INTEL 82541ER_13

82541ER Gigabit Ethernet Controller
Networking Silicon
Datasheet
Product Features
■
■
■
PCI Bus
— PCI revision 2.3, 32-bit, 33/66 MHz
— Algorithms that optimally use advanced PCI,
MWI, MRM, and MRL commands
— 3.3 V (5 V tolerant PCI signaling)
MAC Specific
— Low-latency transmit and receive queues
— IEEE 802.3x-compliant flow-control support
with software-controllable thresholds
— Caches up to 64 packet descriptors in a single
burst
— Programmable host memory receive buffers
(256 B to 16 KB) and cache line size (16 B to
256 B)
— Wide, optimized internal data path
architecture
— 64 KB configurable Transmit and Receive
FIFO buffers
PHY Specific
— Integrated for 10/100/1000 Mb/s operation
— IEEE 802.3ab Auto-Negotiation support
— IEEE 802.3ab PHY compliance and
compatibility
— State-of-the-art DSP architecture implements
digital adaptive equalization, echo
cancellation, and cross-talk cancellation
■
■
■
■
— Automatic polarity detection
— Automatic detection of cable lengths and
MDI vs. MDI-X cable at all speeds
Host Off-Loading
— Transmit and receive IP, TCP, and UDP
checksum off-loading capabilities
— Transmit TCP segmentation
— Advanced packed filtering
— Jumbo frame support up to 16 KB
— Intelligent Interrupt generation (multiple
packets per interrupt)
Manageabiltiy
— Network Device Class Power Management
Specification 1.1
— Compliance with PCI Power Management
1.1 and ACPI 2.0
— SNMP and RMON statistic counters
— D0 and D3 power states
Additional Device
— Four programmable LED outputs
— On-chip power control circuitry
— BIOS LAN Disable pin
— JTAG (IEEE 1149.1) Test Access Port built
in silicon (3.3 V, 5 V tolerant PCI signaling)
Lead-freea 196-pin Ball Grid Array (BGA).
Devices that are lead-free are marked with a
circled “e1” and have the product code:
LUxxxxxx.
a. This device is lead-free. That is, lead has not been intentionally added, but lead may still exist as an impurity at
<1000 ppm. The Material Declaration Data Sheet, which includes lead impurity levels and the concentration of other
Restriction on Hazardous Substances (RoHS)-banned materials, is available at:
ftp://download.intel.com/design/packtech/material_content_IC_Package.pdf#pagemode=bookmarks
In addition, this device has been tested and conforms to the same parametric specifications as previous versions of
the device.
For more information regarding lead-free products from Intel Corporation, contact your Intel Field Sales representative
318139-002
Revision 4.3
Revision History
Date
Revision
Aug 2003
2.0
Non-classified release.
Notes
Mar 2004
3.0
Updated Section 4, “Voltage, Temperature, and Timing Specifications,” for the C-0
stepping.
Oct 2004
3.1
•
•
Corrected EEMODE signal description.
Updated signal names to match design guide and reference schematics.
•
•
Added lead free information.
Added information about migrating from a 2-layer 0.36 mm wide-trace substrate to
a 2-layer 0.32 mm wide-trace substrate. Refer to the section on Package and
Pinout Information.
• Added statement that no changes to existing soldering processes are needed for
the 2-layer 0.32 mm wide-trace substrate change in the section describing
“Package Information”.
• Corrected pinout discrepancies between sections “Signal Descriptions” and
“Package and Pinout Information”.
Nov 2004
3.2
Jan 2005
3.3
Feb 2005
3.4
•
Updated Visual Pin Assignment diagram for pinouts F9, F10, E14, F14, and H14.
Apr 2005
3.5
•
•
Removed all references to CLK_RUN# signal.
Corrected the FLSH_SO/LAN_DISABLE signal definition. If Flash functionality is
not used then an external pull-down resistor is required.
July 2005
3.6
•
Added pin C8 description to Table 29 and Table 31.
Aug 2005
3.7
•
Added new maximum values for DC supply voltages on 1.2 V and 1.8 V pins. See
Table 2, Recommended Operating Conditions and Table 6, DC Characteristics.
•
Corrected 25 MHz Clock Input Requirements in Table 13.
•
Corrected the FLSH_SO/LAN_DISABLE signal definition. If Flash functionality is
not used then an external pull-up resistor is required.
June 2006
3.8
June 2006
3.9
•
Updated Table 13 “25 MHz Clock Input Requirements”.
Aug 2006
4.0
•
•
Updated Table 40 descriptions for pins A10, B10, and C9.
Updated pinout descriptions from Tables 25 - 42 to match Figure 13.
Sept 2006
4.1
•
Removed note “b” from Table 2 and note “a” from Tables 3 and 4. Moved the note
following Table 5 before Table 3 “3.3V Supply Voltage Ramp”
Aug 2007
4.2
•
Added new Intel logo, updated “Product Features”, and added new document
ordering information to copyright page.
June 2008
4.3
•
Clarified product ordering codes.
