INTEL 82562V

Intel® 82562V 10/100 Mbps Platform
LAN Connect
Datasheet
Product Features
n
n
n
n
n
n
n
n
n
IEEE 802.3 10BASE-T/100BASE-TX
compliant physical layer interface
IEEE 802.3u Auto-Negotiation support
Digital Adaptive Equalization control
Link status interrupt capability
XOR tree mode support
3-port LED support (speed, link and
activity)
10BASE-T auto-polarity correction
LAN Connect Interface
PHY detects polarity, MDI-X, and cable
lengths. Auto MDI, MDIX crossover at all
speeds
n
n
n
n
n
n
n
Diagnostic loopback mode
1:1 transmit transformer ratio support
Low power (less than 300 mW in active
transmit mode)
Reduced power in “unplugged mode” (less
than 50 mW)
Automatic detection of “unplugged mode”
3.3 V device
81-pin Mold Cap package--10mm x 10mm
x 1.745mm; 0.635mm Ball, 1.0mm Pitch
Additional Features
n
n
n
The 82562V PLC supports strapping options that enable the following operating modes:
— LED support for three logic configurations.
— LAN disable function using one pin.
— Increased transmit strength.
The receive BER performance increases the margin for cable length.
Return Loss performance is improved.
Revision 1.00
January 2006
317757-001
Revision History
Revision
Revision Date
Description
0.25
July 2005
0.50
October 2005
Added correct package information and added more pin names and numbers
1.00
January 2006
Updated the power values and the signal names list
Initial release.
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rights is granted by this document. Except as provided in Intel's Terms and Conditions of Sale for such products, Intel assumes no liability whatsoever, and Intel
disclaims any express or implied warranty, relating to sale and/or use of Intel® products including liability or warranties relating to fitness for a particular purpose,
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sustaining applications.
Intel 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." Intel reserves these for future definition
and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them.
The 82562V PLC may contain design defects or errors known as errata which may cause the product to deviate from published specifications. Current characterized
errata are available on request.
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by calling 1-800-548-4725 or by
visiting Intel's website at http://www.intel.com.
Intel® is a trademark or registered trademark of Intel Corporation or its subsidiaries in the United States and other countries.
Copyright © 2005-2006, Intel Corporation
* Other brands and names are the property of their respective owners.
Datasheet
Networking Silicon — 82562V
1.0
Introduction
This document is applicable to the Intel® 82562V 10/100 Mbps Platform LAN Connect device.
1.1
Overview
The Intel® 82562V 10/100 Mbps Platform LAN Connect is a highly-integrated device designed for
10 or 100 Mbps Ethernet systems. It is based on the IEEE 10BASE-T and 100BASE-TX standards.
The IEEE 802.3u standard for 100BASE-TX defines networking over two pairs of Category 5
unshielded twisted pair cable or Type 1 shielded twisted pair cable.
The 82562V complies with the IEEE 802.3u Auto-Negotiation standard and the IEEE 802.3x Full
Duplex Flow Control standard. The 82562V also includes a PHY interface compliant to the current
platform LAN connect interface.
1.2
References
• IEEE 802.3 Standard for Local and Metropolitan Area Networks, Institute of Electrical and
Electronics Engineers.
• 82562ET(EM) and 82562V(G) LAN on Motherboard Design Guide. Intel Corporation.
• Intel® I/O Controller Hub 6 (ICH6) Family External Design Specification (EDS), Volume 1,
Revision 1.5V1. Intel Corporation.
• Intel® I/O Controller Hub 6 (ICH6) Family External Design Specification (EDS), Volume 2,
Revision 1.5V2. Intel Corporation.
• LAN Connect Interface Specification. Intel Corporation.
• I/O Control Hub 2, 3, and 4 EEPROM Map and Programming Information. Intel Corporation.
• I/O Control Hub 5, 6, and 7 EEPROM Map and Programming Information. Intel Corporation.
Programming information can be obtained through your local Intel representatives.
1.3
Product Codes
The product ordering code for the 82562V is: EP82562V.
The product ordering code for the 82562V lead-free version is: LU82562V.
Datasheet
1
82562V — Networking Silicon
2.0
82562V Architectural Overview
The 82562V PLC is a 3.3 V device in a 81-pin Mold Cap package. In normal operating mode, the
82562V incorporates all active circuitry required to interface with the Intel® ICHx device with an
integrated 10/100 Mbps LAN controller. The 82562V supports a direct interface to all Media
Access Control (MAC) components that meet the Platform LAN connect interface specification.
Figure 1 shows a block diagram of the 82562V architecture.
Digital
Equalizer
Adaptation
LILED#
Port LED
Drivers
ACTLED#
SPDLED#
Equalizer &
BLW correction
MDI/MDI-X
RDN/RDP
TDN/TDP
Digital Clock
Recovery (100)
100Base-TX
PCS
JRSTSYNC
CRS/Link 10
Detection
Digital Clock
Recovery (10)
10Base-T
PCS
3
LAN
Connect
Interface
Transmit DAC
10/100
3
JTXD[2:0]
JRXD[2:0]
JCLK
AutoNegotiation
Bias & BandGap Voltage
Circuit
Clock
Generator
X1
Crystal
25 MHz
Control
Registers
X2
Figure 1. 82562V PLC Block Diagram
2.1
LAN Connect Interface
The 82562V supports a LAN Connect Interface (LCI) as specified in the LCI Specification. The
LAN Connect is the I/O Control Hub 2 (ICH2) interface to the 82562V. The LCI uses an 8-pin
interface, which reduces the pin count from 15, for an Media Independent Interface (MII) PHY. In
addition, its signaling protocol provides greater functionality, such as dynamic power reduction,
from a PLC in comparison to a standard MII PHY.
Figure 2 shows how the 82562V can be used in a 10/100 Mbps ICHx design.
I/O
ControlHub
Hub4
I/O Control
LAN
Controller
(ICH4)
LAN
Controller
Transmit Differential Pair
(TDP/TDN)
82562EZ
(PlatformPLC
LAN
82562V
Connect
Device)
Receive Differential Pair
(RDP/RDN)
Magnetics
System Bus Interface
2
Datasheet
Networking Silicon — 82562V
Figure 2. 82562V PLC 10/100 Mbps Ethernet Solution
2.1.1
Reset/Synchronize Operations
The Reset/Synchronize signal used by the LAN Connect Interface is driven by the ICHx integrated
LAN device. It has two functions:
• Synchronize. When this pin is activated synchronously for only one LAN connect clock, it is
used for synchronization between the ICHx integrated LAN and PHY on LAN connect word
boundaries.
• Reset. When this pin is asserted beyond one LAN connect clock, the 82562V uses this signal
as a reset signal. To ensure a reset of the 82562V, the reset should remain active for at least 500
µs.
2.1.2
Reset Considerations
When the 82562V Reset signal (JRSTSYNC) is asserted for at least 500 µs, all internal circuits are
reset. The 82562V can also be reset by setting the MII register Reset bit equal to 1 (Register 0, bit
15).
The 82562V filters out JRSTSYNC pulses with a width of less than 200 ns to distinguish between
a reset and synchronize pulse. Again, the Reset signal should be longer than 500 µs to reset the
82562V.
Datasheet
3
82562V — Networking Silicon
2.1.3
LAN Connect Clock Operations
The 82562V drives the Platform LAN Connect clock (JCLK) at one of two possible frequencies
depending upon its operation speed. When the 82562V is in 100BASE-TX mode it drives JCLK at
50 MHz. When the 82562V is in 10BASE-T mode it drives JCLK at 5 MHz. The LAN Connect
clock does not stop during normal operation under any conditions. In reduced power mode, the
82562V drives JCLK at 5 MHz, which is required for proper filtering of incoming packets for
applications such as Wake on LAN (WoL).
2.2
Hardware Configuration
Four pins, Test Enable (TESTEN), Test Clock (ISOL_TCK), Test Input (ISOL_TI), and Test
Execute (ISOL_EXEC), define the general operation of the 82562V. Table 1 lists the pin settings
for the different modes of operation.
Table 1.
