INFINEON ADM6996L

An Infineon Technologies Company
ADM6996L
6 port 10/100 Mb/s
Single Chip Ethernet Switch Controller
Data Sheet
Version 1.03
Infineon-ADMtek Co Ltd
Information in this document is provided in connection with Infineon-ADMtek Co Ltd products. InfineonADMtek Co Ltd may make changes to specifications and product descriptions at any time, without notice.
Designers must not rely on the absence or characteristics of any features or instructions marked “reserved”
or “undefined”. Infineon-ADMtek Co Ltd reserves these for future definition and shall have no
responsibility whatsoever for conflicts or incompatibilities arising from future changes to them
The products may contain design defects or errors know as errata, which may cause the product to deviate
from published specifications. Current characterized errata are available on request. To obtain latest
documentation please contact you local Infineon-ADMtek Co Ltd sales office or visit Infineon-ADMtek Co
Ltd’s website at
http://www.admtek.com.tw
*Third-party brands and names are the property of their respective owners.
Copyright 2004 by ADMtek Incorporated All Rights Reserved.
Infineon-ADMtek Co. Ltd.
V1.04
About this Manual
General Release
Intended Audience
Infineon-ADMtek Co Ltd’s Customers
Structure
This Data sheet contains 6 chapters
Chapter 1
Product Overview
Chapter 2
Interface Description
Chapter 3
Function Description
Chapter 4.
Register Description
Chapter 5.
Electrical Specification
Chapter 6.
Packaging
Revision History
Date
02 Sep 2003
07 October 2003
17 November 2003
12 January 2004
28 April 2004
Version
1.0
1.01
1.02
1.03
1.04
Customer Support
Infineon-ADMtek Co Ltd,
2F, No.2, Li-Hsin Rd.,
Science-based Industrial Park,
Hsinchu, 300, Taiwan, R.O.C.
Sales Information
Tel + 886-3-5788879
Fax + 886-3-5788871
Change
1. First release of ADM6996L
2. Updated Section 1.1 and 2.2.2
3. Updated Section 4.3.12 & 3.4
4. Updated Section 5.3.3 - 8
Updated Infineon-ADMtek logo
Infineon-ADMtek Co. Ltd.
V1.04
Table of Contents
Chapter 1 Product Overview ........................................................................................ 1-1
1.1
Overview.......................................................................................................... 1-1
1.2
Features ............................................................................................................ 1-2
1.3
Applications ..................................................................................................... 1-2
1.4
Block Diagram ................................................................................................. 1-3
1.5
Abbreviations................................................................................................... 1-3
1.6
Conventions ..................................................................................................... 1-5
1.6.1
Data Lengths............................................................................................ 1-5
1.6.2
Pin Types.................................................................................................. 1-5
1.6.2
Register Types.......................................................................................... 1-5
Chapter 2 Interface Description ................................................................................... 2-1
2.1
Pin Diagram ..................................................................................................... 2-1
2.2
Pin Description by Function ............................................................................ 2-2
2.2.1
Twisted Pair Interface.............................................................................. 2-2
2.2.2
6th Port (MII) Interfaces.......................................................................... 2-2
2.2.3
LED Interface........................................................................................... 2-4
2.2.4
EEPROM/Management Interface ............................................................ 2-5
2.2.5
Power/Ground, 48 pins............................................................................ 2-5
2.2.6
MISC ........................................................................................................ 2-6
Chapter 3 Function Description ................................................................................... 3-1
3.1
Functional Descriptions ................................................................................... 3-1
3.2
10/100M PHY Block ....................................................................................... 3-1
3.3
100Base-X Module .......................................................................................... 3-1
3.4
100Base-X Receiver ........................................................................................ 3-2
3.4.1
A/D Converter.......................................................................................... 3-2
3.4.2
Adaptive Equalizer and timing Recovery Module ................................... 3-2
3.4.3
NRZI/NRZ and Serial/Parallel Decoder.................................................. 3-2
3.4.4
Data De-scrambling................................................................................. 3-3
3.4.5
Symbol Alignment .................................................................................... 3-3
3.4.6
Symbol Decoding ..................................................................................... 3-3
3.4.7
Valid Data Signal..................................................................................... 3-3
3.4.8
Receive Errors ......................................................................................... 3-4
3.4.9
100Base-X Link Monitor.......................................................................... 3-4
3.4.10
Carrier Sense ........................................................................................... 3-4
3.4.11
Bad SSD Detection................................................................................... 3-4
3.4.12
Far-End Fault .......................................................................................... 3-5
3.5
100Base-TX Transceiver ................................................................................. 3-5
3.5.1
Transmit Drivers...................................................................................... 3-5
3.5.2
Twisted-Pair Receiver.............................................................................. 3-5
3.6
10Base-T Module............................................................................................. 3-5
3.6.1
Operation Modes ..................................................................................... 3-6
3.6.2
Manchester Encoder/Decoder ................................................................. 3-6
3.6.3
Transmit Driver and Receiver ................................................................. 3-6
3.6.4
Smart Squelch .......................................................................................... 3-6
3.7
Carrier Sense.................................................................................................... 3-7
ADM6996L
i
Infineon-ADMtek Co. Ltd.
V1.04
3.8
Jabber Function................................................................................................ 3-7
3.9
Link Test Function........................................................................................... 3-7
3.10
Automatic Link Polarity Detection.............................................................. 3-8
3.11
Clock Synthesizer ........................................................................................ 3-8
3.12
Auto Negotiation.......................................................................................... 3-8
3.13
Memory Block ............................................................................................. 3-8
3.14
Switch Functional Description..................................................................... 3-9
3.15
Basic Operation............................................................................................ 3-9
3.15.1
Address Learning ..................................................................................... 3-9
3.15.2
Address Recognition and Packet Forwarding ....................................... 3-10
3.15.3
Address Aging ........................................................................................ 3-10
3.15.4
Back off Algorithm ................................................................................. 3-10
3.15.5
Inter-Packet Gap (IPG) ......................................................................... 3-10
3.15.6
Illegal Frames........................................................................................ 3-11
3.15.7
Half Duplex Flow Control ..................................................................... 3-11
3.15.8
Full Duplex Flow Control...................................................................... 3-11
3.15.9
Broadcast Storm filter............................................................................ 3-11
3.16 Auto TP MDIX function................................................................................ 3-11
3.17
Port Locking............................................................................................... 3-12
3.18
VLAN setting & Tag/Untag & port-base VLAN ...................................... 3-12
3.19
Priority Setting ........................................................................................... 3-13
3.20
LED Display .............................................................................................. 3-13
Chapter 4 Register Description .................................................................................... 4-1
4.1
EEPROM Content............................................................................................ 4-1
4.2
EEPROM Register Map................................................................................... 4-1
4.3
EEPROM Register ........................................................................................... 4-2
4.3.1
Signature Register, offset: 0x00h.............................................................. 4-2
4.3.2
Configuration Registers, offset: 0x01h ~ 0x09h ...................................... 4-3
4.3.3
Reserved Register, offset: 0x0ah.............................................................. 4-3
4.3.4
Configuration Register, offset: 0x0bh...................................................... 4-4
4.3.5
Reserved Register, offset: 0x0ch~0x0dh .................................................. 4-4
4.3.6
VLAN priority Map Register, offset: 0x0eh ............................................. 4-4
4.3.7
TOS priority Map Register, offset: 0x0fh................................................. 4-4
4.3.8
Packet with Priority: Normal packet content .......................................... 4-5
4.3.9
VLAN Packet............................................................................................ 4-5
4.3.10
TOS IP Packet.......................................................................................... 4-1
4.3.11
Miscellaneous Configuration Register, offset: 0x10h.............................. 4-1
4.3.12
VLAN mode select Register, offset: 0x11h............................................... 4-2
4.3.13
Miscellaneous Configuration register, offset: 0x12h .............................. 4-5
4.3.14
VLAN mapping table registers, offset: 0x22h ~ 0x13h ............................ 4-5
4.3.15 Reserved Register, offset: 0x27h ~ 0x23h................................................ 4-5
4.3.16 Port0, 1 PVID bit 11 ~ 4 Configuration Register, offset: 0x28h ............. 4-1
4.3.17 Port2, 3 PVID bit 11 ~ 4 Configuration Register, offset: 0x29h ............. 4-1
4.3.18
Port4, 5 PVID bit 11~4 Configuration Register, offset: 0x2ah ............... 4-1
4.3.19
Port6, 7 PVID bit 11~4 Configuration Register, offset: 0x2bh ............... 4-1
4.3.20
Port8 PVID bit 11~4 & VLAN group shift bits Configuration Register.. 4-1
ADM6996L
ii
Infineon-ADMtek Co. Ltd.
V1.04
4.3.21
Reserved Register, offset: 0x2dh.............................................................. 4-2
4.3.22
Reserved Register, offset: 0x2eh .............................................................. 4-2
4.3.23
PHY Restart, offset: 0x2fh........................................................................ 4-2
4.3.24
Miscellaneous Configuration Register, offset: 0x30h.............................. 4-2
4.3.25
Bandwidth Control Register0~3, offset: 0x31h........................................ 4-3
4.3.26
Bandwidth Control Register 4~5, offset: 0x32h....................................... 4-3
4.3.27
Bandwidth Control Enable Register, offset: 0x33h .................................. 4-4
4.4
EEPROM Access ............................................................................................. 4-4
4.5
Serial Register Map.......................................................................................... 4-6
4.6
Serial Register Description .............................................................................. 4-7
4.6.1
Chip Identifier Register, offset: 0x00h..................................................... 4-7
4.6.2
Port Status 0 Register, offset: 0x01h ....................................................... 4-7
4.6.3
Port Status 1 Register, offset: 0x02h ....................................................... 4-9
4.6.4
Cable Broken Status Register, offset: 0x03h............................................ 4-9
4.6.5
Over Flow Flag 0 Register, offset: 0x3ah.............................................. 4-10
4.6.6
Over Flow Flag 0: Register 0x3bh ........................................................ 4-10
4.6.7
Over Flow Flag 2 Register, offset: 0x3ch.............................................. 4-11
4.7
Serial Interface Timing .................................................................................... 4-1
Chapter 5 Electrical Specification................................................................................ 5-1
5.1
TX/FX Interface............................................................................................... 5-1
5.1.1
TP Interface ............................................................................................. 5-1
5.1.2
FX Interface ............................................................................................. 5-1
5.2
DC Characteristics ........................................................................................... 5-2
5.2.1
Absolute Maximum Rating....................................................................... 5-2
5.2.2
Recommended Operating Conditions ...................................................... 5-2
5.2.3
DC Electrical Characteristics for 3.3V Operation .................................. 5-2
5.3
AC Characteristics ........................................................................................... 5-3
5.3.1
Power On Reset........................................................................................ 5-3
5.3.2
EEPROM Interface Timing...................................................................... 5-3
5.3.3
10Base-TX MII Input Timing ................................................................... 5-4
5.3.4
10Base-TX MII Output Timing ................................................................ 5-4
5.3.5
100Base-TX MII Input Timing ................................................................. 5-5
5.3.6
100Base-TX MII Output Timing .............................................................. 5-5
5.3.7
GPSI(7-wire) Input Timing ...................................................................... 5-6
5.3.8
GPSI(7-wire) Output Timing ................................................................... 5-6
Chapter 6 Packaging...................................................................................................... 6-1
6.1
128 Pin PQFP Outside Dimension................................................................... 6-1
List of Figures
Figure 1-1 ADM6996L Block Diagram .......................................................................... 1-3
Figure 2-1 5 TP/FX PORT + 1 MII PORT 128 Pin Diagram.......................................... 2-1
ADM6996L
iii
ADM6996L
Product Review
Chapter 1 Product Overview
1.1
Overview
The ADM6996L is a high performance, low cost, highly integration (Controller, PHY
and Memory) five-port 10/100 Mbps TX/FX plus one 10/100 MAC port Ethernet switch
controller with all ports supporting 10/100 Mbps Full/Half duplex. The ADM6996L is
intended for applications to stand alone bridge for low cost SOHO market such as 5Port,
Router application.
ADM6996L provides most advance function such as: 802.1p(Q.O.S.), 802.1q(VLAN),
Port MAC address Locking, Management, Port Status, TP Auto-MDIX, 25M
Crystal & Extra MII port function to meet customer request on Switch demand.
The ADM6996L also supports Back Pressure in Half-Duplex mode and 802.3x Flow
Control Pause packet in Full-Duplex mode to prevent packet lost when buffer full. When
Back Pressure is enabled, and there is no receive buffer available for the incoming
packet, the ADM6996L will issue a JAM pattern on the receiving port in Half Duplex
mode and transmit the 802.3x Pause packet back to receiving end in Full Duplex mode.
The built-in SRAM used for packet buffer and address learning table is divided into 256
bytes/block to achieve the optimized memory utilization through complicated link list on
packets with various lengths.
ADM6996L also supports priority features by Port-Base, VLAN and IP TOS field
checking. User can be easy to set as different priority mode in individual port, through a
small low-cost micro controller to initialize or on-the-fly to configure. Each output port
supports four queues in the way of fixed N: 1 fairness queuing to fit the bandwidth
demand on various types of packet such as Voice, Video and data. 802.1Q, Tag/Untag,
and up to 16 groups of VLAN also is supported.
An intelligent address recognition algorithm makes ADM6996L to recognize up to 2048
different MAC addresses and enables filtering and forwarding at full wire speed.