Information in this document is provided in connection with Intel products. No license, express or implied, by estoppel or otherwise, to any intellectual
property 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, merchantability, or infringement of any patent, copyright or other intellectual property right. Intel products are not
intended for use in medical, life saving, or life 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 82541ER Gigabit Ethernet Controller 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 from:
Intel Corporation
P.O. Box 5937
Denver, CO 80217-9808
or call in North America 1-800-548-4725, Europe 44-0-1793-431-155, France 44-0-1793-421-777, Germany 44-0-1793-421-333, other Countries 708296-9333.
Intel® is a trademark or registered trademark of Intel Corporation or its subsidiaries in the United States and other countries.
Copyright © Intel Corporation, 2008
*Third-party brands and names are the property of their respective owners.
ii
82541ER Gigabit Ethernet Controller
Contents
1.0
Introduction ...................................................................................................................... 1
1.1
1.2
1.3
1.4
Document Scope................................................................................................... 1
Reference Documents...........................................................................................2
Product Codes....................................................................................................... 2
Block Diagram ....................................................................................................... 3
2.0
Product Code.................................................................................................................... 5
3.0
Signal Descriptions.......................................................................................................... 7
3.1
3.2
3.3
3.4
3.5
3.6
3.7
4.0
Voltage, Temperature, and Timing Specifications ......................................................15
4.1
4.2
4.3
4.4
4.5
5.0
Signal Type Definitions.......................................................................................... 7
PCI Bus Interface Signals (56) ..............................................................................7
3.2.1 PCI Address, Data and Control Signals (44) ............................................ 8
3.2.2 Arbitration Signals (2)............................................................................... 9
3.2.3 Interrupt Signal (1)....................................................................................9
3.2.4 System Signals (3) ................................................................................... 9
3.2.5 Error Reporting Signals (2).....................................................................10
3.2.6 Power Management Signals (2) .............................................................10
EEPROM and Serial FLASH Interface Signals (9)..............................................10
Miscellaneous Signals.........................................................................................11
3.4.1 LED Signals (4) ......................................................................................11
3.4.2 Other Signals (4) ....................................................................................11
PHY Signals ........................................................................................................11
3.5.1 Crystal Signals (2) ..................................................................................11
3.5.2 Analog Signals (10) ................................................................................12
Test Interface Signals (6) ....................................................................................12
Power Supply Connections .................................................................................13
3.7.1 Digital and Analog Supplies ...................................................................13
3.7.2 Grounds, Reserved Pins and No Connects ...........................................13
3.7.3 Voltage Regulation Control Signals (2) ..................................................13
Absolute Maximum Ratings.................................................................................15
Targeted Recommended Operating Conditions..................................................15
4.2.1 General Operating Conditions................................................................15
4.2.2 Voltage Ramp and Sequencing Recommendations...............................16
DC Specifications ................................................................................................18
AC Characteristics...............................................................................................21
Timing Specifications ..........................................................................................23
4.5.1 PCI Bus Interface ...................................................................................23
4.5.1.1 PCI Bus Interface Clock ............................................................23
4.5.1.2 PCI/PCI-X Bus Interface Timing ................................................24
4.5.2 Link Interface Timing ..............................................................................27
4.5.3 EEPROM Interface.................................................................................27
Package and Pinout Information ..................................................................................29
5.1
5.2
Package Information ...........................................................................................29
Thermal Specifications ........................................................................................31
iii
82541ER Gigabit Ethernet Controller
5.3
5.4
Pinout Information ............................................................................................... 32
Visual Pin Assignments....................................................................................... 42
1
2
3
4
5
6
7
8
9
10
11
12
13
82541ER Block Diagram....................................................................................... 3
AC Test Loads for General Output Pins.............................................................. 23
PCI Clock Timing ................................................................................................ 23
PCI Bus Interface Output Timing Measurement ................................................. 24
PCI Bus Interface Input Timing Measurement Conditions .................................. 25
TVAL (max) Rising Edge Test Load.................................................................... 25
TVAL (max) Falling Edge Test Load ................................................................... 26
TVAL (min) Test Load ......................................................................................... 26
TVAL Test Load (PCI 5 V Signaling Environment) ............................................. 26
Link Interface Rise/Fall Timing............................................................................ 27
82541ER Mechanical Specifications................................................................... 29
196 PBGA Package Pad Detail........................................................................... 30
Visual Pin Assignments....................................................................................... 42
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
Absolute Maximum Ratings ................................................................................ 15
Recommended Operating Conditions ................................................................ 15