82562V Hardware Configuration
TESTEN
ISOL
_TCK
ISOL
_TI
ISOL_
EXEC
Mode
82562G family Mode 0:
• LEDs are 82562E-compatible
(“A” configuration)
0
0
0
0
• LAN_DISABLE# pin is used as
ADV10 (auto-negotiation
advertise 10M only)
Alternative Mode: drop-in
replacement for existing 82562Ebased designs
Comments
The ISOL_TCK, ISOL_TCI, and
ISOL_EXEC, and ADV10/
LAN_DISABLE# pins have internal
10 K Ω pull-down resistors and should
not be connected for Mode 0 (refer to
Table 2).
For the alternative 82562E drop-in
replacement mode, pins may
optionally be used as a LAN disable.
82562G family Mode 1:
• LEDs are in configuration B
0
0
1
1
0
1
1
1
Isolate
1
0
1
0
Testing Mode
1
0
0
0
XOR Tree
Board testing plus tri-state.
82562G family Mode 2:
1
0
0
1
The ISOL_TCK and ISOL_TI pins
have 10 K Ω internal pull-down
resistors and should not be connected
for Mode 2 (refer to Table 2).
1
0
1
1
• LAN_DISABLE# pin is single
pin LAN disable (tri-state and full
power down function)
Same as 0011 except that LEDs are in
configuration C
82562G family Mode 3:
Same as 0011 except enhance Tx rise
and fall times.
82562G family Mode 4:
1
4
The ISOL_TCK pin has an internal 10
K Ω pull-down resistor and should not
be connected for Mode 1 (refer to
Table 2).
1
0
0
Same as 1001 except Enhance Tx rise
and fall times.
Tri-state and power down.
The ISOL_TCK pin has an internal 10
K Ω pull-down resistor and should not
be connected for Mode 3.
The ISOL_TI and ISOL_EXEC pins
have internal 10 K Ω pull-down
resistors and should not be connected
for Mode 4.
Datasheet
Networking Silicon — 82562V
Table 1.
82562V Hardware Configuration
TESTEN
ISOL
_TCK
ISOL
_TI
ISOL_
EXEC
1
1
0
1
Reserved
The ISOL_TI pin has an internal
10 K Ω pull-down resistor and should
not be connected.
1
1
1
0
Reserved Testing
The ISOL_EXEC pin has an internal
10 K Ω pull-down resistor and should
not be connected.
1
1
1
1
Power-down Mode
Tri-state and power down.
Mode
Comments
NOTE: Combinations not shown in Table 1 are reserved and should not be used.
Table 2.
LED Logic Functionality
Mode/Configuration
Datasheet
ACTLED
#
SPDLED#
LILED#
Configuration A: 82562ETcompatible
Activity
Speed 100 Mb
Asserted if valid link is present at
10 Mb or 100 Mb
Configuration B: Intel GbE
mode
Activity
Link and Speed 100 Mb
Asserted if valid link is present at
10 Mb or 100 Mb
Configuration C: Alternative
mode
Activity
Link and Speed 100 Mb
Link and Speed 10 Mb
5
82562V — Networking Silicon
3.0
Performance Enhancements
3.1
Usage Modes: 1, 2, 3, and 4
82562V supports several new features that offer design flexibility and reduced BOM cost
compared to the 82562ET PLC device. To implement these new features, a board design must
include the proper pull-up and/or pull-down strapping resistor options. Refer to the 82562V/
82562GZ/82562GX/82562G LAN on Motherboard Design Guide for more information. Table 3
lists the four new modes.
Table 3.
Usage Modes 1, 2, 3, and 4
Mode
Mode 0: 82562ET compatible.
No BOM changes necessary for equivalent performance to 82562ET.
Mode 1: LED configuration B and single-pin
LAN disable.
Usability and reduced BOM cost.
Mode 2: Same as mode 1, except LED
configuration C.
Usability and reduced BOM cost.
Mode 3: LED configuration B, Single Pin
LAN Disable, and enhanced Tx modea
Usability, reduced BOM cost, and stronger Tx drive strength. Refer to
Section 3.1.2.
Mode 4: Same as mode 3, except LED
configuration C.
See table note a.
a.
3.1.1
Benefit
Usability, reduced BOM cost, and stronger Tx drive strength. Refer to
Section 3.1.2.
Only use this mode if advised to do so by an Intel representative to compensate for board design issues affecting IEEE compliance.
Pin Usage for Modes 1, 2, 3, and 4
To use modes 1, 2, 3, or 4, the following pins need to be reviewed (refer to Table 1):
•
•
•
•
•
•
6
ISOL_TCK
ISOL_TI
ISOL_EX
TESTEN
ADV10/LAN_DISABLE# and supporting circuits
ACTLED#, SPDLED#, and LILED# and supporting circuits
Datasheet
Networking Silicon — 82562V
3.1.2
Enhanced Tx Mode
The enhanced Tx mode speeds up the rise and fall times of the 100 Mb signal. This was done so the
82562V can have improved IEEE PHY conformance requirements over a more capacitive Analog
Front End (AFE); usually caused by long traces or differential switches that customers use, usually
on mobile platforms. However, running an 82562V device in enhanced mode increases the radiated
emissions seen from the LAN solution. The increase in radiated emissions may or may not impact
the DUT’s ability to pass regulatory requirements, as it will depend largely on the design of the
AFE. The enhanced mode should only be used when 100Base-TX rise/fall times cannot be met in
the normal 82562V mode. Consult an Intel representative if you are considering using this mode.
3.2
Management Data Interface MDI/MDI-X
MDI/MDI-X provides the ability to automatically detect the required cable connection type and
configure the controller-side MAU to the cable type. MDI/MDI-X effectively allows all properly
wired Ethernet cables usable with any Ethernet device to be connected to the 82562V without any
additional external logic.
MDI/MDI-X enables auto-correction of incorrect cabling with respect to cross-over versus
straight-through cables. The 82562V can identify the cable connection type and adjust its MDI port
to the cable by switching between the TD and RD pairs. The auto-switching is done prior to the
start of the hardware auto negotiation algorithm.
In a standard straight-through RJ-45 port configuration, the transmit pair is on contacts 1 and 2, and
the receive pair on contacts 3 and 6. These are defined by Clause 23.7.1 of the IEEE 802.3u
standard.
Table 4 lists the connections for both straight-through and cross-over RJ-45 ports for comparison.
Table 4.
RJ-45 Connections
RJ-45
Contact
Cross-Over MDIX
Signalb
1
TD+
RD+
2
TD-
RD-
3
RD+
TD+
4
Not Used
Not Used
5
Not Used
Not Used
6
RD-
TD-
7
Not Used
Not Used
8
Not Used
Not Used
a.
b.
Datasheet
Straight-Through MDI
Signala
Straight-through connections used on Data Terminal Equipment (DTE)
applications.
Cross-over connections used on Hub and Switch applications.
7
82562V — Networking Silicon
Note:
8
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Datasheet
Networking Silicon — 82562V
4.0
82562V Signal Descriptions
4.1
Signal Type Definitions
Type
4.2
Name
I
Input
O
Output
Output pin from the 82562V.
I/O
Input/Output
Multiplexed input and output pin to and from the 82562V.
MLT
Multi-level
analog I/O
Multi-level analog pin used for input and output.
B
Bias
Bias pin used for ground connection through a resistor or an external voltage reference.
DPS
Digital Power
Supply
Digital power or ground pin for the 82562V.
APS
Analog Power
Supply
Analog power or ground pin for the 82562V.
Pin
Number
TDP
B8
TDN
B9
RDP
D9
RDN
D8
Type
Description
MLT
Transmit Differential Pair. The transmit differential pair sends serial bit
streams to the unshielded twisted pair (UTP) cable. The differential pair is a twolevel signal in 10BASE-T (Manchester) mode and a three-level signal in
100BASE-TX mode (MLT-3). These signals directly interface with the isolation
transformer.
MLT
Receive Differential Pair. The receive differential pair receive the serial bit
stream from an unshielded twisted pair (UTP) cable. The differential pair is a
two-level signal in 10BASE-T mode (Manchester) or a three-level signal in
100BASE-TX mode (MLT-3). These signals directly interface with an isolation
transformer.