Port MAC address Locking function is also supported by ADM6996L to use on Building
Internet access to prevent multiple users sharing one port traffic.
Infineon-ADMtek Co. Ltd.
1-1
ADM6996L
1.2
Product Review
Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
1.3
Supports five 10M/100M auto-detect Half/Full duplex switch ports with TX/FX
interfaces and one MII/GPSI port.
Supports 2048 MAC addresses table.
Supports four queue for QoS
Supports priority features by Port-Based, 802.1p VLAN & IP TOS of packets.
Supports Store & Forward architecture and performs forwarding and filtering at nonblocking full wire speed.
Supports buffer allocation with 256 bytes per block
Supports Aging function Enable/Disable.
Supports per port Single/Dual color mode with Power On auto diagnostic.
Supports 802.3x Flow Control pause packet for Full Duplex in case buffer is full.
Supports Back Pressure function for Half Duplex operation in case buffer is full.
Supports packet length up to 1522 bytes.
Broadcast Storming Filter function.
Supports 802.1Q VLAN. Up to 16 VLAN groups is implemented by the last four bits
of VLAN ID.
2bit MAC clone to support multiple WAN application
Supports TP interface Auto MDIX function for auto TX/RX swap by strapping-pin.
Easy Management 32bits smart counter for per port RX/TX byte/packet count, error
count and collision count.
Support PHY status output for management system.
25M Crystal only for the whole system.
128 QFP package with 0.18um technology. 1.8V/3.3V power supply.
Applications
ADM6996L in 128-pin PQFP:
Infineon-ADMtek Co. Ltd.
SOHO 5-port switch
5-port switch + Router with MII CPU interface.
1-2
ADM6996L
1.4
Product Review
Block Diagram
Embedded Memory
LED
DISPLAY
CONTROL
Switching Fabric
Memory
BIST
10/100M
10/100M
MAC
MAC
...
10/100M
10/100M
MAC
MAC
LED
Interface
MII
Interface
PORT0
PORT1
PORT2
...
Twisted
Pair
Interface
PORTN
Data Handler
RXP4
RXN4
A/D
CONVERTER
DIGITAL
EQUALIZER
PARTITION HANDLER
TXP4
DRIVER
MLT3 Converter
SCRAMBLER
TXN4
BIAS
TRANSMIT
STATE
MACHINE
CLOCK GENERATOR
Figure 1-1 ADM6996L Block Diagram
1.5
Abbreviations
BER
CFI
COL
CRC
CRS
CS
DA
DI
DO
EDI
EDO
EECS
Infineon-ADMtek Co. Ltd.
Bit Error Rate
Canonical Format Indicator
Collision
Cyclic Redundancy Check
Carrier Sense
Chip Select
Destination Address
Data Input
Data Output
EEPROM Data Input
EEPROM Data Output
EEPROM Chip Select
1-3
ADM6996L
Product Review
EESK
ESD
FEFI
FET
FLP
GND
GPSI
IPG
LFSR
MAC
MDIX
MII
NRZI
NRZ
PCS
PHY
PLL
PMA
PMD
QoS
QFP
RST
RXCLK
RXD
RXDV
RXER
RXN
RXP
SA
SOHO
SSD
SQE
TOS
TP
TTL
TXCLK
TXD
TXEN
TXN
TXP
Infineon-ADMtek Co. Ltd.
EEPROM Clock
End of Stream Delimiter
Far End Fault Indication
Field Effect Transistor
Fast Link Pulse
Ground
General Purpose Serial Interface
Inter-Packet Gap
Linear Feedback Shift Register
Media Access Controller
MDI Crossover
Media Independent Interface
Non Return to Zero Inverter
Non Return to Zero
Physical Coding Sub-layer
Physical Layer
Phase Lock Loop
Physical Medium Attachment
Physical Medium Dependent
Quality of Service
Quad Flat Package
Reset
Receive Clock
Receive Data
Receive Data Valid
Receive Data Errors
Receive Negative (Analog receive differential signal)
Receive Positive (Analog receive differential signal)
Source Address
Small Office Home Office
Start of Stream Delimiter
Signal Quality Error
Type of Service
Twisted Pair
Transistor Transistor Logic
Transmission Clock
Transmission Data
Transmission Enable
Transmission Negative
Transmission Positive
1-4
ADM6996L
Product Review
1.6
Conventions
1.6.1
Data Lengths
qword
dword
word
byte
nibble
64-bits
32-bits
16-bits
8 bits
4 bits
1.6.2 Pin Types
Pin Type
I
O
I/O
OD
SCHE
PD
PU
1.6.2
Description
Input
Output
Bi-directional
Open drain
Schmitt Trigger
internal pull-down
internal pull-up
Register Types
Register Type
RO
WO
RW
Infineon-ADMtek Co. Ltd.
Description
Read-only
Write-only
Read/Write
1-5
ADM6996L
Interface Description
Chapter 2 Interface Description
2.1
Pin Diagram
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
VCCIK
TXEN (PHYAS0)
TXCLK
RXER
GND
GNDO
VCC3O
RXCLK
RXDV
RXD0
VCCIK
GNDIK
CRS
COL
EDI (LEDMODE)
EECS
EESK (XOVEN)
VCCIK
GNDIK
EDO
CKO25M
CFG0
GNDO
VCC3O
SPDTNP5
LNKFP5
DPHALFP5
LNKACT4
GNDIK
VCCIK
LNKACT3
LNKACT2
LNKACT1
LNKACT0
GNDO
RXD1
RXD2
RXD3
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
GNDIK
DUPCOL4
GNDO
VCC3O
(GFCEN) TXD0
P4FX
TXD1
DUPCOL3
DUPCOL2 (BPEN)
DUPCOL1 (PHYAS1)
TXD2
TXD3
LDSPD4
DUPCOL0 (RECANEN)
VCCIK
GNDO
VCC3O
GNDIK
RC
XI
XO
VCCPLL
GNDPLL
ADM6996L
CONTROL
VREF
GNDBIAS
LDSPD3
LDSPD2
VCCIK
GNDIK
LDSPD1
LDSPD0
TEST
VCCIK
GNDIK
RTX
VCCBIAS
GNDO
VCCA2
VCCA2
TXP0
TXN0
TXP4
TXN4
GNDA
GNDA
RXP0
RXN0
RXP4
RXN4
VCCAD
VCCAD
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
RXN3
RXP3
GNDA
TXN3
TXP3
VCCA2
VCCA2
NC
NC
GNDA
NC
NC
VCCAD
RXN2
RXP2
GNDA
TXN2
TXP2
VCCA2
VCCA2
NC
NC
GNDA
NC
NC
VCCAD
RXN1
RXP1
GNDA
TXN1
TXP1
VCCA2
VCCA2
NC
NC
GNDA
NC
NC
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
Figure 2-1 5 TP/FX PORT + 1 MII PORT 128 Pin Diagram
Infineon-ADMtek Co. Ltd.
2-1
ADM6996L
2.2
Interface Description
Pin Description by Function
ADM6996L pins are categorized into one of the following groups:
Section 2.2.1 Twisted Pair Interface
Section 2.2.2 6th Port (MII) Interfaces
Section 2.2.3 LED Interface
Section 2.2.4 EEPROM/Management Interface
Section 2.2.5 Power/Ground, 48 pins
Section 2.2.6 MISC
Note:
“Section 1.6.2 Pin Types” can be used for reference.
2.2.1
Twisted Pair Interface
Pin Name
RXP[0:4]
Pin#
126, 11, 24, 37, 41
RXN[0:4]
127, 12, 25, 38, 40
TXP[0:4]
123, 8, 21, 34, 44
TXN[0:4]
124, 9, 22, 35, 43
2.2.2
Type
I/O,
Analog
I/O,
Analog
I/O,
Analog
I/O,
Analog
Descriptions
Twisted Pair Receive Input Positive.
Twisted Pair Receive Input Negative.
Twisted Pair Transmit Output Positive.
Twisted Pair Transmit Output Negative.
6th Port (MII) Interfaces
Pin Name
TXD[0]
Pin#
63
Type
I/O,
8mA
PU
Descriptions
MII transmit data 0 /GPSI TXD
Acts as MII transmit data TXD[0]. Synchronous to the rising
edge of TXCLK.
I/O,
8mA
PD
Setting
GFCEN: Global Flow Control Enable.
At power-on-reset, latched as Full Duplex Flow control
setting
“1” to enable flow-control (default ), “0” to disable flowcontrol.
MII Transmit Data bit 1
Synchronous to the rising edge of TXCLK. These pins act
as MII TXD[1].
I/O,
Setting
P5GPSI: Port 5 GPSI Enable.
At power-on-reset, latched as P5 GPSI Enable.
“0” to disable port 5 GPSI (default ), “1” to enable port 5
GPSI.
MII Transmit Data bit 3~2
Setting
GFCEN
TXD[1]
61
Setting
P5GPSI
TXD[3:2]
Infineon-ADMtek Co. Ltd.
59, 60
2-2
ADM6996L
Pin Name
Interface Description
Pin#
P4FX
62
XEN
66
Setting
PHYAS0
RXD[0]
Type
8mA
PD
I
PD
I/O
8mA
PD
74
I
PD
102, 101,
100
I
PD
RXDV
73
RXER
68
COL
78
CRS
77
RXCLK
72
TXCLK
67
I
PD
I
PD
I
PD
I
PD
I
PD
I
DHALFP5
91
I
PD
LNKFP5
90
I
PD
SPDTNP5
89
I
PD
RXD[3:1]
Descriptions
Synchronous to the rising edge of TXCLK. These pins act
as MII TXD[3:2].
Port4 FX/TX mode select. Internal pull down.
1: Port4 as FX port.
0: Port4 as TX port.
MII Transmit Enable/GPSI TXEN. Internal pull down.
Setting
PHYAS0: Chip physical address for multiple chip application
on read EEPROM data. Internal pull down.
Power on reset value PHYAS0 combines with PHYAS1
PHYAS1
PHYAS0
0
0
Master(93C46)
If there is no EEPROM then user must use 93C66 timing to
write chip’s register.
If user put 93C46 with correct Signature then user writes
chip register by 93C46 timing.
If user put 93C66 then data put in Bank0. User can write
chip register by 93C66 timing.
User must assert one SK cycle when CS at idle stage when
write chip internal register.
MII port receive data 0 /GPSI RXD
These pins act as MII RXD[0]. Synchronous to the rising
edge of RXCLK. Internal pull down.
MII port receive data 3~1
These pins act as MII RXD[3:1]. Synchronous to the rising
edge of RXCLK. Internal pull down.
MII receive data valid.
Internal pull down.
MII Port Receive Error.
Internal pull down.
MII Port Collision input /GPSI Collision Input
Internal pull down.
MII Port Carrier Sense /GPSI Carrier Sense
Internal pull down.
MII Port Receive Clock Input /GPSI RXCLK
MII Port Transmit clock Input /GPSI TXCLK
PD
Infineon-ADMtek Co. Ltd.
MII Port Hardware Duplex input pin.
Low: Full Duplex. High: Half Duplex.
Internal pull down.
MII Port Hardware Link input pin.
Low: Link OK. High: Link Off.
Internal pull down.
MII Port Hardware Speed input pin.
Low: 100M. High: 10M.
Internal pull down.
2-3
ADM6996L
2.2.3
Interface Description
LED Interface
Pin Name
LNKACT[4:0]
Pin#
92, 95, 96, 97, 98
Type
O,
8mA
DUPCOL[4:3]
103, 106
O,
8mA
107
O,
8mA,
PU
Descriptions
LINK/Activity LED[4:0]. Active low
“1” indicates no link activity on cable
“0” indicates link okay on cable, but no activity and signals
on idle stage.
“Blinking” indicates link activity on cable.
Duplex/Collision LED[4:3]. Active low
“1” for half-duplex and “blinking” for collision indication
“0” for full-duplex indication
Duplex/Collision LED2. Active low
“1” for half-duplex and “blinking” for collision indication
“0” for full-duplex indication
O,
8mA,
PD
Setting
BPEN: At power-on-reset, latched as Back Pressure setting
“1” to enable Back-Pressure (defaulted), “0” to disable Back
Pressure.
At power-on-reset, latched as Back Pressure setting “1” to
enable Back-Pressure (defaulted), “0” to disable Back
Pressure.
Duplex/Collision LED1. Active low
“1” for half-duplex and “blinking” for collision indication
“0” for full-duplex indication
O,
8mA,
PU
Setting
PHYAS1: Power on Reset latch value combine with TXEN.
Internal pull down. Check pin 66.
Duplex/Collision LED0. Active low
“1” for half-duplex and “blinking” for collision indication
“0” for full-duplex indication
O,
8mA
Setting
ANEN: On power-on-reset, latched as Auto Negotiation
capability for all ports.
“1” to enable Auto Negotiation ( defaulted by pulled up
internally ),
“0” to disable Auto Negotiation.
Speed LED[4:0]. Used to indicate corresponding port’s
speed status. “0” for 100Mb/s, “1” for 10Mb/s
DUPCOL2
Setting
BPEN
DUPCOL1
108
Setting
PHYAS1
DUPCOL0
109
Setting
ANEN
LDSPD[4:0]
58, 55, 54, 51, 50
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2-4
ADM6996L
Interface Description
2.2.4 EEPROM/Management Interface
Pin Name
EDO
Pin#
84
EECS
80
EECK
81
Type
I,
TTL,PU
O,
4mA,PD
I/O,
4mA
PD
Setting
XOVEN
EDI
79
I/O,
4mA
PD
Setting
LEDMODE
2.2.5
Setting
XOVEN: This pin is internal pull-down. On power-on-reset,
latched as P4~0 Auto MDIX enable or not.