3.3V Supply Voltage Ramp ................................................................................. 16
1.8V Supply Voltage Ramp ................................................................................. 16
1.2V Supply Voltage Ramp ................................................................................. 17
DC Characteristics .............................................................................................. 18
Power Specifications - D0a ................................................................................. 18
Power Specifications - D3cold ............................................................................ 18
Power Specifications D(r) Uninitialized) .............................................................. 19
Power Specifications - Complete Subsystem ..................................................... 19
I/O Characteristics............................................................................................... 20
AC Characteristics: 3.3 V Interfacing .................................................................. 21
25 MHz Clock Input Requirements ..................................................................... 21
Reference Crystal Specification Requirements................................................... 22
Link Interface Clock Requirements ..................................................................... 22
EEPROM Interface Clock Requirements ............................................................ 22
AC Test Loads for General Output Pins.............................................................. 22
PCI Bus Interface Clock Parameters .................................................................. 23
PCI Bus Interface Timing Parameters................................................................. 24
PCI Bus Interface Timing Measurement Conditions ........................................... 25
Rise and Fall Times ............................................................................................ 27
Link Interface Clock Requirements ..................................................................... 27
Link Interface Clock Requirements ..................................................................... 27
Thermal Characteristics ...................................................................................... 31
PCI Address, Data and Control Signals .............................................................. 32
PCI Arbitration Signals ........................................................................................ 32
Interrupt Signals .................................................................................................. 32
System Signals ................................................................................................... 32
Error Reporting Signals....................................................................................... 33
Power Management Signals ............................................................................... 33
Serial EEPROM Interface Signals....................................................................... 33
Figures
Tables
iv
82541ER Gigabit Ethernet Controller
32
33
34
35
36
37
38
39
40
41
42
Serial FLASH Interface Signals...........................................................................33
LED Signals.........................................................................................................33
Other Signals.......................................................................................................33
IEEE Test Signals ...............................................................................................34
PHY Signals ........................................................................................................34
Test Interface Signals..........................................................................................34
Digital Power Signals ..........................................................................................34
Analog Power Signals .........................................................................................35
Grounds and No Connect Signals.......................................................................35
Voltage Regulation Control Signals.....................................................................35
Signal Names in Pin Order..................................................................................36
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82541ER Gigabit Ethernet Controller
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82541ER Gigabit Ethernet Controller
1.0
Introduction
The Intel® 82541ER Gigabit Ethernet is a single, compact component with an integrated Gigabit
Ethernet Media Access Control (MAC) and physical layer (PHY) functions. For embedded
communication and network devices such as web kiosks, and Point-of-Sale terminal designs with
critical space constraints, the Intel 82541ER allows for a Gigabit Ethernet implementation in a very
small area that is footprint compatible with current generation 10/100 Mbps Fast Ethernet designs.
The Intel® 82541ER integrates fourth generation gigabit MAC design with fully integrated,
physical layer circuitry to provide a standard IEEE 802.3 Ethernet interface for 1000BASE-T,
100BASE_TX, and 10BASE-T applications (802.3, 802.3u, and 802.3ab). The controller is
capable of transmitting and receiving data at rates of 1000 Mbps, 100 Mbps, or 10 Mbps. In
addition to managing MAC and PHY layer functions, the controller provides a 32-bit wide direct
Peripheral Component Interconnect (PCI) 2.3 compliant interface capable of operating at 33 or 66
MHz.
The 82541ER Architecture is designed for high performance and low memory latency. Wide
internal data paths eliminate performance bottlenecks by efficiently handling large address and
data words. The 82541ER controller includes advanced interrupt handling features to limit PCI bus
traffic and a PCI interface that maximizes efficient bus usage. The 82541ER uses efficient ring
buffer descriptor data structures, with up to 64 packet descriptors cached on chip. A large 64 KByte
on-chip packet buffer maintains superior performance as available PCI bandwidth changes. In
addition, using hardware acceleration, the controller offloads tasks from the host controller, such as
TCP/UDP/IP checksum calculations and TCP segmentation.
The 82541ER is packaged in a 15 mm X 15 mm 196-ball grid array and is pin compatible with the
82559ER/82551ER 10/100 Mbps Fast Ethernet Multifunction PCI/CardBus Controller, 82562EZ/
82562EX Platform LAN Connect devices, the 82540EM Gigabit Ethernet Controller and the
82540EP Gigabit Ethernet Controller.
1.1
Document Scope
This document contains datasheet specifications for the 82541ER Gigabit Ethernet Controller,
including signal descriptions, DC and AC parameters, packaging data, and pinout information.
1
82541ER Gigabit Ethernet Controller
1.2
Reference Documents
This document assumes that the designer is acquainted with high-speed design and board layout
techniques. The following documents provide additional information:
• 825462EZ(EX)/82551ER(IT) & 82541ER Combined Footprint LOM Design Guide. Intel
Corporation.
• 82547GI(EI)/82541(PI/GIEI) & 82541ER EEPROM Map and Programming Information
Guide. Intel Corporation.
• PCI Local Bus Specification, Revision 2.3. PCI Special Interest Group.
• PCI Bus Power Management Interface Specification, Revision 1.1. PCI Special Interest
Group.
• IEEE Standard 802.3, 2003 Edition. Incorporates various IEEE standards previously published
separately. Institute of Electrical and Electronics Engineers (IEEE).
• Intel Ethernet Controllers Timing Device Selection Guide. Intel Corporation.