External Bias Pins
Pin Name
Pin
Number
Type
Description
RBIAS10
H7
B
Reference Bias Resistor (100 Mbps). This pin should be connected to a
pull-down resistor.a
RBIAS100
G7
B
Reference Bias Resistor (10 Mbps). This pin should be connected to a pulldown resistor.a
a.
Datasheet
Input pin to the 82562V.
Twisted Pair Ethernet (TPE) Pins
Pin Name
4.3
Description
Based on some board designs, RBIAS100 and RBIAS10 values may need to be increased/decreased to compensate for high/low MDI
transmit amplitude. See the 82562G/GT and 82562ET/EM LAN on Motherboard Design Guide for more information.
9
82562V — Networking Silicon
4.4
Clock Pins
Pin Name
4.5
Pin
Number
Type
Description
X1
H6
I
Crystal Input Clock. X1 and X2 can be driven by an external 25 MHz crystal of
30 PPM. Otherwise, X1 is driven by an external metal-oxide semiconductor
(MOS) level 25 MHz oscillator when X2 is left floating.
X2
H5
O
Crystal Output Clock. X1 and X2 can be driven by an external 25 MHz crystal
of 30 PPM.
Platform LAN Connect Interface Pins
Pin Name
4.6
Pin
Number
Type
Description
JCLK
E2
O
LAN Connect Clock. The LAN Connect Clock is driven by the 82562V on two
frequencies depending on operation speed. When the 82562V is in 100BASE-TX
mode, JCLK drives a 50 MHz clock. Otherwise, JCLK drives a 5 MHz clock for
10BASE-T. The JCLK does not stop during normal operation.
JRSTSYNC
E3
I
Reset/Synchronize. This is a multiplexed pin and is driven by the Media Access
Control (MAC) layer device. Its functions are:
•
Reset. When this pin is asserted beyond one LAN Connect clock period, the
82562V uses this signal Reset. To ensure reset of the 82562V, the Reset
signal should remain active for at least 500 µs.
•
Synchronize. When this pin is activated synchronously, for only one LAN
Connect clock period, it is used to synchronize the MAC and PHY on LAN
Connect word boundaries.
JTXD[2:0]
D1, F1,
H9
I
LAN Connect Transmit Data. The LAN Connect transmit pins are used to
transfer data from the MAC device to the 82562V. These pins are used to move
transmitted data and real time control and management data. They also transmit
out of band control data from the MAC to the PHY. The pins should be fully
synchronous to JCLK.
JRXD[2:0]
C1, D2,
D3
O
LAN Connect Receive Data. The LAN Connect receive pins are used to
transfer data from the 82562V to the MAC device. These pins are used to move
received data and real time control and management data. They also move out of
band control data from the PHY to the MAC. These pins are synchronous to
JCLK.
LED Pins
Pin Name
Pin Number
Type
Description
LILED#
A4
O
Link Integrity LED. The LILED# signal has three logic modes. The LED configurations are
listed in Table 2, “LED Logic Functionality”.
ACTLED#
B4
O
Activity LED. The LED is active low and the Activity LED signal indicates either receive or
transmit activity. When no activity is present, the LED is off. The Activity LED will flicker
when activity is present. The flicker rate depends on the activity load.
If Address Matching mode is enabled by the MAC, this pin will also indicate address match
events on previously received frames.
SPDLED#
10
A5
O
Speed LED. The SPDLED# signal has three logic modes. The LED configurations are listed
in Table 2, “LED Logic Functionality”.
Datasheet
Networking Silicon — 82562V
4.7
Miscellaneous Control Pins
Pin Name
ADV10/
LAN_DISABLE#
Pin Number
Type
A6
I
Description
Advertise 10 Mbps Only. The Advertise 10 Mbps Only signal is asserted high, and the
82562V advertises only 10BASE-T technology during Auto-Negotiation processes in this
state. Otherwise, the 82562V advertises all of its technologies.
Note: ADV10 has an internal 10 K Ω pull-down resistor.
LAN Disable in 82562G Mode. In the 82562G operating mode, this pin is used as a
LAN disable signal. When it is driven low, the device is fully powered down.
ISOL_TCK
G1
I
Test Clock. The Test Clock signal sets the device into asynchronous test mode in
conjunction with the Test Input, Test Execute and Test Enable pins (refer to Table 1,
“82562V Hardware Configuration”).
In the manufacturing test mode, it acts as the test clock.
Note: ISOL_TCK has an internal 10 K Ω pull-down resistor.
ISOL_TI
H1
I
Test Input. The Test Input signal sets the device into asynchronous test mode in
conjunction with the Test Clock, Test Execute and Test Enable pins (refer to Table 1,
“82562V Hardware Configuration”).
In the manufacturing test mode, it acts as the test data input pin.
Note: ISOL_TI has an internal 10 K Ω pull-down resistor.
ISOL_EXEC
G2
I
Test Execute. The Test Execute signal sets the device into asynchronous test mode in
conjunction with the Test Clock, Test Input, and Test Enable pins (refer to Table 1,
“82562V Hardware Configuration”).
In the manufacturing test mode, it places the command that was entered through the TI
pin in the instruction register.
Note: ISOL_EXEC has an internal 10 K Ω pull-down resistor.
TOUT
G3
O
Test Output. The Test Output pin is used for Boundary XOR scan output. In the
manufacturing test mode, it acts as the test output port.
TESTEN
B6
I
Test Enable. The Test Enable pin is used to enable test mode and should be externally
pulled up to VCC using a 200 Ω resistor to allow XOR Tree test mode.
4.8
Power and Ground Connections
Pin Name
VCC
Pin
Number
Type
Description
B3, D4,
E4, E5,
E8, F2,
F6, F7,
G4, H3
DPS
Digital 3.3 V Power. These pins should be connected to the main digital power
supply.
A8, C4,
C7,C8,
C9, D6,
E1, E9,
F4, G6,
G8, G9,
J3, J5
DPS
Digital Ground. These pins should be connected to the main digital ground.
VCCR
D7
APS
Analog Power.
VSSR
C6
APS
Analog Ground. These pins should not be isolated from the main digital.
VCCP
VCCA
VCCA2
VCCT
VSS
VSSP
VSSA
VSSA2
Datasheet
11
82562V — Networking Silicon
5.0
Physical Layer Interface Functionality
The 82562V supports a direct glueless interface to all components that comply with the LAN
Connect specification.
5.1
100BASE-TX Mode
5.1.1
100BASE-TX Transmit Blocks
The transmit subsection of the 82562V accepts 3 bit wide data from the LAN Connect unit.
Another subsection passes data unconditionally to the 4B/5B encoder.
The 4B/5B encoder accepts nibble-wide data (4 bits) from the CSMA unit and compiles it into 5bit-wide parallel symbols. These symbols are scrambled and serialized into a 125 Mbps bit stream,
converted by the analog transmit driver into a MLT-3 waveform format, and transmitted onto the
Unshielded Twisted Pair (UTP) or Shielded Twisted Pair (STP) wire.
5.1.1.1
100BASE-TX 4B/5B Encoder
The 4B/5B encoder complies with the IEEE 802.3u 100BASE-TX standard. Four bits are encoded
according to the transmit 4B/5B lookup table. The lookup table matches a 5-bit code to each 4-bit
code. Table 5 lists the 4B/5B encoding scheme associated with the given symbol.
Table 5.
4B/5B Encoder
Symbol
12
5B Symbol Code
4B Nibble Code
0
11110
0000
1
01001
0001
2
10100
0010
3
10101
0011
4
01010
0100
5
01011
0101
6
01110
0110
7
01111
0111
8
10010
1000
9
10011
1001
A
10110
1010
B
10111
1011
C
11010
1100
D
11011
1101
E
11100
1110
F
11101
1111
I
11111
Inter Packet Idle Symbol (No
4B)
Datasheet
Networking Silicon — 82562V
5.1.1.2
Symbol
5B Symbol Code
4B Nibble Code
J
11000
1st Start of Packet Symbol
0101
K
10001
2nd Start of Packet Symbol
0101
T
01101
1st End of Packet Symbol
R
00111
2nd End of Packet Symbol and
Flow Control
V
00000
INVALID
V
00001
INVALID
V
00010
INVALID
V
00011
INVALID
H
00100
INVALID
V
00101
INVALID
V
00110
INVALID
V
01000
INVALID
V
01100
INVALID
V
10000
Flow Control S
V
11001
INVALID
100BASE-TX Scrambler and MLT-3 Encoder
Data is scrambled in 100BASE-TX in order to reduce electromagnetic emissions during long
transmissions of high-frequency data codes. The scrambler logic accepts 5 bits from the 4B/5B
encoder block and presents the scrambled data to the MLT-3 encoder. The 82562V implements the
11-bit stream cipher scrambler as adopted by the ANSI XT3T9.5 committee for UTP operation.