“0” to disable MDIX ( defaulted ), “1” to enable MDIX.
Suggest externally pull up to enable MDIX for all ports.
EEPROM Serial Data Input. This pin is output for serial
data transfer. When RESETL is low, it will be tri-state.
Setting
LEDMODE: This pin is internal pull-down. On power-onreset, latched as Dual Color mode or not.
“0” to set Single color mode for LED.
“1” to set Dual Color mode for LED.
Power/Ground, 48 pins
Pin Name
GNDA
VCCA2
VCCAD
GNDBIAS
VCCBIAS
GNDPLL
VCCPLL
GNDIK
VCCIK
GNDO
VCC3O
GND
Descriptions
EEPROM Data Output. Serial data input from EEPROM.
This pin is internally pull-up.
EEPROM Chip Select. This pin is active high chip enable
for EEPROM. When RESETL is low, it will be Tri-state.
Internally Pull-down
Serial Clock. This pin is clock source for EEPROM. When
RESETL is low, it will be tri-state.
Pin#
3, 10, 16,
23, 29, 36,
42, 125
6, 7, 19,
20, 32, 33,
45, 122
13, 26,
39, 128
119
121
116
115
47, 52, 64,
76, 93, 83,
111
48, 53, 65,
75, 82, 94,
110
46, 57, 70, 87, 99,
104
56, 71,
88, 105
69
Infineon-ADMtek Co. Ltd.
Type
I
Descriptions
Ground Used by AD Block.
I
1.8V, Power Used by TX Line Driver.
I
3.3V, Power Used by AD Block.
I
I
I
I
I
Ground Used by Bias Block
3.3V, Power Used by Bias Block.
Ground used by PLL
1.8V, Power used by PLL
Ground Used by Digital Core
I
1.8V, Power Used by Digital Core
I
Ground Used by Digital Pad
I
3.3V, Power Used by Digital Pad.
I
Ground Used by Digital Pad.
2-5
ADM6996L
Interface Description
2.2.6 MISC
Pin Name
CKO25M
Pin#
85
Control
117
RTX
VREF
RC
XI
XO
CFG0
TEST
NC
Type
O,
8mA
O
Descriptions
25M Clock Output.
FET Control Signal.
The pin is used to control FET for 3.3V to 1.8V regulator.
120
Analog TX Resistor. Add 1.1K %1 resister to GND.
118
Analog Analog Reference Voltage.
112
I,
RC Input for Power On reset. Reset input pin.
SCHE
113
I,
25M Crystal Input. 25M Crystal Input. Variation is limited
Analog to +/- 50ppm.
114
O,
25M Crystal Output. When connected to oscillator, this pin
Analog should left unconnected.
86
I,
Must Connected to GND.
TTL
49
I,
TEST Value.
TTL At normal application connect to GND.
1, 2, 4,5, 14, 15,17,
NC
18, 27,28,
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ADM6996L
Function Description
Chapter 3 Function Description
3.1
Functional Descriptions
The ADM6996L integrates five 100Base-X physical sub-layer (PHY), 100Base-TX
physical medium dependent (PMD) transceivers, five complete 10Base-T modules, 6 port
10/100 switch controller and one 10/100 MII/GPSI MAC and memory into a single chip
for both 10Mbits/s, 100Mbits/s Ethernet switch operation. It also supports 100Base-FX
operation through external fiber-optic transceivers. The device is capable of operating in
either Full Duplex mode or Half-Duplex mode in 10Mbits/s and 100Mbits/s. Operational
modes can be selected by hardware configuration pins, software settings of management
registers, or determined by the on-chip auto negotiation logic.
The ADM6996L consists of three major blocks:
• 10/100M PHY Block
• Switch Controller Block
• Built-in SSRAM
The interfaces used for communication between PHY block and switch core is MII
interface.
Auto MDIX function is supported in this block. This function can be Enable/Disable by
hardware pin.
3.2
10/100M PHY Block
The 100Base-X section of the device implements the following functional blocks:
• 100Base-X physical coding sub-layer (PCS)
• 100Base-X physical medium attachment (PMA)
• Twisted-pair transceiver (PMD)
• The 100Base-X and 10Base-T sections share the following functional blocks.
• Clock synthesizer module
• MII Registers
• IEEE 802.3u auto negotiation
3.3
100Base-X Module
The ADM6996L implements 100Base-X compliant PCS and PMA and 100Base-TX
compliant TP-PMD as illustrated in Figure 2. Bypass options for each of the major
functional blocks within the 100Base-X PCS provides flexibility for various applications.
100Mbits/s PHY loop back is included for diagnostic purpose.
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ADM6996L
3.4
Function Description
100Base-X Receiver
The 100Base-X receiver consists of functional blocks required to recover and condition
the 125Mbits/s receive data stream. The ADM6996L implements the 100Base-X
receiving state machine diagram as given in ANSI/IEEE Standard 802.3u, Clause 24. The
125Mbits/s receive data stream may originate from the on-chip twisted-pair transceiver in
a 100Base-TX application. Alternatively, the receive data stream may be generated by an
external optical receiver as in a 100Base-FX application.
The receiver block consists of the following functional sub-blocks:
• A/D Converter
• Adaptive Equalizer and timing recovery module
• NRZI/NRZ and serial/parallel decoder
• De-scrambler
• Symbol alignment block
• Symbol Decoder
• Collision Detect Block
• Carrier sense Block
• Stream decoder block
3.4.1 A/D Converter
High performance A/D converter with 125Mhz sampling rate converts signals received
on RXP/RXN pins to 6 bits data streams; besides it possess auto-gain-control capability
that will further improve receive performance especially under long cable or harsh
detrimental signal integrity. Due to high pass characteristic on transformer, built in baseline-wander correcting circuit will cancel it out and restore its DC level.
3.4.2
Adaptive Equalizer and timing Recovery Module
All digital design is especial immune from noise environments and achieves better
correlation between production and system testing. Baud rate Adaptive Equalizer/Timing
Recovery compensates line loss induced from twisted pair and tracks far end clock at
125M samples per second. Adaptive Equalizer implemented with Feed forward and
Decision Feedback techniques meet the requirement of BER less than 10-12 for
transmission on CAT5 twisted pair cable ranging from 0 to 120 meters.
3.4.3
NRZI/NRZ and Serial/Parallel Decoder
The recovered data is converted from NRZI to NRZ. The data is not necessarily aligned
to 4B/5B code group’s boundary.
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ADM6996L
3.4.4
Function Description
Data De-scrambling
The de-scrambler acquires synchronization with the data stream by recognizing idle
bursts of 40 or more bits and locking its deciphering Linear Feedback Shift Register
(LFSR) to the state of the scrambling LFSR. Upon achieving synchronization, the
incoming data is XORed by the deciphering LFSR and de-scrambled.
In order to maintain synchronization, the de-scrambler continuously monitors the validity
of the unscrambled data that it generates. To ensure this, a link state monitor and a hold
timer are used to constantly monitor the synchronization status. Upon synchronization of
the de-scrambler the hold timer starts a 722 us countdown. Upon detection of sufficient
idle symbols within the 722 us period, the hold timer will reset and begin a new
countdown. This monitoring operation will continue indefinitely given a properly
operating network connection with good signal integrity. If the link state monitor does
not recognize sufficient unscrambled idle symbols within 722 us period, the de-scrambler
will be forced out of the current state of synchronization and reset in order to re-acquire
synchronization.
3.4.5
Symbol Alignment
The symbol alignment circuit in the ADM6996L determines code word alignment by
recognizing the /J/K delimiter pair. This circuit operates on unaligned data from the descrambler. Once the /J/K symbol pair (11000 10001) is detected, subsequent data is
aligned on a fixed boundary.
3.4.6
Symbol Decoding
The symbol decoder functions as a look-up table that translates incoming 5B symbols
into 4B nibbles as shown in Table 1. The symbol decoder first detects the /J/K symbol
pair preceded by idle symbols and replaces the symbol with MAC preamble. All
subsequent 5B symbols are converted to the corresponding 4B nibbles for the duration of
the entire packet. This conversion ceases upon the detection of the /T/R symbol pair
denoting the end of stream delimiter (ESD). The translated data is presented on the
internal RXD[3:0] signal lines with RXD[0] represents the least significant bit of the
translated nibble.
3.4.7
Valid Data Signal
The valid data signal (RXDV) indicates that recovered and decoded nibbles are being
presented on the internal RXD[3:0] synchronous to receive clock, RXCLK. RXDV is
asserted when the first nibble of translated /J/K is ready for transfer over the internal MII.
It remains active until either the /T/R delimiter is recognized, link test indicates failure, or
no signal is detected. On any of these conditions, RXDV is de-asserted.
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ADM6996L
Function Description
3.4.8
Receive Errors
The RXER signal is used to communicate receiver error conditions. While the receiver is
in a state of holding RXDV asserted, the RXER will be asserted for each code word that
does not map to a valid code-group.
3.4.9
100Base-X Link Monitor
The 100Base-X link monitor function allows the receiver to ensure that reliable data is
being received. Without reliable data reception, the link monitor will halt both transmit
and receive operations until such time that a valid link is detected.
The ADM6996L performs the link integrity test as outlined in IEEE 100Base-X (Clause
24) link monitor state diagram. The link status is multiplexed with 10Mbits/s link status
to form the reportable link status bit in serial management register 1h, and driven to the
LNKACT pin.
When persistent signal energy is detected on the network, the logic moves into a LinkReady state after approximately 500 us, and waits for an enable from the auto negotiation
module. When receive, the link-up state is entered, and the transmission and reception
logic blocks become active. Should auto negotiation be disabled, the link integrity logic
moves immediately to the link-up state after entering the link-ready state.
3.4.10 Carrier Sense
Carrier sense (CRS) for 100Mbits/s operation is asserted upon the detection of two
noncontiguous zeros occurring within any 10-bit boundary of the received data stream.
The carrier sense function is independent of symbol alignment. In switch mode, CRS is
asserted during either packet transmission or reception. For repeater mode, CRS is
asserted only during packet reception. When the idle symbol pair is detected in the
received data stream, CRS is de-asserted. In repeater mode, CRS is only asserted due to
receive activity. CRS is intended to encapsulate RXDV.
3.4.11 Bad SSD Detection
A bad start of stream delimiter (Bad SSD) is an error condition that occurs in the
100Base-X receiver if carrier is detected (CRS asserted) and a valid /J/K set of codegroup (SSD) is not received.
If this condition is detected, then the ADM6996L will assert RXER and present
RXD[3:0] = 1110 to the internal MII for the cycles hat correspond to received 5B codegroups until at least two idle code-groups are detected. Once at least two idle code groups
are detected, RXER and CRS become de-asserted.
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ADM6996L
Function Description
3.4.12 Far-End Fault
Auto negotiation provides a mechanism for transferring information from the Local
Station to the link Partner that a remote fault has occurred for 100Base-TX. As auto
negotiation is not currently specified for operation over fiber, the far end fault indication
function (FEFI) provides this capability for 100Base-FX applications.
A remote fault is an error in the link that one station can detect while the other cannot. An
example of this is a disconnected wire at a station’s transmitter. This station will be
receiving valid data and detect that the link is good via the link integrity monitor, but will
not be able to detect that its transmission is not propagating to the other station.
A 100Base-FX station that detects such a remote fault may modify its transmitted idle
stream from all ones to a group of 84 ones followed by a single 0. This is referred to as
the FEFI idle pattern.
3.5
100Base-TX Transceiver
ADM6996L implements a TP-PMD compliant transceiver for 100Base-TX operation.
The differential transmit driver is shared by the 10Base-T and 100Base-TX subsystems.
This arrangement results in one device that uses the same external magnetic for both the
10Base-T and the 100Base-TX transmission with simple RC component connections.
The individually wave-shaped 10Base-T and 100Base-TX transmit signals are
multiplexed in the transmission output driver selection.
3.5.1
Transmit Drivers
The ADM6996L 100Base-TX transmission driver implements MLT-3 translation and
wave-shaping functions. The rise/fall time of the output signal is closely controlled to
conform to the target range specified in the ANSI TP-PMD standard.
3.5.2
Twisted-Pair Receiver
For 100Base-TX operation, the incoming signal is detected by the on-chip twisted-pair
receiver that consists of a differential line receiver, an adaptive equalizer and a base-line
wander compensation circuits.
The ADM6996L uses an adaptive equalizer that changes filter frequency response in
accordance with cable length. The cable length is estimated based on the incoming signal
strength. The equalizer tunes itself automatically for any cable length to compensate for
the amplitude and phase distortions incurred from the cable.
3.6
10Base-T Module
The 10Base-T Transceiver Module is IEEE 802.3 compliant. It includes the receiver,
transmitter, collision, heartbeat, loop back, jabber, wave shaper, and link integrity
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3-5
ADM6996L
Function Description
functions, as defined in the standard. Figure 3 provides an overview for the 10Base-T
module.