• PCI Mobile Design Guide, Revision 1.1. PCI Special Interest Group.
Software driver developers should contact their local Intel representatives for programming
information.
1.3
Product Codes
The product ordering codes are:
• GD82541ER (leaded device)
• LU82541ER (lead-free device)
2
82541ER Gigabit Ethernet Controller
1.4
Block Diagram
EEPROM
PCI Core
Slave
Access
Logic
Flash
DMA Function
Descriptor Management
64KB
Packet
RAM
Control
Status
Logic
TX/RX MAC
CSMA/CD
RX FIlters
(Perfect & VLAN)
VLA
N
Statistics
8 bits
Management
Interface
8 bits
Trellis Viterbi
Encoder/Decoder
Side-stream
Scrambler/
Descrambler
4 bits
PHY
Control
4 bits
ECHO, NEXT,
FEXT
Cancellers
4DPAM5
Encoder
AGC, A/D
Timing
Recovery
Pulse Shaper,
DAC, Filter
Hybrid
Line Driver
Media Dependent Interface
Figure 1. 82541ER Block Diagram
3
82541ER Gigabit Ethernet Controller
Note:
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82541ER Gigabit Ethernet Controller
2.0
Product Ordering Codes
The product ordering codes for the 82541ER Gigabit Ethernet Controller are:
• GD82541ER (leaded device)
• LU82541ER (lead-free device)
5
82541ER Gigabit Ethernet Controller
Note:
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82541ER Gigabit Ethernet Controller
3.0
Signal Descriptions
3.1
Signal Type Definitions
The signals of the 82541ER controller are electrically defined as follows:
Name
Definition
I
Input. Standard input only digital signal.
O
Output. Standard output only digital signal.
TS
Tri-state. Bi-directional tri-state digital input/output signal.
STS
Sustained Tri-state. An active low tri-state signal owned and driven by only one agent at a
time. The agent that drives an STS pin low must drive it high for at least one clock before letting
it float. A new agent cannot start driving an STS signal any sooner than one clock after the
previous owner tri-states it. A pullup is required to sustain the inactive state until another agent
drives it, and must be provided by the central resource.
Open Drain. Wired-OR with other agents.
3.2
OD
The signaling agent asserts the OD signal, but the signal is returned to the inactive state by a
weak pull-up resistor. The pull-up resistor may require two or three clock periods to fully restore
the signal to the de-asserted state.
A
Analog. PHY analog data signal.
P
Power. Power connection, voltage reference, or other reference connection.
PCI Bus Interface Signals (56)
When the Reset signal (RST#) is asserted, the 82541ER will not drive any PCI output or bidirectional pins.
7
82541ER Gigabit Ethernet Controller
3.2.1
PCI Address, Data and Control Signals (44)
Symbol
Type
Name and Function
Address and Data. Address and data signals are multiplexed on the same PCI pins. A
bus transaction includes an address phase followed by one or more data phases.
AD[31:0]
TS
The address phase is the clock cycle when the Frame signal (FRAME#) is asserted
low. During the address phase AD[31:0] contain a physical address (32 bits). For I/O,
this is a byte address, and for configuration and memory, a DWORD address. The
82541ER device uses little endian byte ordering.
During data phases, AD[7:0] contain the least significant byte (LSB) and AD[31:24]
contain the most significant byte (MSB).
C/BE#[3:0]
TS
Bus Command and Byte Enables. Bus command and byte enable signals are
multiplexed on the same PCI pins. During the address phase of a transaction, C/
BE#[3:0] define the bus command. In the data phase, C/BE#[3:0] are used as byte
enables. The byte enables are valid for the entire data phase and determine which byte
lanes contain meaningful data.
C/BE#[0] applies to byte 0 (LSB) and C/BE#[3] applies to byte 3 (MSB).
PAR
TS
Parity. The Parity signal is issued to implement even parity across AD[31:0] and C/
BE#[3:0]. PAR is stable and valid one clock after the address phase. During data
phases, PAR is stable and valid one clock after either IRDY# is asserted on a write
transaction or TRDY# is asserted after a read transaction. Once PAR is valid, it remains
valid until one clock after the completion of the current data phase.
When the 82541ER controller is a bus master, it drives PAR for address and write data
phases, and as a slave device, drives PAR for read data phases.
FRAME#
IRDY#
TRDY#
STOP#
8
STS
STS
STS
STS
Cycle Frame. The Frame signal is driven by the 82541ER device to indicate the
beginning and length of a bus transaction.
While FRAME# is asserted, data transfers continue. FRAME# is de-asserted when the
transaction is in the final data phase.
Initiator Ready. Initiator Ready indicates the ability of the 82541ER controller (as a bus
master device) to complete the current data phase of the transaction. IRDY# is used in
conjunction with the Target Ready signal (TRDY#). The data phase is completed on
any clock when both IRDY# and TRDY# are asserted.