The cipher equation used is:
X[n] = X[n-11] + X[n-9] (mod 2)
The MLT-3 encoder receives the scrambled Non-Return to Zero (NRZ) data stream from the
scrambler and encodes the stream into MLT-3 for presentation to the driver. MLT-3 is similar to
NRZ1 coding, but three levels are output instead of two. The three output levels are positive,
negative and zero. When an NRZ “0” arrives at the input of the encoder, the last output level is
maintained (either positive, negative or zero). When an NRZ “1” arrives at the input of the encoder,
the output steps to the next level. The order of steps is negative-zero-positive-zero which continues
periodically. Refer to IEEE 802.3 Specification for details.
5.1.1.3
100BASE-TX Transmit Framing
The 82562V does not differentiate between the fields of the MAC frame containing preamble, start
of frame delimiter, data and Cyclic Redundancy Check (CRC). The 82562V encodes the first byte
of the preamble as the “JK” symbol, encodes all other pieces of data according to the 4B/5B lookup
table, and adds the “TR” code after the end of the packet. The 82562V scrambles and serializes the
data into a 125 Mbps stream, encodes it as MLT-3, and drives it onto the wire.
Datasheet
13
82562V — Networking Silicon
5.1.1.4
Transmit Driver
The transmit differential lines are implemented with a digital slope controlled current driver that
meets Twisted Pair Physical Media Device (TP-PMD) specifications. Current is sunk from the
isolation transformer by the transmit differential pins. The conceptual transmit differential
waveform for 100 Mbps is illustrated in Figure 3.
Figure 3. Conceptual Transmit Differential Waveform
The magnetics module external to the 82562V converts ITDP and ITDN to 2.0 VPP, as required by
the TP-PMD specification. The same magnetics used for 100BASE-TX mode can also work in
10BASE-T mode.
5.1.2
100BASE-TX Receive Blocks
The receive subsection of the 82562V accepts 100BASE-TX MLT-3 data on the receive differential
pair. Due to the advanced digital signal processing design techniques employed, the 82562V
accurately receives valid data from Category 5 (CAT5) UTP and Type 1 STP cables of length well
in excess of 100 meters.
5.1.2.1
Adaptive Equalizer
The distorted MLT-3 signal at the end of the wire is restored by the equalizer. The equalizer
performs adaptation based on the shape of the received signal, equalizing the signal to meet
superior data dependent jitter performance.
5.1.2.2
Receive Clock and Data Recovery
The clock recovery circuit uses advanced digital signal processing technology to compensate for
various signal jitter causes. The circuit recovers the 125 MHz clock and data and presents the data
to the MLT-3 decoder.
5.1.2.3
MLT-3 Decoder, Descrambler, and Receive Digital Section
The 82562V first decodes the MLT-3 data, and then the descrambler reproduces the 5B symbols
originated in the transmitter. The descrambling is based on synchronization to the transmission of
the 11-bit Linear Feedback Shift Register (LFSR) during an idle phase. The data is decoded at the
4B/5B decoder. After the 4B symbols are obtained, the 82562V outputs the receive data to the
CSMA unit.
14
Datasheet
Networking Silicon — 82562V
In 100BASE-TX mode, the 82562V can detect errors in receive data in a number of ways. Any of
the following conditions is considered an error:
•
•
•
•
Link integrity fails in the middle of frame reception.
The start of stream delimiter “JK” symbol is not fully detected after idle.
An invalid symbol is detected at the 4B/5B decoder.
Idle is detected in the middle of a frame (before “TR” is detected).
5.2
10BASE-T Mode
5.2.1
10BASE-T Transmit Blocks
5.2.1.1
10BASE-T Manchester Encoder
After the 2.5 MHz clocked data is serialized in a 10 Mbps serial stream, the 20 MHz clock
performs the Manchester encoding. The Manchester code always has a mid-bit transition. The
boundary transition occurs only when the data is the same from bit to bit. For example, if the value
is 11b, then the change is from low to high within the boundary.
5.2.1.2
10BASE-T Driver and Filter
Since 10BASE-T and 100BASE-TX have different filtration needs, both filters are implemented
inside the chip. The 82562V supports both technologies through one pair of transmit differential
pins and by externally sharing the same magnetics.
In 10 Mbps mode the line drivers use a pre-distortion algorithm to improve jitter tolerance. The line
drivers reduce their drive level during the second half of “wide” (100 ns) Manchester pulses and
maintain a full drive level during all narrow (50 ns) pulses and the first half of the wide pulses. This
reduces line overcharging during wide pulses, a major source of jitter.
5.2.2
10BASE-T Receive Blocks
5.2.2.1
10BASE-T Manchester Decoder
The 82562V performs Manchester decoding and timing recovery in 10BASE-T mode. The
Manchester encoded data stream is decoded from the receive differential pair. This data is
transferred to the controller at 2.5 MHz/nibble. The high-performance circuitry of the 82562V
exceeds the IEEE 802.3 jitter requirements.
5.2.2.2
10BASE-T Twisted Pair Ethernet (TPE) Receive Buffer and Filter
In 10 Mbps mode, data is expected to be received on the receive differential pair after passing
through isolation transformers. The filter is implemented inside the 82562V for supporting single
magnetics that are shared with the 100BASE-TX side. The input differential voltage range for the
Twisted Pair Ethernet (TPE) receiver is greater than 585 mV and less than 3.1 V. The TPE receive
buffer distinguishes valid receive data, link test pulses, and the idle condition, according to the
requirements of the 10BASE-T standard.
The following line activity is determined to be inactive and is rejected as invalid data:
Datasheet
15
82562V — Networking Silicon
• Differential pulses of peak magnitude less than 300 mV.
• Continuous sinusoids with a differential amplitude less than 6.2 VPP and frequency less than 2
MHz.
• Sine waves of a single cycle duration starting with 0° or 180° phase that have a differential
amplitude less than 6.2 VPP and a frequency of at least 2 MHz and not more than 16 MHz.
These single-cycle sine waves are discarded only if they are preceded by 4 bit times (400 ns)
of silence.
All other activity is determined to be either data, link test pulses, Auto-Negotiation fast link pulses,
or the idle condition.
5.3
Analog References
The 82562V has two inputs, RBIAS100 and RBIAS10, that require external resistor connections to
set biases for its internal analog section. The input pins are sensitive to the resistor value and
experimentation is required to determine the correct values for any given layout. Note that the
values listed in Figure 4 are starting values. Also, resistors of 1% tolerance should be used.
Figure 4. Analog References
82562
549Ω1%
619
1%
619 1%
649 Ω 1%
5.4
RBIAS10
RBIAS100
Dynamic Reduced Power & Auto Plugging Detection
The 82562V can be configured to support a dynamic reduced power mode. This mode reduces
power consumption of the 82562V when LAN activity is not present. The reduced power mode
decreases power consumption from 300 mW to about 50 mW and is based on automatic detection
of cable plugging. If the 82562V is configured to support dynamic power reduction, it enters the
reduced power mode whenever a cable is not connected to the device. In reduced power mode, the
82562V shuts off the link circuits, except the circuit used for the automatic plugging detection. On
the LAN Connect side, the entire interface remains active, including full access to all Media
Independent Interface (MII) registers. In this mode, the 82562V switches to the 10 Mbps speed
interface (5 MHz for LAN Connect). Thus, the reduced power mode is fully transparent to driver.