The ADM6996L 10Base-T module is comprised of the following functional blocks:
• Manchester encoder and decoder
• Collision detector
• Link test function
• Transmit driver and receiver
• Serial and parallel interface
• Jabber and SQE test functions
• Polarity detection and correction
3.6.1 Operation Modes
The ADM6996L 10Base-T module is capable of operating in either half-duplex mode or
full-duplex mode. In half-duplex mode, the ADM6996L functions as an IEEE 802.3
compliant transceiver with fully integrated filtering. The COL signal is asserted during
collisions or jabber events, and the CRS signal is asserted during transmit and receive. In
full duplex mode the ADM6996L can simultaneously transmit and receive data.
3.6.2
Manchester Encoder/Decoder
Data encoding and transmission begins when the transmission enable input (TXEN) goes
high and continues as long as the transceiver is in good link state. Transmission ends
when the transmission enable input goes low. The last transition occurs at the center of
the bit cell if the last bit is a 1, or at the boundary of the bit cell if the last bit is 0.
Decoding is accomplished by a differential input receiver circuit and a phase-locked loop
that separate the Manchester-encoded data stream into clock signals and NRZ data. The
decoder detects the end of a frame when no more mid bit transitions are detected. Within
one and half bit times after the last bit, carrier sense is de-asserted.
3.6.3
Transmit Driver and Receiver
The ADM6996L integrates all the required signal conditioning functions in its 10Base-T
block such that external filters are not required. Only one isolation transformer and
impedance matching resistors are needed for the 10Base-T transmit and receive interface.
The internal transmit filtering ensures that all the harmonics in the transmission signal are
attenuated properly.
3.6.4
Smart Squelch
The smart squelch circuit is responsible for determining when valid data is present on the
differential receive. The ADM6996L implements an intelligent receive squelch on the
RXP/RXN differential inputs to ensure that impulse noise on the receive inputs will not
be mistaken for a valid signal. The squelch circuitry employs a combination of amplitude
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ADM6996L
Function Description
and timing measurements (as specified in the IEEE 802.3 10Base-T standard) to
determine the validity of data on the twisted-pair inputs.
The signal at the start of the packet is checked by the analog squelch circuit and any
pulses not exceeding the squelch level (either positive or negative, depending upon
polarity) will be rejected. Once this first squelch level is overcome correctly, the opposite
squelch level must then be exceeded within 150ns. Finally, the signal must exceed the
original squelch level within an additional 150ns to ensure that the input waveform will
not be rejected.
Only after all these conditions have been satisfied will a control signal be generated to
indicate to the remainder of the circuitry that valid data is present.
Valid data is considered to be present until the squelch level has not been generated for a
time longer than 200 ns, indicating end of packet. Once good data has been detected, the
squelch levels are reduced to minimize the effect of noise, causing premature end-ofpacket detection. The receive squelch threshold level can be lowered for use in longer
cable applications. This is achieved by setting bit 10 of register address 11h.
3.7
Carrier Sense
Carrier Sense (CRS) is asserted due to receive activity once valid data is detected via the
smart squelch function. For 10 Mbits/s half duplex operation, CRS is asserted during
either packet transmission or reception. For 10 Mbits/s full duplex and repeater mode
operations, the CRS is asserted only due to receive activity.
3.8
Jabber Function
The jabber function monitors the ADM6996L output and disables the transmitter if it
attempts to transmit a longer than legal sized packet. If TXEN is high for greater than
24ms, the 10Base-T transmitter will be disabled. Once disabled by the jabber function,
the transmitter stays disabled for the entire time that the TXEN signal is asserted. This
signal has to be de-asserted for approximately 256 ms (The un-jab time) before the jabber
function re-enables the transmit outputs. The jabber function can be disabled by
programming bit 4 of register address 10h to high.
3.9
Link Test Function
A link pulse is used to check he integrity of the connection with the remote end. If valid
link pulses are not received, the link detector disables the 10Base-T twisted-pair
transmitter, receiver, and collision detection functions.
The link pulse generator produces pulses as defined in IEEE 802.3 10Base-T standard.
Each link pulse is nominally 100ns in duration and is transmitted every 16 ms, in the
absence of transmit data.
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ADM6996L
Function Description
3.10 Automatic Link Polarity Detection
ADM6996L’s 10Base-T transceiver module incorporates an “automatic link polarity
detection circuit”. The inverted polarity is determined when seven consecutive link pulses
of inverted polarity or three consecutive packets are received with inverted end-of-packet
pulses. If the input polarity is reversed, the error condition will be automatically corrected
and reported in bit 5 of register 10h.
3.11 Clock Synthesizer
The ADM6996L implements a clock synthesizer that generates all the reference clocks
needed from a single external frequency source. The clock source must be a TTL level
signal at 25 MHz +/- 50ppm
3.12 Auto Negotiation
The Auto Negotiation function provides a mechanism for exchanging configuration
information between two ends of a link segment and automatically selecting the highest
performance mode of operation supported by both devices. Fast Link Pulse (FLP) Bursts
provide the signaling used to communicate auto negotiation abilities between two devices
at each end of a link segment. For further detail regarding auto negotiation, refer to
Clause 28 of the IEEE 802.3u specification. The ADM6996L supports four different
Ethernet protocols, so the inclusion of auto negotiation ensures that the highest
performance protocol will be selected based on the ability of the link partner.
Highest priority relative to the following list:
• 100Base-TX full duplex (highest priority)
• 100Base-TX half duplex
• 10Base-T full duplex
• 10Base-T half duplex (lowest priority)
3.13 Memory Block
ADM6996L build in memory is divided as two blocks. One is MAC addressing table and
another one is data buffer.
MAC address Learning Table size is 2048 entry with each entry occupy eight bytes
length. These eight bytes data include 6 bytes source address, VLAN information, Port
information and Aging counter.
Data buffer is divided to 256 bytes/block. ADM6996L buffer management is per port
fixed block number and all port share one global buffer. This architecture can get better
memory utilization and network balance on different speed and duplex test condition.
Received packet will separate as several 256 bytes/block and chain together. If packet
size more than 256 bytes then ADM6996L will chain two or more block to store
receiving packet.
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ADM6996L
Function Description
3.14 Switch Functional Description
The ADM6996L uses a “store & forward” switching approach for the following reason:
Store & forward switches allow switching between different speed media (e.g. 10BaseX
and 100BaseX). Such switches require the large elastic buffer especially bridging
between a server on a 100Mbps network and clients on a 10Mbps segment.
Store & forward switches improve overall network performance by acting as a “network
cache”
Store & forward switches prevent the forwarding of corrupted packets by the frame check
sequence (FCS) before forwarding to the destination port.
3.15 Basic Operation
The ADM6996L receives incoming packets from one of its ports, searches in the Address
Table for the Destination MAC Address and then forwards the packet to the other port
within same VLAN group, if appropriate. If the destination address is not found in the
address table, the ADM6996L treats the packet as a broadcast packet and forwards the
packet to the other ports which in same VLAN group.
The ADM6996L automatically learns the port number of attached network devices by
examining the Source MAC Address of all incoming packets at wire speed. If the Source
Address is not found in the Address Table, the device adds it to the table.
3.15.1 Address Learning
The ADM6996L uses a hash algorithm to learn the MAC address and can learn up to 2K
MAC addresses. Address is stored in the Address Table. The ADM6996L searches for
the Source Address (SA) of an incoming packet in the Address Table and acts as below:
If the SA was not found in the Address Table (a new address), the ADM6996L waits
until the end of the packet (non-error packet) and updates the Address Table. If the SA
was found in the Address Table, then aging value of each corresponding entry will be
reset to 0.
When the DA is PAUSE command, then the learning process will be disabled
automatically by ADM6996L.
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ADM6996L
Function Description
3.15.2 Address Recognition and Packet Forwarding
The ADM6996L forwards the incoming packets between bridged ports according to the
Destination Address (DA) as below. All the packet forwarding will check VLAN first.
Forwarding port must same VLAN with source port.
1) If the DA is an UNICAST address and the address was found in the Address
Table, the ADM6996L will check the port number and acts as follows:
If the port number is equal to the port on which the packet was received,
the packet is discarded.
If the port number is different, the packet is forwarded across the bridge.
2) If the DA is an UNICAST address and the address was not found, the
ADM6996L treats it as a multicast packet and forwards across the bridge.
3) If the DA is a Multicast address, the packet is forwarded across the bridge.
4) If the DA is PAUSE Command (01-80-C2-00-00-01), then this packet will be
dropped by ADM6996L. ADM6996L can issue and learn PAUSE command.
5) ADM6996L will forward the packet with DA of ( 01-80-C2-00-00-00 ), filter out
the packet with DA of ( 01-80-C2-00-00-01 ), and forward the packet with DA of
( 01-80-C2-00-00-02 ~ 01-80-C2-00-00-0F )
3.15.3 Address Aging
Address aging is supported for topology changes such as an address moving from one
port to the other. When this happens, the ADM6996L internally has a 300 seconds timer
will aged out (remove) the address from the address table. Aging function can
enable/disable by user. Normally, disabling aging function is for security purpose.
3.15.4 Back off Algorithm
The ADM6996L implements the truncated exponential back off algorithm compliant to
the 802.3 CSMA-CD standard. ADM6996L will restart the back off algorithm by
choosing 0-9 collision counts. The ADM6996L resets the collision counter after 16
consecutive retransmit trials.
3.15.5 Inter-Packet Gap (IPG)
IPG is the idle time between any two successive packets from the same port. The typical
number is 96 bits time. The value is 9.6us for 10Mbps ETHERNET, 960ns for 100Mbps
fast ETHERNET and 96ns for 1000M. ADM6996L provide option of 92 bit gap in
EEPROM to prevent packet lost when turn off Flow Control and clock P.P.M. value
difference.
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ADM6996L
Function Description
3.15.6 Illegal Frames
The ADM6996L will discard all illegal frames such as runt packet (less than 64 bytes),
oversize packet (greater than 1518 or 1522 bytes) and bad CRC. Dribbling packing with
good CRC value will accept by ADM6996L. In case of bypass mode enabled,
ADM6996L will support tag and untagged packets with size up to 1522 bytes. In case of
non-bypass mode, ADM6996L will support tag packets up to 1526bytes, untagged
packets up to 1522bytes.
3.15.7 Half Duplex Flow Control
Back Pressure function is supported for half-duplex operation. When the ADM6996L
cannot allocate a receive buffer for an incoming packet (buffer full), the device will
transmit a jam pattern on the port, thus forcing a collision. Back Pressure is enabled by
the BPEN set during RESET asserting. An Infineon-ADMtek Co Ltd proprietary
algorithm is implemented inside the ADM6996L to prevent back pressure function cause
HUB partitioned under heavy traffic environment and reduce the packet lost rate to
increase the whole system performance.
3.15.8 Full Duplex Flow Control
When full duplex port run out of its receive buffer, a PAUSE packet command will be
issued by ADM6996L to notice the packet sender to pause transmission. This frame
based flow control is totally compliant to IEEE 802.3x. ADM6996L can issue or receive
pause packet.
3.15.9 Broadcast Storm filter
If Broadcast Storming filter is enable, the broadcast packets over the rising threshold
within 50 ms will be discarded by the threshold setting. See EEPROM Reg.10h.
Broadcast storm mode after initial:
- time interval : 50ms
the max. packet number = 7490 in 100Base, 749 in 10Base
Per Port Rising Threshold
00
01
10
All 100TX
Disable 10% 20%
Not
All Disable 1% 2%
100TX
11
40%
4%
Per Port Falling Threshold
00
01
10
All 100TX
Disable 5% 10%
Not
All Disable 0.5% 1%
100TX
11
20%
2%
3.16 Auto TP MDIX function
At normal application which Switch connect to NIC card is by one by one TP cable. If
Infineon-ADMtek Co. Ltd.
3-11
ADM6996L
Function Description
Switch connect other device such as another Switch must by two way. First one is Cross
Over TP cable. Second way is use extra RJ45 which crossover internal TX+- and RX+signal. By second way customer can use one by one cable to connect two Switch devices.
All these effort need extra cost and not good solution. ADM6996L provide Auto MDIX
function which can adjust TX+- and RX+- at correct pin. User can use one by one cable
between ADM6996L and other device. This function can be Enable/Disable by hardware
pin and EEPROM configuration register 0x01h~0x09h bit 15. If hardware pin set all port
at Auto MDIX mode then EEPROM setting is useless. If hardware pin set all port at non
Auto MDIX mode then EEPROM can set each port this function enable or disable.
3.17 Port Locking
Port locking function will provide customer simple way to limit per port user number to
one. If this function is turn on then ADM6996L will lock first MAC address in learning
table. After this MAC address locking will never age out except Reset signal. Another
MAC address which not same as locking one will be dropped. ADM6996L provide one
MAC address per port. This function is per port setting. When turn on Port Locking
function, recommend customer turn off aging function. See EEPROM register 0x12h bit
0~8.
3.18 VLAN setting & Tag/Untag & port-base VLAN
ADM6996L supports bypass mode and untagged port as default setting while the chip is
power-on. Thus, every packet with or without tag will be forwarding to the destination
port without any modification by ADM6996L. Meanwhile port-base VLAN could be
enabled according to the PVID value ( user define 4bits to map 16 groups written at
register 13 to register 22 ) of the configuration content of each port.
ADM6996L also supports 16 802.1Q VLAN groups. In VLAN four bytes tag include
twelve VLAN ID. ADM6996L learn user define four bits of VID. If user need to use this
function, two EEPROM registers are needed to be programmed first :
* Port VID number at EEPROM register 0x01h~0x09h bit 13~10, register 0x28h~0x2bh
and register 0x2ch bit 7~0: ADM6996L will check coming packet. If coming packet is
non VLAN packet then ADM6996L will use PVID as VLAN group reference.