During the write cycle, IRDY# indicates that valid data is present on AD[31:0]. For a
read cycle, it indicates the master is ready to accept data. Wait cycles are inserted until
both IRDY# and TRDY# are asserted together. The 82541ER controller drives IRDY#
when acting as a master and samples it when acting as a slave.
Target Ready. The Target Ready signal indicates the ability of the 82541ER controller
(as a selected device) to complete the current data phase of the transaction. TRDY# is
used in conjunction with the Initiator Ready signal (IRDY#). A data phase is completed
on any clock when both TRDY# and IRDY# are sampled asserted.
During a read cycle, TRDY# indicates that valid data is present on AD[31:0]. For a write
cycle, it indicates the target is ready to accept data. Wait cycles are inserted until both
IRDY# and TRDY# are asserted together. The 82541ER device drives TRDY# when
acting as a slave and samples it when acting as a master.
Stop. The Stop signal indicates the current target is requesting the master to stop the
current transaction. As a slave, the 82541ER controller drives STOP# to request the
bus master to stop the transaction. As a master, the 82541ER controller receives
STOP# from the slave to stop the current transaction.
82541ER Gigabit Ethernet Controller
Symbol
3.2.2
I
Initialization Device Select. The Initialization Device Select signal is used by the
82541ER as a chip select signal during configuration read and write transactions.
DEVSEL#
STS
Device Select. When the Device Select signal is actively driven by the 82541ER, it
signals notifies the bus master that it has decoded its address as the target of the
current access. As an input, DEVSEL# indicates whether any device on the bus has
been selected.
VIO
P
VIO. The VIO signal is a voltage reference for the PCI interface (3.3 V or 5 V PCI
signaling environment). It is used as the clamping voltage.
Note: VIO should be connected to 3.3V Aux or 5V Aux in order to be compatible with
the pull-up clamps specification.
Arbitration Signals (2)
Type
Name and Function
REQ#
TS
Request Bus. The Request Bus signal is used to request control of the bus from the
arbiter. This signal is point-to-point.
GNT#
I
Grant Bus. The Grant Bus signal notifies the 82541ER that bus access has been
granted. This is a point-to-point signal.
Interrupt Signal (1)
Symbol
INTA#
3.2.4
Name and Function
IDSEL#
Symbol
3.2.3
Type
Type
TS
Name and Function
Interrupt A. Interrupt A is used to request an interrupt of the 82541ER. It is an active
low, level-triggered interrupt signal.
System Signals (3)
Symbol
Type
Name and Function
CLK
I
PCI Clock. The PCI Clock signal provides timing for all transactions on the PCI bus
and is an input to the 82541ER device. All other PCI signals, except the Interrupt A
(INTA#) and PCI Reset signal (RST#), are sampled on the rising edge of CLK. All other
timing parameters are defined with respect to this edge.
M66EN
I
66 MHz Enable. M66EN indicates whether the system bus is enabled for 66MHz
RST#
I
PCI Reset. When the PCI Reset signal is asserted, all PCI output signals are floated
and all input signals are ignored.
Most of the internal state of the 82541ER is reset on the de-assertion (rising edge) of
RST#.
9
82541ER Gigabit Ethernet Controller
3.2.5
Error Reporting Signals (2)
Symbol
SERR#
PERR#
3.2.6
Name and Function
OD
System Error. The System Error signal is used by the 82541ER controller to report
address parity errors. SERR# is open drain and is actively driven for a single PCI clock
when reporting the error.
STS
Parity Error. The Parity Error signal is used by the 82541ER controller to report data
parity errors during all PCI transactions except by a Special Cycle. PERR# is sustained
tri-state and must be driven active by the 82541ER controller two data clocks after a
data parity error is detected. The minimum duration of PERR# is one clock for each
data phase a data parity error is present.
Power Management Signals (2)
Symbol
3.3
Type
Type
Name and Function
LAN_PWR
GOOD
I
Power Good (Power-on Reset). The Power Good signal is used to indicate that stable
power is available for the 82541ER. When the signal is low, the 82541ER holds itself in
reset state and floats all PCI signals.
AUX_PWR
I
Auxiliary Power. If the Auxiliary Power signal is high, then auxiliary power is available
and the 82541ER device should support the D3cold power state.
EEPROM and Serial FLASH Interface Signals (9)
Symbol
EEMODE
Type
I
Name and Function
EEPROM Mode. The EEPROM Mode pin is used to select the interface and
source of the EEPROM used to initialize the device. For a MIcrowire* EEPROM on
the standard EEPROM pins, tie this pin to ground with a 100 Ω pull-down resistor.
For a Serial Peripheral Interface (SPI*) EEPROM, leave this pin disconnected.
EEDI
O
EEDO
I
EEPROM Data Input. The EEPROM Data Input pin is used for output to the
memory device.
EEPROM Data Output. The EEPROM Data Output pin is used for input from the
memory device. The EEDO includes an internal pull-up resistor.
Note: Voltage for EEDO must be less than 0.7 V.
EECS
O
EEPROM Chip Select. The EEPROM Chip Select signal is used to enable the
device.