16
Datasheet
Networking Silicon — 82562V
5.4.1
Auto Plugging Detection
The 82562V senses the link all the time. If it detects loss of any link activity for more than 6.6
seconds, it indicates to the Media Access Controller (MAC) an “unplugged state” by resetting the
SQL LAN Connect control bit. If the 82562V is in reduced power mode and link activity is
detected, the 82562V notifies the MAC (in less than 1 second) that it is in a “plugged state” by
setting the SQL LAN Connect control bit. Link activity detection is based on energy detection.
5.4.2
Dynamic Reduced Power
The 82562V can be configured to support dynamic reduced power. In the dynamic reduced power
mode, the 82562V transitions to reduced power mode when an unplugged state is detected. The
82562V only returns to full power if the reduced power bit on the LAN Connect is reset and a
plugged state is detected. However, if the 82562V is not configured to support dynamic reduced
power, the 82562V operates according to the LAN Connect power-down bit (in other words, the
82562V operates in reduced power mode only if the LAN Connect power-down bit is set).
5.4.3
Configuration
The dynamic reduced power mode is configured through bit 13 of register 16. The default value is
disabled (0). The status of the 82562V is read through bits 10:9 of register 16. When the 82562V is
in reduced power mode, these two bits are set to 1b.
Table 6.
Register 16 (10 Hexadecimal): PLC Status, Control and Address Data
Bit
13
Name
Dynamic Reduced Power Down
Description
0 = Automatic reduced power down enabled
Read/Write
Read/Write
1 = Automatic reduced power down disabled
(default)
10
100BASE-TX Power Down
The 100BASE-TX Power Down bit indicates the
power state.
Read Only
0 = Normal operation (default)
1 = Power down
9
10BASE-T Power Down
The 10BASE-T Power Down bit indicates the
power state.
Read Only
0 = Normal operation (default)
1 = Power down
The 82562V PLC can enter a reduced power state manually through bit 11 of register 0. This bit is
ORed with the LAN Connect power down bit, which enables the 82562V to enter a reduced power
state.
Table 7.
Register 0: Control Data
Bit
11
Name
Reduced Power Down
Description
0 = Reduced power down disabled (normal
operation; default)
Read/Write
Read/Write
1 = Reduced power down enabled
Datasheet
17
82562V — Networking Silicon
6.0
Platform LAN Connect Registers
The following sections describe PHY registers that are accessible through the LAN Connect
management frame protocol.
Acronyms mentioned in the registers are defined as follows:
SC:
Self cleared.
RO:
Read only.
RW:
Read/Write.
E:
EEPROM setting affects content.
LL:
Latch low.
LH:
Latch high.
6.1
Medium Dependent Interface (MDI) Registers 0 through 7
6.1.1
Register 0: Control Register Bit Definitions
Bit(s)
15
Name
Reset
Description
Default
R/W
This bit sets the status and control register of the PHY to their
default states and is self-clearing. The PHY returns a value of
one until the reset process has completed and accepts a read or
write transaction.
0
RW
SC
0 = Normal operation
1 = PHY Reset
14
Loopback
This bit enables loopback of transmit data nibbles to the
receive data path. The PHY receive circuitry is isolated from
the network.
0
RW
1
RW
1
RW
0
RW
Note that this may cause the descrambler to lose
synchronization and produce 560 ns of “dead time.”
Note also that the loopback configuration bit takes priority over
the Loopback MDI bit.
0 = Loopback disabled (normal operation)
1 = Loopback enabled
13
Speed Selection
This bit is valid on read and controls speed when AutoNegotiation is disabled.
0 = 10 Mbps
1 = 100 Mbps
12
Auto-Negotiation
Enable
This bit enables Auto-Negotiation. Bits 13 and 8, Speed
Selection and Duplex Mode, respectively, are ignored when
Auto-Negotiation is enabled.
0 = Auto-Negotiation disabled
1 = Auto-Negotiation enabled
11
Reduced Power
Down
This bit sets the PHY into a low power mode.
0 = Power down disabled (normal operation)
1 = Power down enabled
18
Datasheet
Networking Silicon — 82562V
Bit(s)
10
Name
Isolate
Description
Default
R/W
0
RW
0
RW
This bit allows the PHY to isolate the medium independent
interface. The PHY is disconnected from the LAN Connect
block on both the transmit and receive side.
0 = Normal operation
1 = Isolates internal medium independent interface
9
Restart AutoNegotiation
This bit restarts the Auto-Negotiation process and is selfclearing.
SC
0 = Normal operation
1 = Restart Auto-Negotiation process
8
Duplex Mode
This bit controls the duplex mode when Auto-Negotiation is
disabled. When Auto-Negotiation is enabled this bit is read
only and always equals 1b.
0
RW/
RO
When the PHY is placed in Loopback mode, the behavior of
the PHY shall not be affected by the status of this bit.
0 = Half Duplex
1 = Full Duplex
6.1.2
7
Collision Test
This bit is not used in the 82562V and has a default value of 1b.
(If it is used in other devices, it forces a collision in response to
the assertion of the transmit enable signal.)
1
RW
6:0
Reserved
These bits are reserved and should be set to 0b.
0
RW
Register 1: Status Register Bit Definitions
Bit(s)
Name
Description
Default
R/W
15
Reserved
This bit is reserved and should be set to 0b.
0
RO
14
100BASE-TX Fullduplex
This bit enables 100BASE-TX full-duplex operation and is
dependent on ADV10. If ADV10 is active, the default
value is 0.
1
RO
1
RO
1
RO
1
RO
0 = PHY unable to perform full-duplex 100BASE-TX
1 = PHY able to perform full-duplex 100BASE-TX
13
100 Mbps Halfduplex
This bit enables 100BASE-TX half-duplex operation and is
dependent on ADV10. If ADV10 is active, the default
value is 0.
0 = PHY unable to perform half-duplex 100BASE-TX
1 = PHY able to perform half-duplex 100BASE-TX
12
10 Mbps Fullduplex
This bit enables 10BASE-T full duplex operation.
0 = PHY unable to perform full-duplex 10BASE-T
1 = PHY able to perform full-duplex 10BASE-T
11
10 Mbps Halfduplex
This bit enables 10BASE-T half-duplex operation.
0 = PHY unable to perform half-duplex 10BASE-T
1 = PHY able to perform half-duplex 10BASE-T
10:7
Reserved
These bits are reserved and should be set to 0b.
0
RO
6
Management
Frames Preamble
Suppression
This bit allows the 82562V to receive management frames
with suppressed preamble.
0
RO
0 = PHY will not accept management frames with
preamble suppressed
1 = PHY will accept management frames with preamble
suppressed
Datasheet
19
82562V — Networking Silicon
Bit(s)
5
Name
Auto-Negotiation
Complete
Description
This bit reflects status of the Auto-Negotiation process.
Default
R/W
0
RO
0
RO
1
RO
0 = Auto-Negotiation process has not completed
1 = Auto-Negotiation process completed
4
Remote Fault
0 = No remote fault condition detected
1 = Remote fault condition detected
3
Auto-Negotiation
Ability
0 = PHY is unable to perform Auto-Negotiation
This bit reflects the PHY’s Auto-Negotiation ability status.
Link Status
This bit reflects link status.
1 = PHY is able to perform Auto-Negotiation
2
0
0 = Invalid link detected
RO
LL
1 = Valid link established
1
Jabber Detect
This bit is used only in 10BASE-T mode.
0
0 = No jabber condition detected
RO
LH
1 = Jabber condition detected
0
Extended
Capability
This bit enables the extended register capabilities.
1
RO
0 = Extended register capabilities disabled
1 = Extended register capabilities enabled
6.1.3
Register 2: PHY Identifier Register Bit Definitions
Bit(s)
15:0
6.1.4
PHY ID (high byte)
Description
Value: 02A8 hexadecimal
Default
--
R/W
RO
Register 3: PHY Identifier Register Bit Definitions
Bit(s)
6.1.5
Name
Name
Description
Default
R/W
15:0
PHY ID (low byte)
Value: 0330 hexadecimal for 82562V PLC (and 82562GZ)
--
RO
15:0
PHY ID (low byte)
Value: 0310 hexadecimal for 82562G
--
RO
Register 4: Auto-Negotiation Advertisement Register Bit Definitions
Bit(s)
Name
Description
Default
R/W
15
Next Page
This bit is a constant 0, transmit primary capability data
page.