ADM6996L will use packet’s VLAN value when receive tagged packet.
* VLAN Group Mapping Register. EEPROM register 013h~022h define VLAN grouping
value. User use these register to define VLAN group.
User can define each port as Tag port or Untag port by Configuration register Bit 4. The
operation of packet between Tag port and Untag port can explain by follow example:
Example1: Port receives Untag packet and send to Untag port.
ADM6996L will check the port user define four bits of VLAN ID first then check
VLAN group resister. If destination port same VLAN as receiving port then this packet
will forward to destination port without any change. If destination port not same VLAN
Infineon-ADMtek Co. Ltd.
3-12
ADM6996L
Function Description
as receiving port then this packet will be dropped.
Example2: Port receives Untag packet and send to Tag port.
ADM6996L will check the port user define fours bits of VLAN ID first then check
VLAN group resister. If destination port same VLAN as receiving port than this packet
will forward to destination port with four byte VLAN Tag and new CRC. If destination
port not same VLAN as receiving port then this packet will be dropped.
Example3: Port receives Tag packet and send to Untag port.
ADM6996L will check the packet VLAN ID first then check VLAN group resister.
If destination port same VLAN as receiving port than this packet will forward to
destination port after remove four bytes with new CRC error. If destination port not same
VLAN as receiving port then this packet will be dropped.
Example4: Port receives Tag packet and send to Tag port.
ADM6996L will check the user define packet VLAN ID first then check VLAN
group resister. If destination port same VLAN as receiving port than this packet will
forward to destination port without any change. If destination port not same VLAN as
receiving port then this packet will be dropped.
3.19 Priority Setting
It is a trend that data, voice and video will be put on networking, Switch not only deal
data packet but also provide service of multimedia data. ADM6996L provides two
priority queues on each port with N:1 rate. See EEPROM Reg.0x10h.
This priority function can set three ways as below:
* By Port Base: Set specific port at specific queue. ADM6996L only check the port
priority and not check packet’s content VLAN and TOS.
* By VLAN first: ADM6996L check VLAN three priority bit first then IP TOS priority
bits.
* By IP TOS first: ADM6996L check IP TOS three priority bit first then VLAN three
priority bits.
If port set at VLAN/TOS priority but receiving packet without VLAN or TOS
information then port base priority will be used .
3.20 LED Display
Three LED per port are provided by ADM6996L. Link/Act, Duplex/Col & Speed are
three LED display of ADM6996L. Dual color LED mode also supported by ADM6996L.
For easy production purpose ADM6996L will send test signal to each LED at power on
reset stage. EEPROM register 0x12h define LED configuration table.
Infineon-ADMtek Co. Ltd.
3-13
ADM6996L
Function Description
ADM6996L LED is active Low signal. Dupcol0 & Dupcol1 will check external signal at
Reset time. If external signal add pull high then LED will active Low. If external signal
add pull down resister then LED will drive high.
Single
Color
R?
510
Mode
D?
LED-High
VCC
LED
Dual
Link /Ac t
R?
Color
510
Mode
D?
Speed
LED
D?
LED
Infineon-ADMtek Co. Ltd.
3-14
ADM6996L
Register Description
Chapter 4 Register Description
4.1
EEPROM Content
EEPROM provides ADM6996L many options setting such as:
•
•
•
•
•
•
4.2
Port Configuration: Speed, Duplex, Flow Control Capability and Tag/ Untag.
VLAN & TOS Priority Mapping
Broadcast Storming rate and Trunk.
Fiber Select, Auto MDIX select
VLAN Mapping
Per Port Buffer number
EEPROM Register Map
Register
0x00h
0x01h
0x02h
0x03h
0x04h
0x05h
0x06h
0x07h
0x08h
0x09h
0x0ah
0x0bh
0x0ch
0x0dh
0x0eh
0x0fh
0x10h
0x11h
0x12h
0x13h
0x14h
0x15h
0x16h
0x17h
0x18h
0x19h
Bit 15- 8
Signature
Port 0 Configuration
Reserved
Port 1 Configuration
Reserved
Port 2 Configuration
Reserved
Port 3 Configuration
Port 4 Configuration
Port 5 Configuration
VID 0, 1
Reserved
option
Configuration Register
Reserved
Reserved
VLAN priority Map High
TOS priority Map High
Miscellaneous Configuration 0
Miscellaneous Configuration 1
Miscellaneous Configuration 2
VLAN 0 outbound Port Map
VLAN 1 outbound Port Map
VLAN 2 outbound Port Map
VLAN 3 outbound Port Map
VLAN 4 outbound Port Map
VLAN 5 outbound Port Map
VLAN 6 outbound Port Map
Infineon-ADMtek Co. Ltd.
Bit 7 - 0
Signature
Port 0 Configuration
Reserved
Port 1 Configuration
Reserved
Port 2 Configuration
Reserved
Port 3 Configuration
Port 4 Configuration
Port 5 Configuration
Reserved
Default Value
0x4154h
0x040fh
0x040fh
0x040fh
0x040fh
0x040fh
0x040fh
0x040fh
0x040fh
0x040fh
0x5902h
Configuration Register
Reserved
Reserved
VLAN priority Map Low
TOS priority Map Low
Miscellaneous Configuration 0
Miscellaneous Configuration 1
Miscellaneous Configuration 2
VLAN 0 outbound Port Map
VLAN 1 outbound Port Map
VLAN 2 outbound Port Map
VLAN 3 outbound Port Map
VLAN 4 outbound Port Map
VLAN 5 outbound Port Map
VLAN 6 outbound Port Map
0x8000h
0xfa50h
0xfa50h
0x5500h
0x5500h
0x0040h
0xff00h
0x3600h
0xffffh
0xffffh
0xffffh
0xffffh
0xffffh
0xffffh
0xffffh
4-1
ADM6996L
Register Description
Register
0x1ah
0x1bh
0x1ch
0x1dh
0x1eh
0x1fh
0x20h
0x21h
0x22h
0x23h
0x24h
0x25h
0x26h
0x27h
0x28h
0x29h
0x2ah
0x2bh
0x2ch
0x2dh
0x2eh
0x2fh
0x30h
0x31h
0x32h
0x33h
4.3
Bit 15- 8
Bit 7 - 0
VLAN 7 outbound Port Map
VLAN 7 outbound Port Map
VLAN 8 outbound Port Map
VLAN 8 outbound Port Map
VLAN 9 outbound Port Map
VLAN 9 outbound Port Map
VLAN 10 outbound Port Map
VLAN 10 outbound Port Map
VLAN 11 outbound Port Map
VLAN 11 outbound Port Map
VLAN 12 outbound Port Map
VLAN 12 outbound Port Map
VLAN 13 outbound Port Map
VLAN 13 outbound Port Map
VLAN 14 outbound Port Map
VLAN 14 outbound Port Map
VLAN 15 outbound Port Map
VLAN 15 outbound Port Map
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
P0 PVID [11:4]
Reserved
P1 PVID [11:4]
Reserved
P2 PVID [11:4]
P4 PVID [11:4]
P3 PVID [11:4]
VLAN Group Configuration
P5 PVID [11:4]
Reserved
Reserved
PHY Restart
Miscellaneous Configuration 3
Miscellaneous Configuration 3
Bandwidth Control Register 3,2
Bandwidth Control Register 1,0
Reserved
Bandwidth Control Register 5,4
Bandwidth Control Enable
Bandwidth Control Enable
Default Value
0xffffh
0xffffh
0xffffh
0xffffh
0xffffh
0xffffh
0xffffh
0xffffh
0xffffh
0x0000h
0x0000h
0x0000h
0x0000h
0x0000h
0x0000h
0x0000h
0x0000h
0x0000h
0xd000h
0x4442h
0x0000h
0x0000h
0x0987h
0x0000h
0x0000h
0x0000h
EEPROM Register
4.3.1 Signature Register, offset: 0x00h
Bits
Type Description
15:0
RO The value must be 4154h(AT)
Initial value
0x4154h
Note:
ADM6996L will check register 0 value before read all EEPROM content. If this value
not match with 0x4154h then other values in EEPROM will be useless. ADM6996L will
use internal default value. User cannot write Signature register when programming
ADM6996L internal register.
Infineon-ADMtek Co. Ltd.
4-2
ADM6996L
Register Description
4.3.2
Bits
0
Configuration Registers, offset: 0x01h ~ 0x09h
Type Description
Initial value
R/W 802.3x Flow control command ability. 1: enable.
0x1h
0: disable.
1
R/W Auto negotiation Enable. 1: enable, 0: disable.
0x1h
2
R/W Speed. 1: 100M, 0: 10M.
0x1h
3
R/W Duplex. 1: Full Duplex, 0: Half Duplex.
0x1h
4
R/W Output Packet Tagging. 1: Tag. 0:UnTag.
0x0h
5
R/W Port Disable. 1: disable port. 0: enable port.
0x0h
6
R/W TOS over VLAN priority. 1: Check TOS first, 0: Check VLAN.
0x0h
0x0h
7
R/W Enable port-base priority. 1: Port Base Priority. 0: VLAN or TOS. If
packet without VLAN or TOS then port priority turn on.
Note:
If this bit turn on then ADM6996L will not check TOS or VLAN as
priority reference. ADM6996L will check port base priority only.
ADM6996L default is bypass mode which checks port base priority only.
If user want check VLAN tag priority then must set chip at Tag mode.
9:8
R/W Port-base priority.
0x0h
13:10 R/W PVID. Port VLAN ID. Check Register 0x28h~0x2ch for other
0x1h
PVID[11:4]
0x0h
14
R/W Select FX. 1: FX mode. 0: TP mode.
Note:
Port7 TX/FX can set by hardware Reset latch value P7FX. If hardware
pin set Port7 as FX then this bit is useless. If hardware pin set Port7 as
TX then this pin can set Port7 as FX or TX.
0x0h
15
R/W Crossover Auto MDIX enable. 1: enable. 0: disable.
Note:
Hardware Reset latch value EECK can set global Auto MDIX function. If
hardware pin set all port at Auto MDIX then this bit is useless. If
hardware pin set chip at non Auto MDIX then this bit can set each port at
Auto MDIX.
4.3.3 Reserved Register, offset: 0x0ah
Bits
Type Description
8:0
RO Reserved
9
R/W Replaced packet VID 0, 1 by PVID. 1: enable, 0: disable.
15:10 RO Reserved
Infineon-ADMtek Co. Ltd.
Initial value
0x102h
0x0h
0x16h
4-3
ADM6996L
Register Description
4.3.4 Configuration Register, offset: 0x0bh
Bits
Type Description
Initial value
5:0
RO Reserved
0x0h
0x0h
6
R/W Enable IPG leveling. 1/92 bit. 0/96 bit.
Note:
When this bit is enable ADM6996L will transmit packet out at 92 bit IPG
to clean buffer. If user disables this function then ADM6996L will
transmit packet at 96 bit.
7
R/W Enable Trunk. 1: enable Port3, 4 as Trunk port. 0: disable.
0x0h
14:8
RO Reserved
0x0h
15
R/W Disable Far_End_Fault detection. 1: disable. 0: enable.
0x1h
4.3.5 Reserved Register, offset: 0x0ch~0x0dh
Bits Type Description
15:0
RO Reserved
Initial value
0xfa5h
4.3.6
Bits
1:0
3:2
5:4
7:6
9:8
11:10
13:12
15:14
Initial value
0x0h
0x0h
0x1h
0x1h
0x2h
0x2h
0x3h
0x3h
VLAN priority Map Register, offset: 0x0eh
Type Description
R/W Mapped priority of tag value (VLAN) 0.
R/W Mapped priority of tag value (VLAN) 1.
R/W Mapped priority of tag value (VLAN) 2.
R/W Mapped priority of tag value (VLAN) 3.
R/W Mapped priority of tag value (VLAN) 4.
R/W Mapped priority of tag value (VLAN) 5.
R/W Mapped priority of tag value (VLAN) 6.
R/W Mapped priority of tag value (VLAN) 7.
Note:
Value 3 ~ 0 are for priority queue Q3~Q0 respectively.
The Weight ratio is Q3 : Q2 : Q1: Q0 = 8 : 4 : 2 : 1.
The default is port-base priority for un-tag packet and non_IP frame.
4.3.7
Bits
1:0
3:2
5:4
7:6
9:8
11:10
TOS priority Map Register, offset: 0x0fh
Type Description
R/W Mapped priority of tag value (TOS) 0.
R/W Mapped priority of tag value (TOS) 1.
R/W Mapped priority of tag value (TOS) 2.
R/W Mapped priority of tag value (TOS) 3.
R/W Mapped priority of tag value (TOS) 4.
R/W Mapped priority of tag value (TOS) 5.
Infineon-ADMtek Co. Ltd.
Initial value
0x0h
0x0h
0x1h
0x1h
0x2h
0x2h
4-4
ADM6996L
Register Description
Bits
Type Description
13:12 R/W Mapped priority of tag value (TOS) 6.
15:14 R/W Mapped priority of tag value (TOS) 7.
Initial value
0x3h
0x3h
Note:
Value 3 ~ 0 are for priority queue Q3~Q0 respectively.