EESK
O
EEPROM Serial Clock. The EEPROM Shift Clock provides the clock rate for the
EEPROM interface, which is approximately 1 MHz for Microwire* and 2 MHZ for
SPI.
FLSH_CE#
O
Flash Chip Enable Output. Used to enable FLASH device.
FLSH_SCK
O
Flash Serial Clock Output. The clock rate of the serial FLASH interface is
approximately 1 MHz.
FLSH_SI
O
Flash Serial Data Input. This pin is an output to the memory device.
FLSH_SO/
LAN_DISABLE#
I
Flash Serial Data Output / LAN Disable. This pin is an input from the Flash
memory. Alternatively, the pin can be used to disable the LAN port from a system
General Purpose Input Output (GPIO) port. It has an internal pullup device. If the
82541ER is not using Flash functionality, the pin should be connected to an
external pull-up resistor.
If this pin is used as LAN_DISABLE#, the device goes to low power state and the
LAN port is disabled when this pin is sampled low on rising edge of PCI reset.
10
82541ER Gigabit Ethernet Controller
3.4
Miscellaneous Signals
3.4.1
LED Signals (4)
Symbol
3.4.2
Type
Name and Function
LINK_LED#
O
LED0 / LINK Up. Programmable LED indication. Defaults to indicate link
connectivity.
ACTIVITY#
O
LED1 / Activity. Programmable LED indication. Defaults to flash to indicate
transmit or receive activity.
LINK100#
O
LED2 / LINK 100. Programmable LED indication. Defaults to indicate link at
100 Mbps.
LINK1000#
O
LED3 / LINK 1000. Programmable LED indication. Defaults to indicate link at
1000 Mbps.
Other Signals (4)
Symbol
SDP[3:0]
Type
TS
Name and Function
Software Defined Pin. The Software Defined Pins are reserved and programmable
with respect to input and output capability. These default to input signals upon powerup but may be configured differently by the EEPROM. The upper four bits may be
mapped to the General Purpose Interrupt bits if they are configured as input signals.
3.5
PHY Signals
3.5.1
Crystal Signals (2)
Symbol
Type
Name and Function
XTAL1
I
Crystal One. The Crystal One pin is a 25 MHz +/- 50 ppm input signal. It should be
connected to a crystal, and the other end of the crystal should connect to XTAL2.
XTAL2
O
Crystal Two. Crystal Two is the output of an internal oscillator circuit used to drive a
crystal into oscillation.
11
82541ER Gigabit Ethernet Controller
3.5.2
Analog Signals (10)
Symbol
Type
Name and Function
Media Dependent Interface [0].
1000BASE-T: In MDI configuration, MDI[0]+/- corresponds to BI_DA+/-, and in MDI-X
configuration, MDI[0]+/- corresponds to BI_DB+/-.
MDI[0]+/-
A
100BASE_TX: In MDI configuration, MDI[0]+/- is used for the transmit pair, and in
MDI-X configuration, MDI[0]+/- is used for the receive pair.
10BASE-T: In MDI configuration, MDI[0]+/- is used for the transmit pair, and in MDI-X
configuration, MDI[0]+/- is used for the receive pair.
Media Dependent Interface [1].
1000BASE-T: In MDI configuration, MDI[1]+/- corresponds to BI_DB+/-, and in MDI-X
configuration, MDI[1]+/- corresponds to BI_DA+/-.
MDI[1]+/-
A
100BASE_TX: In MDI configuration, MDI[1]+/- is used for the receive pair, and in
MDI-X configuration, MDI[1]+/- is used for the transit pair.
10BASE-T: In MDI configuration, MDI[1]+/- is used for the receive pair, and in MDI-X
configuration, MDI[1]+/- is used for the transit pair.
Media Dependent Interface [2].
MDI[2]+/-
A
1000BASE-T: In MDI configuration, MDI[2]+/- corresponds to BI_DC+/-, and in MDI-X
configuration, MDI[2]+/- corresponds to BI_DD+/-.
100BASE_TX: Unused.
10BASE-T: Unused.
Media Dependent Interface [3].
MDI[3]+/-
A
1000BASE-T: In MDI configuration, MDI[3]+/- corresponds to BI_DC+/-, and in MDI-X
configuration, MDI[3]+/- corresponds to BI_DD+/-.
100BASE_TX: Unused.
10BASE-T: Unused.
3.6
IEEE_TEST-
A
IEEE test pin output minus. Used to gain access to the internal PHY clock for
1000BASE-T IEEE physical layer conformance testing.
IEEE_TEST+
A
Analog test pin output plus. Used to gain access to the internal PHY clock for
1000BASE-T IEEE physical layer conformance testing.
Test Interface Signals (6)
Symbol
12
Type
Name and Function
Test Enable. Enables test mode.
TEST
I
JTAG_TCK
I
JTAG Test Access Port Clock.
JTAG_TDI
I
JTAG Test Access Port Data In.
JTAG_TDO
O
JTAG Test Access Port Data Out.
JTAG_TMS
I
JTAG Test Access Port Mode Select.