0
RO
14
Reserved
This bit is reserved and should be set to 0b.
0
RO
13
Remote Fault
0 = No remote fault
0
RW
00101111
RW
00001
RO
1 = Indicate link partner’s remote fault
20
12:5
Technology Ability
Field
Technology Ability Field is an 8-bit field containing
information indicating supported technologies specific to
the selector field value.
4:0
Selector Field
The Selector Field is a 5-bit field identifying the type of
message to be sent by Auto-Negotiation. This field is read
only and contains a value of 00001b, IEEE Standard 802.3.
Datasheet
Networking Silicon — 82562V
6.1.6
Register 5: Auto-Negotiation Link Partner Ability Register Bit Definitions
Bit(s)
6.1.7
Name
Description
Default
R/W
15
Next Page
This bit reflects the PHY’s link partner’s Next Page ability.
--
RO
14
Acknowledge
This bit is used to indicate that the 82562V has successfully
received its link partner’s Auto-Negotiation advertising
ability.
--
RO
13
Remote Fault
This bit reflects the PHY’s link partner’s Remote Fault
condition.
--
RO
12:5
Technology Ability
Field
This bit reflects the PHY’s link partner’s Technology
Ability Field.
--
RO
4:0
Selector Field
This bit reflects the PHY’s link partner’s Selector Field.
--
RO
Register 6: Auto-Negotiation Expansion Register Bit Definitions
Bit(s)
Name
Description
Default
R/W
15:5
Reserved
These bits are reserved and should be set to 0b.
0
RO
4
Parallel Detection
Fault
This bit clears itself on read.
0
RO
3
2
0 = No fault detected via parallel detection
SC
1 = Fault detected via parallel detection (multiple link
fault occurred)
LH
Link Partner Next
Page Able
0 = Link Partner is not Next Page able
Next Page Able
0 = 0 = Local drive is not Next Page able
0
RO
0
RO
0
RO
1 = Link Partner is Next Page able
1 = Local drive is Next Page able
1
0
6.2
Page Received
Link Partner AutoNegotiation Able
This bit clears itself on read.
0 = New Page not received
SC
1 = New Page received
LH
0 = Link Partner is not Auto-Negotiation able
0
RO
1 = Link Partner is Auto-Negotiation able
MDI Registers 8 through 15
Registers 8 through 15 are reserved for IEEE.
Datasheet
21
82562V — Networking Silicon
6.3
MDI Registers 16 through 31
6.3.1
Register 16: PHY Status and Control Register Bit Definitions
Bit(s)
Name
Description
Default
R/W
15:14
Reserved
These bits are reserved and should be set to 00b.
00
RW
13
Reduced Power
Down Disable
This bit disables the automatic reduced power down.
1
RW
0 = Enable automatic reduced power down
1 = Disable automatic reduced power down
12
Reserved
This bit is reserved and should be set to 0b.
0
RW
11
Receive DeSerializer In-Sync
Indication
This bit indicates status of the 100BASE-TX Receive DeSerializer In-Sync.
--
RO
10
100BASE-TX
Power-Down
This bit indicates the power state of 100BASE-TX PHY
unit.
1
RO
1
RO
--
RO
0 = Normal operation
1 = Power-down
9
10BASE-T PowerDown
0 = Normal operation
This bit indicates the power state of 10BASE-T PHY unit.
Polarity
This bit indicates 10BASE-T polarity.
1 = Power-Down
8
0 = Normal polarity
1 = Reverse polarity
7
Reserved
This bit is reserved and should be set to 0b.
0
RO
6:2
PHY Address
These bits contain the sampled PHY address.
--
RO
1
Speed
This bit indicates the Auto-Negotiation result.
--
RO
--
RO
0 = 10 Mbps
1 = 100 Mbps
0
Duplex Mode
This bit indicates the Auto-Negotiation result.
0 = Half-duplex
1 = Full-duplex
6.3.2
Register 17: PHY Unit Special Control Bit Definitions
Bit(s)
15
Name
Scrambler By-pass
Description
0 = Normal operations
Default
R/W
0
RW
0
RW
0
RW
0
RW
1 = By-pass scrambler
14
By-pass 4B/5B
0 = Normal operation
1 = 4 bit to 5 bit by-pass
13
12
22
Force Transmit HPattern
0 = Normal operation
Force 34 Transmit
Pattern
0 = Normal operation
1 = Force transmit H-pattern
1 = Force 34 transmit pattern
Datasheet
Networking Silicon — 82562V
Bit(s)
11
Name
Valid Link
Description
0 = Normal operation
Default
R/W
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
1 = 100BASE-TX valid link
10
9
Symbol Error
Enable
0 = Normal operation
Carrier Sense
Disable
This bit controls the receive 100 carrier sense disable
function.
1 = Symbol error output is enabled
0 = Carrier sense enabled
1 = Carrier sense disabled
8
7
6
Disable Dynamic
Power-Down
0 = Dynamic Power-Down enabled
Auto-Negotiation
Loopback
0 = Auto-Negotiation normal mode
MDI Tri-State
1 = Dynamic Power-Down disabled
1 = Auto-Negotiation loopback
0 = Normal operation
1 = MDI Tri-state (transmit driver tri-states)
5
Force Polarity
0 = Normal polarity
1 = Reversed polarity
4
3
Auto Polarity
Disable
0 = Normal polarity operation
Squelch Disable
0 = Normal squelch operation
1 = Auto Polarity disabled
1 = 10BASE-T squelch test disable
2
Extended Squelch
1 = 10BASE-T Extended Squelch control enabled
0 = 10BASE-T Extended Squelch control disabled
1
0
6.3.3
15:0
Jabber Function
Disable
0 = Normal Jabber operation
1 = Link disabled
1 = Jabber disabled
Name
Reserved
Description
These bits are reserved and should be set to a constant 0b.
Default
0
R/W
RO
Register 19: 100BASE-TX Receive False Carrier Counter Bit Definitions
Bit(s)
15:0
Datasheet
0 = Normal Link Integrity operation
Register 18: Reserved
Bit(s)
6.3.4
Link Integrity
Disable
Name
Receive False
Carrier
Description
These bits are used for the false carrier counter.
Default
--
R/W
RO
SC
23
82562V — Networking Silicon
6.3.5
Register 20: 100BASE-TX Receive Disconnect Counter Bit Definitions
Bit(s)
15:0
6.3.6
Disconnect Event
Description
Default
This field contains a 16-bit counter that increments for each
disconnect event. The counter stops when it is full and selfclears on read
--
R/W
RO
SC
Register 21: 100BASE-TX Receive Error Frame Counter Bit Definitions
Bit(s)
15:0
6.3.7
Name
Name
Receive Error
Frame
Description
Default
This field contains a 16-bit counter that increments once
per frame for any receive error condition (such as a symbol
error or premature end of frame) in that frame. The counter
stops when it is full and self-clears on read.
--
R/W
RO
SC
Register 22: Receive Symbol Error Counter Bit Definitions
Bit(s)
15:0
Name
Symbol Error
Counter
Description
Default
This field contains a 16-bit counter that increments for each
symbol error. The counter stops when it is full and selfclears on read.
--
R/W
RO
SC
In a frame with a bad symbol, each sequential six bad
symbols count as one.
6.3.8
Register 23: 100BASE-TX Receive Premature End of Frame Error Counter
Bit Definitions
Bit(s)
15:0
6.3.9
15:0
Default
This field contains a 16-bit counter that increments for each
premature end of frame event. The counter stops when it is
full and self-clears on read.
--
R/W
RO
SC
Name
End of Frame
Counter
Description
This is a 16-bit counter that increments for each end of
frame event. The counter stops when it is full and selfclears on read.