The Weight ratio is Q3 : Q2 : Q1: Q0 = 8 : 4 : 2 : 1.
The default is port-base priority for un-tag packet and non_IP frame.
4.3.8
Packet with Priority: Normal packet content
Ethernet Packet from Layer 2
Preamble/SFD
Destination (6
bytes)
Byte 0~5
Source (6 bytes) Packet length (2 Data (46-1500
bytes)
bytes)
Byte 6~11
Byte 12~13
CRC (4 bytes)
Byte 14~
4.3.9 VLAN Packet
ADM6996L will check packet byte 12 &13. If byte[12:13]=8100h then this packet is a
VLAN packet
Tag Protocol TD 8100
Byte 12~13
Tag Control Information LEN Length
TCI
Byte14~15
Byte 16~17
Routing Information
Byte 18
Byte 14~15: Tag Control Information TCI
Bit[15:13]: User Priority 7~0
Bit 12: Canonical Format Indicator (CFI)
Bit[11~0]: VLAN ID. The ADM6996L will use bit[3:0] as VLAN group.
Infineon-ADMtek Co. Ltd.
4-5
ADM6996L
Register Description
4.3.10 TOS IP Packet
ADM6996L check byte 12 &13 if this value is 0800h then ADM6996L knows this is a
TOP priority packet.
Type 0800
Byte 12~13
IP Header
Byte 14~15
IP header define
Byte 14
Bit[7:0]: IP protocol version number & header length.
Byte 15: Service type
Bit[7~5]: IP Priority (Precedence ) from 7~0
Bit 4: No Delay (D)
Bit 3: High Throughput
Bit 2: High Reliability (R)
Bit[1:0]: Reserved
4.3.11
Bits
1:0
2
3
4
5
6
7
9:8
11:10
13:12
15:14
Miscellaneous Configuration Register, offset: 0x10h
Type Description
R/W Broadcast Storming Threshold[1:0]. See below table.
R/W Broadcast Storming Enable. 1/ enable, 0/disable. Default 0.
R/W Reserved. Default 0.
R/W XCRC. 1/disable CRC check, 0/enable CRC Check. Default 0.
RO Reserved
RO Reserved
R/W Aging Disable. 1/disable aging, 0/enable aging. Default 0.
R/W Discard mode (drop scheme for Q0)
R/W Discard mode (drop scheme for Q1)
R/W Discard mode (drop scheme for Q2)
R/W Discard mode (drop scheme for Q3)
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x1h
0x0h
0x0h
0x0h
0x0h
0x0h
Note:
Bit[1:0]: Broadcast Storming threshold.
Broadcast storm mode after initial:
- time interval : 50ms
the max. packet number = 7490 in 100Base, 749 in 10Base
Infineon-ADMtek Co. Ltd.
4-1
ADM6996L
Register Description
Note (Continued):
- per port rising threshold
00
01
All
Disable
10%
100TX
Not All Disable
1%
100TX
10
20%
11
40%
2%
4%
- per port falling threshold
00
01
10
11
All
Disable
5%
10%
20%
100TX
Not All Disable 0.5%
1%
2%
100TX
Bit 2: Broadcast Storming Enable. 0/Disable. 1/Enable.
Bit 4: CRC check disable. 1/ Disable. 0/Enable.
Bit 7: Aging Disable. 1/Disable. 0/Enable.
-
Drop Scheme for each queue
Discard Mode
00
01
Utilization
TBD
0%
0%
10
11
25%
50%
4.3.12 VLAN mode select Register, offset: 0x11h
Bits
Type Description
3:0
RO Reserved
4
R/W MAC Clone enable
0: Normal mode. Learning with SA only. ADM6996L fill/search MAC
table by SA or DA only.
1: MAC Clone mode. Learning with SA, VID0. ADM6996L fill/search
MAC table by SA or DA with VID0. This bit can let chip learn two same
addresses with different VID0.
5
R/W VLAN mode select
0: by-pass mode with port-base VLAN.
1: 802.1Q base VLAN.
7:6
RO Reserved
15:8
RO Reserved
Initial value
0x0h
0x0h
0x0h
0x0h
0xffh
Note:
Below is Bit4, 5 VLAN Tag and MAC application example.
Infineon-ADMtek Co. Ltd.
4-2
ADM6996L
Register Description
Below is Router old architecture. The disadvantages of this are:
1. WAN port only support 10M Half-Duplex and non-MDIX function.
2. Need extra 10M NIC cost.
3. ISA bus will become bottleneck of whole system.
CPU with
one MII
ISA
10M Half
NIC
MII
Port4 MAC MII Port
Port0
Port1
Port2
Port3
10M Half Non
MDIX WAN Port
4 100/10 LAN Port
Below is new architecture by using ADM6996L serial chip VLAN function. The
advantages of below are:
1. WAN Port can upgrade to 100/10 Full/Half , Auto MDIX.
2. WAN/LAN Port is programmable and put on same Switch.
3. No need extra NIC and save lot of cost.
4. High bandwidth of MII port up to 200M speed.
CPU with
one MII
MII
Port5 MAC MII Port
Port0
Port1
Port2
4 100/10 LAN Port
Port3
Port4
100/10
WAN
Port
VLAN & MAC Clone Function
New Router application works well on normal application. If user’s ISP vendor( cable
modem) lock Registration Card’s ID then Router CPU must send this Lock Registration
Card’s ID to WAN Port. One condition happen is there exist two same MAC ID on this
Infineon-ADMtek Co. Ltd.
4-3
ADM6996L
Register Description
Switch. One is original Card and another one is CPU. This will make Switch learning
table trouble.
ADM6996L provide MAC Clone function that allow two same MAC address with
different VLAN ID0 on learning table. This will solve Lock registration Card’s ID issue.
AT8989P serial chip will put these two same MAC addresses with different VLAN ID0
at different learning table entry.
How to Set ADM6996L on Router.
Port0~3: LAN Port.
Port4: WAN Port.
Port5: MII Port as CPU Port.
Step1: Set Register 0x11h bit4 and bit5 to 1.
{Coding: Write Register 0x11h as 0xff30h}
Step2: Set Port0~3 as Untag Port and set PVID=1.
{Coding: Write Register 0x01h, 0x03h, 0x05h, 0x07h as 0x840f. Port0~3 as
Untag, PVID=1, Enable MDIX}
Step3: Set Port4 as Untag Port and set PVID=2.
{ Coding:Write Register 0x08h as 0x880fh. Port4 as Untag, PVID=2, Enable
MDIX.}
Step4: Set Port5 MII Port as Tag Port and set PVID=2.
{Coding:Write Register 0x09h as 0x881fh. Port5 MII port as Tag, PVID=2.}
Step5: Group Port0, 1, 2, 3, 5 as VLAN 1.
{Coding: Write Register 0x14h as 0x0155h. VLAN1 cover Port0, 1, 2, 3, 5.}
Step6: Group Port4, 5 as VLAN 2.
{Coding: Write Register 0x15h as 0x0180h. VLAN2 cover Port4, 5.}
How MAC Clone Operation:
1. LAN to LAN/CPU Traffic.
ADM6996L LAN traffic to LAN/CPU only. Traffic to another LAN port will be
untag packet. Traffic to CPU is Tag packet with VID=1. CPU can check VID to
distinguish LAN traffic or WAN traffic.
2. WAN to CPU Traffic.
ADM6996L WAN traffic to CPU only. Traffic to CPU is Tag packet with VID=2.
CPU can check VID to distinguish LAN traffic or WAN traffic.
3. CPU to LAN Packet.
ADM6996L CPU Packet to LAN port must add VID=1 in VLAN field.
ADM6996L check VID to distinguish LAN traffic or WAN traffic. LAN output
packet is Untag.
4. CPU to WAN Packet.
ADM6996L CPU Packet to WAN port must add VID=2 in VLAN filed.
ADM6996L check VID to distinguish LAN traffic or WAN traffic. WAN output
packet is Untag.
5. ADM6996L learning sequence
Infineon-ADMtek Co. Ltd.
4-4
ADM6996L
Register Description
ADM6996L will check VLAN mapping setting first then check learning table.
User does not worry LAN/WAN traffic mix up.
Bit 10: Half Duplex Back Pressure enable. 1/enable, 0/disable.
4.3.13
Bits
0
1
2
3
4
5
6
7
8
10:9
11
13:12
14
15
Miscellaneous Configuration register, offset: 0x12h
Type Description
R/W Port0 MAC Lock. 1: Lock first MAC source address, 0: disable.
R/W Reserved
R/W Port1 MAC Lock. 1: Lock first MAC source address, 0: disable.
R/W Reserved
R/W Port2 MAC Lock. 1: Lock first MAC source address, 0: disable.
R/W Reserved
R/W Port3 MAC Lock. 1: Lock first MAC source address, 0: disable.
R/W Port4 MAC Lock. 1: Lock first MAC source address, 0: disable.
R/W Port5 MAC Lock. 1: Lock first MAC source address, 0: disable.
R/W Reserved
R/W Reserved
R/W Reserved
R/W Reserved
R/W Drop packet when excessive collision happen enable. 1: enable, 0:
disable.
4.3.14 VLAN mapping table registers, offset: 0x22h ~ 0x13h
Bits
Type Description
8:0
R/W VLAN mapping table.
15:9
RO Reserved
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x3h
0x0h
0x3h
0x0h
0x0h
Initial value
0x1ffh
0x7fh
Note:
16 VLAN Group: See Register 0x2ch bit 11=0
Bit0: Port0
Bit6: Port3
Bit2: Port1
Bit7: Port4
Bit4: Port2
Bit8: Port5.
Select the VLAN group ports is to set the corresponding bits to 1.
4.3.15 Reserved Register, offset: 0x27h ~ 0x23h
Bits
Type Description
15:0 R/W Reserved
Infineon-ADMtek Co. Ltd.
Initial value
0x0h
4-5
ADM6996L
Register Description
4.3.16 Port0, 1 PVID bit 11 ~ 4 Configuration Register, offset: 0x28h
Bits Type Description
7:0
R/W Port0 PVID bit 11~4. These 8 bits combine with register 0x01h Bit
[13~10] as full 12 bit VID.
15:8 RO
Reserved
Initial value
0x0h
4.3.17 Port2, 3 PVID bit 11 ~ 4 Configuration Register, offset: 0x29h
Bits
Type Description
7:0
R/W Port1 PVID bit 11~4. These 8 bits combine with register 0x03h
Bit[13~10] as full 12 bit VID.
15:8
RO Reserved
Initial value
0x0h
4.3.18 Port4, 5 PVID bit 11~4 Configuration Register, offset: 0x2ah
Bits
Type Description
7:0
R/W Port2 PVID bit 11~4. These 8 bits combine with register 0x05h
Bit[13~10] as full 12 bit VID.
15:8
RO Reserved
Initial value
0x0h
4.3.19 Port6, 7 PVID bit 11~4 Configuration Register, offset: 0x2bh
Bits
Type Description
7:0
R/W Port3 PVID bit 11~4. These 8 bits combine with register 0x07h
Bit[13~10] as full 12 bit VID.
15:8
RO Port4 PVID bit 11~4. These 8 bits combine with register 0x08h
Bit[13~10] as full 12 bit VID.
4.3.20 Port8 PVID bit 11~4 & VLAN group shift bits Configuration Register
offset: 0x2ch
Bits
Type Description
7:0
R/W Port5 PVID bit 11~4. These 8 bits combine with register 0x09h
Bit[13~10] as full 12 bit VID.
10:8
R/W Tag shift for VLAN grouping. Default 000.
0: VID[3:0] 1: VID[4:1] 2: VID[5:2]
3: VID[6:3] 4: VID[7:4] 5: VID[8:5]
6: VID[9:6] 7: VID[10:7]
11
R/W Reserved
12
R/W Control reserved MAC (0180C2000010-0180C20000FF)
1: Forward, 0: Discard.
13
R/W Control reserved MAC (0180C2000002- 0180C200000F)
1: Forward, 0: Discard.
Infineon-ADMtek Co. Ltd.
0x0h
0x0h
0x0h
Initial value
0x0h
0x0h
Initial value
0x0h
0x0h
0x0h
0x1h
0x1h
4-1
ADM6996L
Bits
14
15
Register Description
Type Description
R/W Control reserved MAC (0180C2000001)
1: Forward, 0: Discard.
R/W Control reserved MAC (0180C2000000)
1: Forward, 0: Discard.
Initial value
0x0h
0x1h
Note:
Bit[10:8]: VLAN Tag shift register. ADM6996L will select 4 bit from total 12 bit VID as
VLAN group reference.
Bit[15:12]: IEEE 802.3 reserved DA forward or drop police.
4.3.21 Reserved Register, offset: 0x2dh
Bits
Type Description
15:0 R/W Reserved
Initial value
0x4442h
4.3.22 Reserved Register, offset: 0x2eh
Bits
Type Description
15:0
R/W Reserved
Initial value
0x0000h
4.3.23 PHY Restart, offset: 0x2fh
Bits Type Description
15:0 R/W Write 0x0000h to this register will restart internal PHYs.
4.3.24 Miscellaneous Configuration Register, offset: 0x30h
Bits
Type Description
0
R/W Reserved
1
R/W Reserved
2
R/W Reserved
4:3
R/W Reserved
5
R/W MAC Clone Enable Bit[1].
6
R/W MII Speed Double.