JTAG_TRST#
I
JTAG Test Access Port Reset. This is an active low reset signal for JTAG.
To disable the JTAG interface, this signal should be terminated using a
100 Ω pull-down resistor to ground. It must not be left unconnected.
Normal mode: connect to VSS.
82541ER Gigabit Ethernet Controller
3.7
Power Supply Connections
3.7.1
Digital and Analog Supplies
Symbol
3.7.2
Type
3.3V
P
3.3 V I/O Power Supply.
Analog_1.8V
P
1.8V Analog Power Supply.
CLKR_1.8V
P
1.8V analog power supply for the clock recovery.
XTAL_1.8V
P
Input power for the XTAL regulator.
1.2V
P
1.2V Power supply. This is for analog and digital circuits.
Analog_1.2V
P
1.2V Analog Power Supply.
PLL_1.2V
P
Input power for the ICS regulator.
Grounds, Reserved Pins and No Connects
Symbol
3.7.3
Name and Function
Type
Name and Function
VSS
P
Ground.
AVSS
P
Shared analog Ground.
RSVD_VSS
P
Reserved Ground. This pin is reserved by Intel and may have factory test functions.
For normal operation, connect to ground.
RSVD_NC
P
Reserved No connect. This pin is reserved by Intel and may have factory test
functions. For normal operation, do not connect any circuit to these pins. Do not
connect pull-up or pull-down resistors.
NC
P
No Connect. This pin is not connected internally.
RSVD_VCC
P
Reserved VCC. This pin is reserved by Intel and may have factory test functions. For
normal operation, connect to VCC through a 1K pull-up resistor
Voltage Regulation Control Signals (2)
Symbol
Type
Name and Function
CTRL12
A
1.2V Control. LDO voltage regulator output to drive external PNP pass transistor. If
1.2V is already present in the system, leave output unconnected. To achieve optimal
D3 power consumption, leave the output unconnected and use a high-efficiency
external switching regulator.
CTRL18
A
1.8V Control. LDO voltage regulator output to drive external PNP pass transistor. If
1.8V is already present in the system, leave output unconnected. To achieve optimal
D3 power consumption, leave the output unconnected and use a high-efficiency
external switching regulator.
13
82541ER Gigabit Ethernet Controller
Note:
14
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82541ER Gigabit Ethernet Controller
4.0
Voltage, Temperature, and Timing Specifications
4.1
Absolute Maximum Ratings
Table 1.
Absolute Maximum Ratingsa
Symbol
Parameter
Min
Max
Unit
VDD (3.3)
DC supply voltage on 3.3 V pins
with respect to VSS
VSS - 0.5
4.6
V
VDD (1.8)
DC supply voltage on 1.8 V pins
with respect to VSS
VSS - 0.5
2.5 or
VDD (1.8) + 0.5b
V
VDD (1.2)
DC supply voltage on 1.2V pins
with respect to VSS
VSS - 0.5
1.7 or
VDD (1.2) + 0.5c
V
VDD
DC supply voltage
VSS - 0.5
4.6
V
VI / VO
LVTTL input voltage
VSS - 0.5
4.6d
V
IO
Output current
40
mA
TSTG
Storage temperature range
125
°C
VDD overstress:
VDD (3.3) * 7.2
V
-40
ESD per MIL_STD-883 Test
Method 3015, Specification 2001V
Latchup Over/Undershoot: 150
mA, 125 C
a. Maximum ratings are referenced to ground (VSS). Permanent device damage is likely to occur if the ratings in this table are
exceeded. These values should not be used as the limits for normal device operations.
b. The maximum value is the lesser value of 2.5V or VDD (2.5) + 0.5 V. This specification applies to biasing the device to a steady
state for an indefinite duration.
c. The maximum value is the lesser value of 1.7 V or VDD (2.5) + 0.5 V.
d. The maximum value must also be less than VIO.
4.2
Targeted Recommended Operating Conditions
4.2.1
General Operating Conditions
Table 2.
Recommended Operating Conditions (Sheet 1 of 2)a
Symbol
VDD (3.3)
Parameter
DC supply voltage on 3.3 V pins
Min
Max
Unit
3.0
3.6
V
b
c
VDD (1.8)
DC supply voltage on 1.8 V pins
1.71
1.89
V
VDD (1.2)
DC supply voltage on 1.2 V pins
1.14d
1.26e
V
VIO
PCI bus reference voltage
3.0
5.25
V
tR / tF
Input rise/fall time (normal input)
0
200
ns
15
82541ER Gigabit Ethernet Controller
Table 2.