Default
--
R/W
RO
SC
Register 25: 10BASE-T Transmit Jabber Detect Counter Bit Definitions
Bit(s)
15:0
24
Premature End of
Frame
Description
Register 24: 10BASE-T Receive End of Frame Error Counter Bit Definitions
Bit(s)
6.3.10
Name
Name
Jabber Detect
Counter
Description
Default
This is a 16-bit counter that increments for each jabber
detection event. The counter stops when it is full and selfclears on read.
--
R/W
RO
SC
Datasheet
Networking Silicon — 82562V
6.3.11
Register 27: PHY Unit Special Control Bit Definitions
Bit(s)
Name
Description
Default
R/W
15:6
Reserved
These bits are reserved and should be set to a constant 0.
0
RO
5
Switch Probe
Mapping
This bit switches the mapping on the LEDs. The LED
mapping is described below in bits 2:0, LED Switch
Control. This bit should always be set to 0b.
0
RW
4
New mode
If this bit equals 0, the device is in 82562EZ (or 82562ET)
mode.
RO
If this bit equals 1, the device is in 82562V (or 82562GZ)
mode.
6.3.12
3
100BASE-TX
Receive Jabber
Disable
2:0
LED Switch
Control
This bit enables the carrier sense disconnection while the
PHY is in jabber mode at 100 Mbps speed.
Value
ACTLED#
LILED#
000
Activity
Link
001
Speed
Collision
010
Speed
Link
011
Activity
Collision
100
Off
Off
101
Off
On
110
On
Off
111
On
On
0
RW
000
RW
Register 28: MDI/MDI-X Control Bit Definitions
Bit(s)
Name
Description
Default
R/W
15:8
Reserved
These bits are reserved and should be set to a constant 0.
0
RW
7
Auto Switch
Enable
Enables the MDI/MDI-X feature (writing to this bit
overwrites the default value).
0
RW
1 = Enabled.
0 = Disabled.
6
Switch
RW
Manual switch (valid only if bit 7 is set to 0).
1 = Forces the port to be MDI-X (cross-over).
0
0 = Forces the port to be MDI (straight-through).
5
Status
Indicates the state of the MDI pair.
0
RO
0
RO
0000
RW
1 = MDI-X (cross-over).
0 = MDI (straight-through).
4
Auto Switch
Complete
Indicates when the correct configuration is achieved.
1 = Resolution algorithm has completed.
0 = Resolution algorithm has not completed.
3:0
Resolution Timer
Defines the minimum slot time the algorithm uses in order
to switch between one configuration or another.
0000 = 80 ms.
1111 = 105 ms.
Datasheet
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82562V — Networking Silicon
Note:
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Datasheet
Networking Silicon — 82562V
7.0
82562V Test Port Functionality
The 82562V’s XOR Tree Test Access Port (TAP) is the access point for test data to and from the
device. The port provides the ability to perform basic production level testing.
7.1
Asynchronous Test Mode
An asynchronous test mode is supported for system level design use. The modes are selected
through the use of the Test Port input pins (TESTEN, ISOL_TCK, ISOL_TI and ISOL_EXEC) in
static combinations. During normal operation the test pins must be pulled down through a resistor
(pulling Test high enables the test mode). All other port inputs may have a pull-down at the
designers discretion.
7.2
Test Function Description
The 82562V TAP mode supports several tests that can be used in board level design. These tests
can help verify basic functionality and test the integrity of solder connections on the board. The
tests are described in the following sections.
The XOR Tree test mode is the most useful of the asynchronous test modes. It enables the
placement of the 82562V to be validated at board test. The XOR Tree was chosen for its speed
advantages. Modern Automated Test Equipment (ATE) can perform a complete peripheral scan
without support at the board level. This command connects all output signals of the input buffers in
the device periphery into an XOR Tree scheme. All output drivers of the output-buffers, except the
test output (TOUT) pin, are put into high-Z mode. These pins are driven to affect the tree’s output.
Any hard strapped pins will prevent the tester from scanning correctly. The XOR Tree test mode is
obtained by placing the test pins in the following configuration (refer to Table 8):
TESTEN = 1
ISOL_TCK = 0
ISOL_TI = 0
ISOL_EXEC = 0.
Table 8.
XOR Tree Chain Order
Chain Order
Datasheet
Chain
1
JTXD2
2
JTXD1
3
JTXD0
4
JRSTSYNC
5
ADV10 (LAN_DISABLE#)
6
JCLK
7
JRXD2
8
JRXD1
9
JRXD0
10
ACTLED#
27
82562V — Networking Silicon
Table 8.
XOR Tree Chain Order
Chain Order
Chain
11
SPDLED#
12
LILED#
XOR Tree Output
TOUT
The following pins are not included in the XOR Tree chain: X1, ISOL_TCK, ISOL_EXEC,
ISOL_TI and TESTEN.
28
Datasheet
Networking Silicon — 82562V
8.0
Electrical and Timing Specifications
8.1
Absolute Maximum Ratings
Maximum ratings are listed below:
Case Temperature under Stress . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0° C to 135° C
Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-65° C to 150° C
Supply Voltage with respect to VSS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.5 V to 3.45 V
Output Voltages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.50 V to 3.45 V
Input Voltages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VCC to 3.45 V
Stresses above the listed absolute maximum ratings may cause permanent damage to the 82562V
device. This is a stress rating only and functional operations of the device at these or any other
conditions above those indicated in the operational sections of this specification is not implied.
Exposure to absolute maximum rating conditions for extended periods may affect device
reliability.
8.2
DC Characteristics
Table 9.
General DC Specifications
Symbol
Datasheet
Parameter
Condition
Min
Typical
Max
Units
3.0
3.3
3.45
V
85
C
VCC
Supply Voltage
T
Temperature
Minimum/Maximum Case
Temperature
P
Power
Consumption
10/100 Mbps (transmitter
on)
300
mW
Reduced Power
50
mW
Auto-Negotiation
200
mW
0
Notes
29
82562V — Networking Silicon
Table 10. Current and Power Values (measured)*
Link State
3.3V
Current
(mA)
82562V Power
Measurement
(mW)**
100Mb - active
126
415.8
100Mb - idle
127
419.1
System
State
Maximum
100Mb - active
127
419.1
100Mb - idle
127
419.1
10Mb - active
95.5
315.5
10Mb - idle
66.5
219.4
No Link
95
311.8
D0
* Averaging of three typical units at typical and maximum conditions with nominal VCC.
** LED power deducted from overall power consumption.
8.2.1
X1 Clock DC Specifications
Table 11. X1 Clock DC Specifications
Symbol
Parameter
VIL
Input Low Voltage
VIH
Input High Voltage
IILIH
Input Leakage
Currents
CI
Input Capacitance
Condition
Min
Typical
Max
Units
0.8
V
2.0
0 < VIN < VCC
Notes
V
±10
µA
8
pF
1
NOTES:
1. This characteristic is only characterized, not tested. It is valid for digital pins only.
30
Datasheet
Networking Silicon — 82562V
8.2.2
LAN Connect Interface DC Specifications
Table 12. LAN Connect Interface DC Specifications
Symbol
Parameter
Condition
Min
Typical
Max
Units
VCCJ
Input/Output
Supply Voltage
3.0
3.45
V
VIL
Input Low Voltage
-0.5
0.3VCCJ
V
VIH
Input High Voltage
0.6VCCJ
VCCJ + 0.5
V
IIL
Input Leakage
Current
0 < VIN < VCCJ
±10
µA
VOL
Output Low
Voltage
IOUT = 1500 µA
0.1VCCJ
V
VOH
Output High
Voltage
IOUT = -500 µA
CIN
Input Pin
Capacitance
0.9VCCJ
Notes
V
8
pF
1
NOTES:
1. This characteristic is only characterized, not tested. It is valid for digital pins only.
8.2.3
LED DC Specifications
Table 13. LED DC Specifications
Symbol
8.2.4
Parameter
Condition
VOLLED
Output Low
Voltage
IOUT = 10 mA
VOHLED
Output High
Voltage
IOUT = -10 mA
Min
Typical
Max
Units
0.7
V
2.4
Notes
V
10BASE-T Voltage and Current DC Specifications
Table 14. 10BASE-T Transmitter
Symbol
VOD10
Parameter
Output Differential
Peak Voltage
Condition
RL = 100 Ω
Min
Typical
2.2
Max
Units
Notes
2.8
V
1
Units
Notes
KΩ
1
NOTES:Current is measured between the transmit differential pins (TDP and TDN) at 3.3 V.