1: Port 5 MII RXCLK, TXCLK maximum speed is 50MHz
0: Port 5 MII RXCLK, TXCLK maximum speed is 25MHz
7
R/W Reserved
8
R/W Reserved
9
R/W Dual Speed Hub COL_LED Enable.
1: Dual Speed Hub LED display.
Port0 Col LED: 10M Col LED.
Port1 Col LED: 100M Col LED.
0: Normal LED display.
10
R/W Reserved
Infineon-ADMtek Co. Ltd.
Initial value
0x0000h
Initial value
0x1h
0x1h
0x1h
0x0h
0x0h
0x0h
0x1h
0x1h
0x0h
0x0h
4-2
ADM6996L
Register Description
Bits
11
12
Type Description
R/W Reserved
R/W Port 4 LED Mode.
1:Link/Act/Speed
0:LinkAct/DupCol/Speed
15:13 R/W Reserved
Initial value
0x1h
0x0h
0x0h
4.3.25 Bandwidth Control Register0~3, offset: 0x31h
Bits
Type Description
2:0
R/W Port 0 Meter Threshold Control. Reference table below.
3
R/W Receive Packet Length Counted on the Source Port 0.
0 = The switch will add length to the P0 counter.
6:4
R/W Port 1 Meter Threshold Control, default 000. Reference table below.
7
R/W Receive Packet Length Counted on the Source Port 1.
0 = The switch will add length to the P1 counter.
10:8
R/W Port 2 Meter Threshold Control, default 000. Reference table below.
11
R/W Receive Packet Length Counted on the Source Port 2.
0 = The switch will add length to the P2 counter.
14:12 R/W Port 3 Meter Threshold Control. Reference table below.
15
R/W Receive Packet Length Counted on the Source Port 3.
0 = The switch will add length to the P3 counter.
Note: Reference Table
000
001
256K
512K
010
1M
011
2M
100
5M
101
10M
110
20M
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
111
50M
4.3.26 Bandwidth Control Register 4~5, offset: 0x32h
Bits
Type Description
2:0
R/W Port 4 Meter Threshold Control. Reference table below.
3
R/W Receive Packet Length Counted on the Source Port 4
0 = The switch will add length to the P4 counter.
6:4
R/W Port 5 Meter Threshold Control
7
R/W Receive Packet Length Counted on the Source Port 5
0 = The switch will add length to the P5 counter.
15:8
RO Reserved
Note: Reference Table
000
001
256K
512K
Infineon-ADMtek Co. Ltd.
010
1M
011
2M
100
5M
101
10M
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
110
20M
111
50M
4-3
ADM6996L
Register Description
4.3.27 Bandwidth Control Enable Register, offset: 0x33h
Bits
Type Description
0
R/W Bandwidth Control Enable for Port 0.
1 = Port 0 enables the bandwidth control.
0 = Port 0 disables the bandwidth control.
1
R/W Reserved
2
R/W Bandwidth Control Enable for Port 1.
3
R/W Reserved
4
R/W Bandwidth Control Enable for Port 2.
5
R/W Reserved
6
R/W Bandwidth Control Enable for Port 3.
7
R/W Bandwidth Control Enable for Port 4.
8
R/W Bandwidth Control Enable for Port 5.
15:9
RO Reserved
4.4
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
EEPROM Access
Customer can select ADM6996L read EEPROM contents as chip setting or not.
ADM6996L will check the signature of
EEPROM to decide read content of EEPROM or not.
RESETL & EEPROM content relationship
RESETL
CS
SK
DI
DO
0
High Impedance
High Impedance
High Impedance
High Impedance
Rising edge 0 1 Output
(30ms)
Output
Output
Input
1 (after 30ms)
Input
Output
Input
Input
Keep at least 30ms after RESETL from 0 1. ADM6996L will read data from EEPROM.
After RESETL if CPU update EEPROM that ADM6996L will update configuration
registers too.
When CPU programming EEPROM & ADM6996L, ADM6996L recognizes the
EEPROM WRITE instruction only. If there is any Protection instruction before or after
the EEPROM WRITE instruction, CPU needs to generate separated CS signal cycle for
each Protection & WRITE instruction.
CPU can directly program ADM6996L after 30ms of Reset signal rising edge with or
without EEPROM
Infineon-ADMtek Co. Ltd.
4-4
ADM6996L
Register Description
ADM6996L serial chips will latch hardware-reset value as recommend value. It includes
EEPROM interface:
EECS: Internal Pull down 40K resister.
EESK: TP port Auto-MDIX select. Internal pull down 40K resister as non Auto-MDIX
mode.
EDI: Dual Color Select. Internal pull down 40K resister as Single Color Mode.
EDO: EEPROM enable. Internal pull up 40K resister as EEPROM enable.
Below Figure is ADM6996L serial chips EEPROM pins operation at different stage.
Reset signal is control by CPU with at least 100ms low. Point1 is Reset rising edge. CPU
must prepare proper value on EECS(0), EESK, EDI, EDO(1) before this rising edge.
ADM6996L will read this value into chip at Point2. CPU must keep these values over
point2. Point2 is 200ns after Reset rising edge.
ADM6996L serial chips will read EEPROM content at Point4 which 800ns far away
from the rising edge of Reset. CPU must turn EEPROM pins EECS, EESK, EDI and
EDO to High-Z or pull high before Point4.
If user want change state to High-Z or pull high on EEPROM pins, the order is CS-> DI > DO -> SK is better.
800nS
200nS
200nS
100mS
Reset
1
2
3
4
5
A little bit different with the timing on writing EEPROM. See below graph. Must be
carefully is when CS go down after write a command, SK must issue at least one clock.
This is a difference between ADM6996L with EEPROM write timing. If system without
EEPROM then user must write ADM6996L internal register by 93C66 timing. If user
uses EEPROM then the writing timing is depend on EEPROM type.
CS
SK
Write Command
Infineon-ADMtek Co. Ltd.
4-5
ADM6996L
4.5
Register Description
Serial Register Map
Register
0x00h
0x01h
0x02h
0x03h
0x04h
0x05h
0x06h
0x07h
0x08h
0x09h
0x0ah
0x0bh
0x0ch
0x0dh
0x0eh
0x0fh
0x10h
0x11h
0x12h
0x13h
0x14h
0x15h
0x16h
0x17h
0x18h
0x19h
0x1ah
0x1bh
0x1ch
0x1dh
0x1eh
0x1fh
0x20h
0x21h
0x22h
0x23h
0x24h
0x25h
0x26h
0x27h
0x28h
0x29h
Infineon-ADMtek Co. Ltd.
Bit 31- 0
Chip Identifier
Port Status 0
Port Status 1
Cable Broken Status
Port 0 Receive Packet Count
Reserved
Port 1 Receive Packet Count
Reserved
Port 2 Receive Packet Count
Reserved
Port 3 Receive Packet Count
Port 4 Receive Packet Count
Port 5 Receive Packet Count
Port 0 Receive Packet Byte Count
Reserved
Port 1 Receive Packet Byte Count
Reserved
Port 2 Receive Packet Byte Count
Reserved
Port 3 Receive Packet Byte Count
Port 4 Receive Packet Byte Count
Port 5 Receive Packet Byte Count
Port 0 Transmit Packet Count
Reserved
Port 1 Transmit Packet Count
Reserved
Port 2 Transmit Packet Count
Reserved
Port 3 Transmit Packet Count
Port 4 Transmit Packet Count
Port 5 Transmit Packet Count
Port 0 Transmit Packet Byte Count
Reserved
Port 1 Transmit Packet Byte Count
Reserved
Port 2 Transmit Packet Byte Count
Reserved
Port 3 Transmit Packet Byte Count
Port 4 Transmit Packet Byte Count
Port 5 Transmit Packet Byte Count
Port 0 Collision Count
Reserved
MODE
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
Default
0x00071010h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
4-6
ADM6996L
Register Description
Register
0x2ah
0x2bh
0x2ch
0x2dh
0x2eh
0x2fh
0x30h
0x31h
0x32h
0x33h
0x34h
0x35h
0x36h
0x37h
0x38h
0x39h
0x3ah
0x3bh
0x3ch
4.6
Bit 31- 0
Port 1 Collision Count
Reserved
Port 2 Collision Count
Reserved
Port 3 Collision Count
Port 4 Collision Count
Port 5 Collision Count
Port 0 Error Count
Reserved
Port 1 Error Count
Reserved
Port 2 Error Count
Reserved
Port 3 Error Count
Port 4 Error Count
Port 5 Error Count
Over Flow Flag 0
Over Flow Flag 1
Over Flow Flag 2
MODE
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
LH/COR
LH/COR
LH/COR
Default
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
0x00000000h
Serial Register Description
4.6.1 Chip Identifier Register, offset: 0x00h
Bits
Type Description
3:0
RO 0000 (Version number)
31:4
RO 0x0007101h
Initial value
0x0h
0x7101h
4.6.2
Bits
0
Initial value
0x0h
1
2
3
4
Port Status 0 Register, offset: 0x01h
Type Description
RO Port 0 Linkup Status:
1: Link is established.
0: Link is not established.
RO Port 0 Speed Status:
1: 100Mb/s
0: 10 Mb/s
RO Port 0 Duplex Status
1: Full Duplex.
0: Half Duplex.
RO Port 0 Flow Control Enable
1: 802.3X on for full duplex or back pressure on for half duplex.
0: Flow Control Disable
RO Reserved
Infineon-ADMtek Co. Ltd.
0x0h
0x0h
0x0h
0x0h
4-7
ADM6996L
Bits
5
6
7
8
Register Description
Type
RO
RO
RO
RO
9
RO
10
RO
11
RO
12
13
14
15
16
RO
RO
RO
RO
RO
17
RO
18
RO
19
RO
20
21
22
23
24
RO
RO
RO
RO
RO
25
RO
26
RO
27
RO
Description
Reserved
Reserved
Reserved
Port 1 Linkup Status:
1: Link is established.
0: Link is not established.
Port 1 Speed Status:
1: 100Mb/s
0: 10 Mb/s
Port 1 Duplex Status
1: Full Duplex.
0: Half Duplex.
Port 1 Flow Control Enable
1: 802.3X on for full duplex or back pressure on for half duplex.
0: Flow Control Disable
Reserved
Reserved
Reserved
Reserved
Port 2 Linkup Status:
1: Link is established.
0: Link is not established.
Port 2 Speed Status:
1: 100Mb/s
0: 10 Mb/s
Port 2 Duplex Status
1: Full Duplex.
0: Half Duplex.
Port 2 Flow Control Enable
1: 802.3X on for full duplex or back pressure on for half duplex.
0: Flow Control Disable
Reserved
Reserved
Reserved
Reserved
Port 3 Linkup Status:
1: Link is established.
0: Link is not established.
Port 3 Speed Status:
1: 100Mb/s
0: 10 Mb/s
Port 3 Duplex Status
1: Full Duplex.
0: Half Duplex.
Port 3 Flow Control Enable
Infineon-ADMtek Co. Ltd.
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
4-8
ADM6996L
Bits
28
29
30
31
4.6.3
Bits
0
Register Description
Type Description
1: 802.3X on for full duplex or back pressure on for half duplex.
0: Flow Control Disable
RO Port 4 Linkup Status:
1: Link is established.
0: Link is not established.
RO Port 4 Speed Status:
1: 100Mb/s
0: 10 Mb/s
RO Port 4 Duplex Status
1: Full Duplex.
0: Half Duplex.
RO Port 4 Flow Control Enable
1: 802.3X on for full duplex or back pressure on for half duplex.
0: Flow Control Disable
31:5
Port Status 1 Register, offset: 0x02h
Type Description
RO Port 5 Linkup Status:
1: Link is established.
0: Link is not established.
RO Port 5 Speed Status: Two bits indicate the operating speed.
Bit[2]
Bit[1]
Speed
0
1
100Mb/s
0
0
10Mb/s
RO Port 5 Duplex Status
1: Full Duplex.
0: Half Duplex.
RO Port 5 Flow Control Enable
1: 802.3X on for full duplex or back pressure on for half duplex.
0: Flow Control Disable
RO Reserved
4.6.4
Bits
1:0
2
4:3
5
Cable Broken Status Register, offset: 0x03h
Type Description
RO Port 0 Cable Broken Length
RO Port 0 Cable Broken
RO Reserved
RO Reserved
2:1
3
4
Infineon-ADMtek Co. Ltd.
Initial value
0x0h
0x0h
0x0h
0x0h
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
Initial value
0x0h
0x0h
0x0h
0x0h
4-9
ADM6996L
Register Description
Bits
Type Description
7:6
RO Port 1 Cable Broken Length
8
RO Port 1 Cable Broken
10:9
RO Reserved
11
RO Reserved
3:12
RO Port 2 Cable Broken Length
14
RO Port 2 Cable Broken
16:15 RO Reserved
17
RO Reserved
19:18 RO Port 3 Cable Broken Length
20
RO Port 3 Cable Broken
22:21 RO Port 4 Cable Broken Length
23
RO Port 4 Cable Broken
31:24 RO Reserved
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
4.6.5 Over Flow Flag 0 Register, offset: 0x3ah
Bits
Type Description
0
RO Overflow of Port 0 Receive Packet Count
1
RO Reserved
2
RO Overflow of Port 1 Receive Packet Count
3
RO Reserved
4
RO Overflow of Port 2 Receive Packet Count
5
RO Reserved
6
RO Overflow of Port 3 Receive Packet Count
7
RO Overflow of Port 4 Receive Packet Count
8
RO Overflow of Port 5 Receive Packet Count
9
RO Overflow of Port 0 Receive Packet Byte Count
10
RO Reserved
11
RO Overflow of Port 1 Receive Packet Byte Count
12
RO Reserved
13
RO Overflow of Port 2 Receive Packet Byte Count
14
RO Reserved
15
RO Overflow of Port 3 Receive Packet Byte Count
16
RO Overflow of Port 4 Receive Packet Byte Count
17
RO Overflow of Port 5 Receive Packet Byte Count
31:18 RO Reserved
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
4.6.6
Bits
0
1
2
Initial value
0x0h
0x0h
0x0h
Over Flow Flag 0: Register 0x3bh
Type Description
RO Overflow of Port 0 Transmit Packet Count
RO Reserved
RO Overflow of Port 1 Transmit Packet Count
Infineon-ADMtek Co. Ltd.
