.) 12pF

D.C. Resistance (max.) 0.9Ω

Insertion Loss (max.) 1.0dB 0MHz to 65MHz

Hipot (min.) 1500Vrms

Note:

1. The IEEE 802.3u standard for 100BASE-TX assumes a transformer loss of 0.5dB. For the transmit line transformer, insertion loss of up to 1.3dB

can be compensated by increasing the line drive current by means of reducing the ISET resistor value.

The following transformer vendors provide compatible magnetic parts for Micrel’s device:

4-Port IntegratedAuto Number Single Port AutoNumber

Vendor Part MDI-X of Port Vendor Part MDI-X of Port

Pulse H1164 Yes 4 Pulse H1102 Yes 1

Bel Fuse 558-5999-Q9 Yes 4 Bel Fuse S558-5999-U7 Yes 1

YCL PH406466 Yes 4 YCL PT163020 Yes 1

Transpower HB826-2 Yes 4 Transpower HB726 Yes 1

Delta LF8731 Yes 4 Delta LF8505 Yes 1

LanKom SQ-H48W Yes 4 LanKom LF-H41S Yes 1

Table 24. Qualified Magnetics Vendors

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Package Information

128-Pin PQFP (PQ)

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

This 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.