1. RL is the resistive load measured across the transmit differential pins, TDP and TDN.
Table 15. 10BASE-T Receiver
Symbol
RID10
Datasheet
Parameter
Input Differential
Resistance
Condition
DC
Min
10
Typical
Max
31
82562V — Networking Silicon
Table 15. 10BASE-T Receiver
VIDA10
Input Differential
Accept Peak
Voltage
5 MHz ≤ f ≤ 10 MHz
585
VIDR10
Input Differential
5 MHz ≤ f ≤ 10 MHz
Reject Peak Voltage
VICM10
Input Common
Mode Voltage
3100
mV
300
mV
VCC/2
V
NOTES:
1. The input differential resistance is measured across the receive differential pins, RDP and RDN.
8.2.5
100BASE-TX Voltage and Current DC Specifications
Table 16. 100BASE-TX Transmitter
Symbol
VOD100
Parameter
Output Differential
Peak Voltage
Condition
RL = 100 Ω
Min
Typical
Max
Units
Notes
0.95
1.0
1.05
V
1
Units
Notes
KΩ
1
NOTES:Current is measured between the transmit differential pins (TDP and TDN) at 3.3 V.
1. RL is the resistive load measured across the transmit differential pins, TDP and TDN.
Table 17. 100BASE-TX Receiver
Symbol
Parameter
RID100
Input Differential
Resistance
VIDA100
Input Differential
Accept Peak
Voltage
VIDR100
Input Differential
Reject Peak Voltage
VICM100
Input Common
Mode Voltage
Condition
DC
Min
Typical
Max
10
500
1200
mV
100
mV
VCC/2
V
NOTES:
1. The input differential resistance is measured across the receive differential pins, RDP and RDN.
32
Datasheet
Networking Silicon — 82562V
8.3
AC Characteristics
Figure 5 defines the conditions for timing measurements. The design must guarantee proper
operation for voltage swings and slew rates that exceed the specified test conditions.
Figure 5. AC Test Level Conditions
Input Levels
Output Levels
VOH = 2.0 V
1.4 V
VOL = 0.8 V
8.3.1
10BASE-T Normal Link Pulse (NLP) Timing Parameters
Table 18. Normal Link Pulse Timing Parameters
Symbol
Parameter
Condition
T6
TNLP_WID
NLP Width
10 Mbps
T7
TNLP_PER
NLP Period
10 Mbps
Min
Typical
Max
100
8
16
Units
Notes
ns
24
ms
Figure 6. Normal Link Pulse Timings
T7
T6
Normal Link Pulse
Datasheet
33
82562V — Networking Silicon
8.3.2
Auto-Negotiation Fast Link Pulse (FLP) Timing Parameters
Table 19. Fast Link Pulse Timing Parameters
Symbol
Parameter
Condition
Min
Typical
Max
Units
T8
TFLP_WID
FLP Width (clock
and data)
T9
TFLP_CLK_CLK
Clock Pulse to
Clock Pulse Period
111
125
139
µs
T10
TFLP_CLK_DATA
Clock Pulse to Data
Pulse Period
55.5
62.5
69.5
µs
T11
TFLP_BUR_NUM
Pulses in One Burst
17
33
#
T12
TFLP_BUR_WID
Burst Width
T13
TFLP_BUR_PER
FLP Burst Period
100
ns
2
8
16
Notes
ms
24
ms
Figure 7. Fast Link Pulse Timings
T9
T10
T8
Fast Link Pulse
Clock Pulse
Data Pulse
Clock Pulse
T13
T12
FLP Bursts
34
Datasheet
Networking Silicon — 82562V
8.3.3
100BASE-TX Transmitter AC Specifications
Table 20. 100BASE-TX Transmitter Timing Parameters
Symbol
T14
8.3.4
TJIT
Parameter
TDP/TDN
Differential Output
Peak Jitter
Condition
Min
Typical
Max
Units
1400
ps
Max
Units
Notes
HLS Data
Reset (JRSTSYNC) AC Specifications
Table 21. Reset Timing Parameters
Symbol
Parameter
Condition
Min
Typical
T58
TRST_WID
Reset Pulse Width
500
µs
T59
TPOP_RST
Power-up to Falling
Edge of Reset
1000
µs
Notes
Figure 8. Reset Timing Parameters
Power Up
(Vcc)
RESET
Datasheet
T59
T58
35
82562V — Networking Silicon
9.0
Package and Pinout Information
9.1
Package Information
The 82562V is a 81-pin Mold Cap package. The Package dimensions are shown in Figure 9. More
information on Intel device packaging is available in the Intel Packaging Handbook, which is
available from the Intel Literature Center or your local sales office.
Figure 9. Dimension Diagram for the 82562V PLC
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9.2
Pinout Information
9.2.1
82562V Pin Assignments
Table 22. 82562V Pin Assignments
36
Pin
Number
Pin Name
Pin
Number
Pin Name
Pin
Number
Pin Name
Pin
Number
Pin Name
A1
NC
C7
VSS
F4
VSS
J1
NC
A2
NC
C8
VSS
F5
NC
J2
NC
A3
N3
C9
VSS
F6
VSS
J3
VSS
A4
LINK_UP_N
D1
JTXD0
F7
VCCA
J4
NC
A5
SPEED_LED
D2
JRXD1
F8
NC
J5
VSSA2
A6
adv10/
LAN_DIS/N
D3
JRXD0
F9
NC
J6
NC
A7
NC
D4
VCC
G1
ISOL_TCK
J7
NC
A8
VSS
D5
NC
G2
ISOL_EXEC
J8
NC
A9
NC
D6
VSS
G3
TOUT
J9
NC
B1
NC
D7
VCCR
G4
VCCA2
B2
NC
D8
RDN
G5
NC
Datasheet
Networking Silicon — 82562V
Table 22. 82562V Pin Assignments
Pin
Number
Pin Name
Pin
Number
Pin Name
Pin
Number
Pin Name
B3
VCC
D9
RDP
G6
VSS
B4
ACT_LED
E1
VSSP
G7
RBIAS100
B5
NC
E2
JCLK
G8
VSS
B6
TEST_EN
E3
JRST_SYNC
G9
VSS
B7
NC
E4
VCC
H1
ISOL_TI
B8
TDP
E5
VCC
H2
NC
B9
TDN
E6
NC
H3
VCC
C1
JRXD2
E7
NC
H4
NC
C2
NC
E8
VCCT
H5
X2
C3
NC
E9
VSS
H6
X1
C4
VSS
F1
JTXD2
H7
RBIAS10
C5
NC
F2
VCCP
H8
NC
C6
VSSR
F3
JTXD1
H9
NC
Pin
Number
Pin Name
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Datasheet
37
82562V — Networking Silicon
9.2.2
82562V Package Diagram
Figure 10. 82562V Pin Out Diagram--Top View
38
NC
NC
NC
NC
VSSA2
NC
VSS
NC
NC
J
NC
NC
RBIAS10
X1
X2
NC
VCC
NC
ISOL_TI
H
VSSA
VSS
RBIAS100
VSS
NC
VCCA2
TOUT
ISOL_EX ISOL_TC
EC
K
G
NC
NC
VCCA
VSS
NC
VSS
JTXD1
VCCP
JTXD2
F
VSS
VCCT
NC
NC
VCC
VCC
JRSTSYN
C
JCLK
VSSP
E
RDP
RDN
VCCR
VSS
NC
VCC
JRXD0
JRXD1
JTXD0
D
VSS
VSS
VSS
VSSR
NC
VSS
NC
NC
JRXD2
C
TDN
TDP
NC
TEST_EN
NC
ACT_LED
VCC
NC
NC
B
NC
VSS
NC
ADV10/la SPEED_L LINK_UP_
n_dis_n
ED
N
NC
NC
NC
A
9
8
7
3
2
1
6
5
4
Datasheet
Networking Silicon — 82562V
Note:
Datasheet
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39
82562V — Networking Silicon
40
Datasheet