4-10
ADM6996L
Register Description
Bits
Type Description
3
RO Reserved
4
RO Overflow of Port 2 Transmit Packet Count
5
RO Reserved
6
RO Overflow of Port 3 Transmit Packet Count
7
RO Overflow of Port 4 Transmit Packet Count
8
RO Overflow of Port 5 Transmit Packet Count
9
RO Overflow of Port 0 Transmit Packet Byte Count
10
RO Reserved
11
RO Overflow of Port 1 Transmit Packet Byte Count
12
RO Reserved
13
RO Overflow of Port 2 Transmit Packet Byte Count
14
RO Reserved
15
RO Overflow of Port 3 Transmit Packet Byte Count
16
RO Overflow of Port 4 Transmit Packet Byte Count
17
RO Overflow of Port 5 Transmit Packet Byte Count
31:18 RO Reserved
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
4.6.7 Over Flow Flag 2 Register, offset: 0x3ch
Bits
Type Description
0
RO Overflow of Port 0 Collision Count
1
RO Reserved
2
RO Overflow of Port 1 Collision Count
3
RO Reserved
4
RO Overflow of Port 2 Collision Count
5
RO Reserved
6
RO Overflow of Port 3 Collision Count
7
RO Overflow of Port 4 Collision Count
8
RO Overflow of Port 5 Collision Count
9
RO Overflow of Port 0 Error Count
10
RO Reserved
11
RO Overflow of Port 1 Error Count
12
RO Reserved
13
RO Overflow of Port 2 Error Count
14
RO Reserved
15
RO Overflow of Port 3 Error Count
16
RO Overflow of Port 4 Error Count
17
RO Overflow of Port 5 Error Count
31:18 RO Reserved
Initial value
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
0x0h
Infineon-ADMtek Co. Ltd.
4-11
ADM6996L
4.7
Register Description
Serial Interface Timing
ADM6996L serial chip internal counter or EEPROM access timing.
EESK: Similar as MDC signal.
EDI: Similar as MDIO.
ECS: Must keep low.
EECK
z
EEDI
(STA)
z
EEDI
(AT8999)
1
Preamble
0
1
1
0
1
0
0
0
0
Opcode Table Device
(read) Select Address
Start
1
1
1
1
1
z
0
0
1
0
0
TA
Register Address
0
0
0
0
0
0
Register Data [31:0]
z
Idle
Preamble: At least 32 continuous “1”.
Start: 01(2 bits)
Opcode: 10 (2 bits, Only supports read command)
Table select: 1/Counter, 0/ EEPROM (1 bit)
Register Address: Read Target register address. ( 7 bits)
TA: Turn Around.
Register Data: 32 bit data.
Counter output bit sequence is bit 31 to bit 0.
If user read EEPROM then 32 bits data will separate as two EEPROM registers. The
sequence is:
Register +1, Register ( Register is even number).
Register, Register-1(Register is Odd number).
Example: Read Register 00h then ADM6996L will drive 0x01h & 0x00h.
Read Register 03h then ADM6996L will drive 0x03h & 0x02h.
Idle: EESK must send at least one clock at idle time.
ADM6996L issue Reset internal counter command
EESK: Similar as MDC signal.
EDI: Similar as MDIO.
ECS: Must keep low.
EECK
z
EEDI
(STA)
0
Preamble
Infineon-ADMtek Co. Ltd.
1
Start
0
1
Opcode
(reset)
1
0
0
0
0
0
0
0
0
1
Device Reset
Port Number or Counter Index
Address Type
Idle
4-1
ADM6996L
Register Description
Preamble: At least 32 continuous “1”.
Start: 01(2 bits)
Opcode: 01 (2 bits, Reset command)
Device Address: Chip physical address as PHYAS[1:0].
Reset_type: Reset counter by port number or by counter index.
1: Clear dedicate port’s all counters.
0: Clear dedicate counter.
Port_number or counter index: User define clear port or counter.
Idle: EECK must send at least one clock at idle time.
Infineon-ADMtek Co. Ltd.
4-2
ADM6996L
Electrical Specification
Chapter 5 Electrical Specification
5.1
TX/FX Interface
5.1.1
TP Interface
TXP
1:1
0.01U
49.9
TXN
C1
49.9 R2
VCCA2
ADM6995
RXP
1
2
3
4
5
6
7
8
R1
0.01U
49.9
49.9
RXN
RJ-45
1:1
0.1U
75
Auto-MDIX
X'FMR
75
75
Hi-Pot Cap
Transformer requirement:
. TX/RX rate 1:1
. TX/RX central tap connect together to VCCA2.
User can change TX/RX pin for easy layout but do not change polarity. ADM6996L
supports auto polarity on receiving side.
5.1.2
FX Interface
+3.3V
127
+3.3V
69
127
69
3.3V Fiber
Transceiver
TXP
TXN
SD
ADM6995
VCC(3.3)
VCC(3.3)
RXP
1 GND_RX
2 RD+
3 RD4 SD
5 VCC_RX
6 VCC_TX
7 TD8 TD+
9 GND_TX
RXN
+3.3V
83
83
182
182
127
SD
83
Infineon-ADMtek Co. Ltd.
5-1
ADM6996L
Electrical Specification
5.2
DC Characteristics
5.2.1
Absolute Maximum Rating
Symbol
VCC
Vcca2
Vccpll
Vccik
VIN
Vout
TSTG
PD
ESD
5.2.2
Rating
Units
V
V
V
V
V
V
°C
W
V
-0.3 to 3.63
1.8
1.8
1.8
-0.3 to VCC + 0.3
-0.3 to Vcc + 0.3
-55 to 155
1.3W
2KV
Recommended Operating Conditions
Symbol
Vcc
Vcca2
Vccpll
Vccik
Vin
PC
Tj
5.2.3
Parameter
Power Supply
TX line driver
PLL voltage
Digital core voltage
Input Voltage
Output Voltage
Storage Temperature
Power Dissipation
ESD Rating
Parameter
Power Supply
TX line driver
PLL voltage
Digital core voltage
Input Voltage
Power consumption
Junction Operating Temperature
Min
2.8
1.7
1.7
1.7
0
0
Typical
3.3
1.8
1.8
1.8
1.3
25
Max
3.465
1.9
1.9
1.9
Vcc
115
Units
V
V
V
V
V
W
°C
DC Electrical Characteristics for 3.3V Operation
Under Vcc=3.0V~3.6V, Tj= 0 °C ~ 115 °C )
Symbol
VIL
VIH
VOL
VOH
RI
Parameter
Conditions
Min
Typical
Max
Input Low Voltage
CMOS
0.3 * Vcc
Input High Voltage
CMOS
0.7 * Vcc
Output Low Voltage
CMOS
0.4
Output High Voltage
CMOS
0.7 * Vcc
Input
Pull_up/down VIL=0V or
100
Resistance
VIH = Vcc
Infineon-ADMtek Co. Ltd.
Units
V
V
V
V
KΩ
5-2
ADM6996L
Electrical Specification
5.3
AC Characteristics
5.3.1
Power On Reset
0ms
50ms
100ms
tRST
RST*
tCONF
All Configuration Pins
Symbol Parameter
TRST RST Low Period
TCONF Start of Idle Pulse Width
5.3.2
Conditions
Min
100
100
Typical
Max
Units
ms
ns
EEPROM Interface Timing
0us
10u s
20us
30us
EECS
tESKL
tESKH
tESK
EESK
tEWDD
EEDO
tERDS
tERDH
EEDI
Symbol
TESK
TESKL
TESKH
TERDS
Parameter
Conditions
EESK Period
EESK Low Period
EESK High Period
EEDI to EESK Rising Setup
Time
TERDH EEDI to EESK Rising Hold
Time
TEWDD EESK Falling to EEDO
Output Delay Time
Infineon-ADMtek Co. Ltd.
Min
2550
2550
10
Typical
5120
Max
2570
2570
10
Units
ns
ns
ns
ns
ns
20
ns
5-3
ADM6996L
Electrical Specification
5.3.3 10Base-TX MII Input Timing
0ns
1000ns
2000ns
tCK
tCKL
tCKH
MII_RXCLK
tRXS
MII_RXDV
tRXH
MII_RXD
MII_CRS
Symbol
Parameter
Conditions
Max
Units
180
220
ns
ns
MII_RXCLK High Period
180
220
ns
MII_CRS, MII_RXDV and
MII_RXD to MII_RXCLK rising
setup
MII_CRS, MII_RXDV and
MII_RXD to MII_RXCLK rising
hold
10
ns
10
ns
tCK
tCKL
MII_RXCLK Period
MII_RXCLK Low Period
tCKH
tRXS
tRXH
5.3.4
Min
Typical
400
10Base-TX MII Output Timing
0ns
500ns
1000ns
1500ns
2000ns
2500ns
tCK
tCKL
tCKH
MII_TXCLK
tTXOD
MII_TXEN
MII_TXD
Symbol
Parameter
Conditions
Min
Typical
Max
Units
tCK
tCKL
MII_TXCLK Period
MII_TXCLK Low Period
180
220
ns
ns
tCKH
MII_TXCLK High Period
180
220
ns
tTXOD
MII_TXD, MII_TXEN to
MII_TXCLK Rising Output Delay
0
25
ns
Infineon-ADMtek Co. Ltd.
400
5-4
ADM6996L
5.3.5
Electrical Specification
100Base-TX MII Input Timing
0ns
100ns
200ns
tCK
tCKL
tCKH
MII_RXCLK
tRXS
MII_RXDV
tRXH
MII_RXD
MII_CRS
Symbol
Parameter
Conditions
Min
Typical
Max
Units
tCK
tCKL
MII_RXCLK Period
MII_RXCLK Low Period
18
22
ns
ns
tCKH
MII_RXCLK High Period
18
22
ns
tRXS
MII_CRS, MII_RXDV and
MII_RXD to MII_RXCLK rising
setup
MII_CRS, MII_RXDV and
MII_RXD to MII_RXCLK rising
hold
10
ns
10
ns
tRXH
40
5.3.6 100Base-TX MII Output Timing
0ns
50ns
100ns
150ns
200ns
250ns
tCK
tCKL
tCKH
MII_TXCLK
tTXOD
MII_TXEN
MII_TXD
Symbol
tCK
tCKL
Parameter
MII_TXCLK Period
MII_TXCLK Low Period
Infineon-ADMtek Co. Ltd.
Conditions
Min
Typical
Max
Units
22
ns
ns
40
18
5-5
ADM6996L
Electrical Specification
Symbol
Max
Units
tCKH
MII_TXCLK High Period
18
22
ns
tTXOD
MII_TXD, MII_TXEN to
MII_TXCLK Rising Output Delay
0
25
ns
Max
5.3.7
Parameter
Conditions
Min
Typical
GPSI(7-wire) Input Timing
500ns
250ns
0ns
tCK
tCKL
tCKH
GPSI_RXCLK
tTXH
tTXS
GPSI_RXD
GPSI_CRS/COL
Symbol
TCK
TCKL
Parameter
Conditions
GPSI_RXCLK Period
GPSI_RXCLK Low Period
Min
Typical
100
40
60
Units
ns
ns
60
ns
TCKH
GPSI_RXCLK High Period
40
TTXS
GPSI_RXD,
GPSI_CRS/COL to
GPSI_RXCLK Rising Setup
Time
GPSI_RXD,
GPSI_CRS/COL to
GPSI_RXCLK Rising Hold
Time
10
ns
10
ns
TTXH
5.3.8
GPSI(7-wire) Output Timing
0ns
250ns
500ns
tCK
tCKL
tCKH
GPSI_TXCLK
GPSI_TXD
tOD
GPSI_TXEN
Infineon-ADMtek Co. Ltd.
5-6
ADM6996L
Electrical Specification
Symbol
TCK
TCKL
Parameter
GPSI_TXCLK Period
GPSI_TXCLK Low Period
TCKH
TOD
40
60
Units
ns
ns
GPSI_TXCLK High Period
40
60
ns
GPSI_TXCLK Rising to
GPSI_TXEN/GPSI_TXD
Output Delay
50
70
ns
Infineon-ADMtek Co. Ltd.
Conditions
Min
Typical
100
Max
5-7
ADM6996L
Appendix
Chapter 6 Packaging
6.1
128 Pin PQFP Outside Dimension
17.2 +/- 0.2 mm
14.0 +/- 0.1 mm
18.5 mm
23.2 +/- 0.2 mm
20.0 +/- 0.1 mm
12.5 mm
3.4 mm
MAX
0.5 mm
Infineon-ADMtek Co. Ltd.
6-1