Recommended Operating Conditions (Sheet 2 of 2)a
Symbol
Parameter
Min
Max
Unit
tr/tf
input rise/fall time (Schmitt input)
0
10
ms
TA
Operating temperature range
(ambient)
0
70
°C
TJ
Junction temperature
≤125
°C
a. Sustained operation of the device at conditions exceeding these values, even if they are within the absolute maximum rating
limits, might result in permanent damage.
b. The value listed in this table is for external voltage regulation. If the internal voltage regulator is used, the minimum value is
1.67 V.
c. The value listed in this table is for external voltage regulation. If the internal voltage regulator is used, the maximum value is
1.926 V.
d. The value listed in this table is for external voltage regulation. If the internal voltage regulator is used, the minimum value is
1.12 V.
e. The value listed in this table is for external voltage regulation. If the internal voltage regulator is used, the maximum value is
1.284 V.
4.2.2
Voltage Ramp and Sequencing Recommendations
Note:
Table 3.
In any case or time period (greater than 1 ns), the supply voltage should comply with 3.3V > 1.8V
> 1.2V. This is important to avoid stress in the ESD protection circuits. After 3.3V reaches 10% of
its final value, all voltage rails (1.8V and 1.2V) have 150 ms to reach their final operating values.
3.3V Supply Voltage Ramp
Parameter
Table 4.
Description
Min
Max
Unit
Rise Time
Time from 10% to 90% mark
0.1
100
ms
Monotonicity
Voltage dip allowed in ramp
0
mV
Slope
Ramp rate at any time between 10% to 90%
28800
V/s
Operational
Range
Voltage range for normal operating conditions
3.6
V
Ripple
Maximum voltage ripple at a bandwidth equal
to 50 MHz
70
mV
Overshoot
Maximum voltage allowed
4
V
1.8V Supply Voltage Ramp
Symbol
16
3
Parameter
Min
Max
Unit
Rise Time
Time from 10% to 90% mark
0.1
100
ms
Monotonicity
Voltage dip allowed in ramp
0
mV
Slope
Ramp rate at any time between 10% to 90%
57600
V/s
Operational
Range
Voltage range for normal operating conditions
(PNP’s)a
1.674
1.89
V
Operational
Range
Voltage range for normal operating conditions
(PNP’s)
-7
5
%
Operational
Range
Voltage range for normal operating conditions
(external regulator)
1.71
1.89
V
Operational
Range
Voltage range for normal operating conditions
(external regulator)
-5
5
%
82541ER Gigabit Ethernet Controller
Table 4.
1.8V Supply Voltage Ramp
Ripple
Maximum voltage ripple at a bandwidth equal
to 50 MHz
20
mV
Overshoot
Maximum voltage allowed
2.2
V
Output
Capacitance
Capacitance range when using PNP circuit
4.7
20
µF
Input
Capacitance
Capacitance range when using PNP circuit
4.7
20
µF
Capacitance
ESR
Equivalent series resistance of output
capacitanceb
5
100
mΩ
Ictrl_18
Maximum output current rating to CTRL18
20
mA
a. Operating with an internal regulator (PNP) supports a wider tolerance output voltage due to process tracking.
b. Tantalum capacitors must not be used.
Table 5.
1.2V Supply Voltage Ramp
Symbol
Parameter
Min
Max
Unit
0
mV
38400
V/s
Rise Time
Time from 10% to 90% mark
Monotonicity
Voltage dip allowed in ramp
0.025
ms
Slope
Ramp rate at any time between 10% to 90%
Operational
Range
Voltage range for normal operating conditions
(PNP’s)a
1.116
1.26
V
Operational
Range
Voltage range for normal operating conditions
(PNP’s)
-7
5
%
Operational
Range
Voltage range for normal operating conditions
(external regulator)
1.14
1.26
V
Operational
Range
Voltage range for normal operating conditions
(external regulator)
-5
5
%
Ripple
Maximum voltage ripple at a bandwidth equal
to 50 MHz
20
mV
Overshoot
Maximum voltage allowed
1.45
V
Output
Capacitance
Capacitance range when using PNP circuit
4.7
20
µF
Input
Capacitance
Capacitance range when using PNP circuit
4.7
20
µF
Capacitance
ESR
Equivalent series resistance of output
capacitanceb
5
100
mΩ
Ictrl_12
Maximum output current rating to CTRL_12
20
mA
a. Operating with an internal regulator (PNP) supports a wider tolerance output voltage due to process tracking.
b. Tantalum capacitors must not be used.
17
82541ER Gigabit Ethernet Controller
4.3
Table 6.
DC Specifications
DC Characteristics
Symbol
Parameter
VDD (3.3)
Condition
Min
Typ
Max
Units
DC supply voltage on 3.3 V
pins
3.00
3.3
3.60
V
VDD (1.8)
DC supply voltage on 1.8 V
pins
1.71a
1.8
1.89b
V
VDD (1.2)
DC supply voltage on 1.2 V
pins
1.14c
1.2
1.26d
V
a. The value listed in this table is for external voltage regulation. If the internal voltage regulator is used, the minimum value is
1.67 V.
b. The value listed in this table is for external voltage regulation. If the internal voltage regulator is used, the maximum value is
1.926 V.
c. The value listed in this table is for external voltage regulation. If the internal voltage regulator is used, the minimum value is
1.12 V.
d. The value listed in this table is for external voltage regulation. If the internal voltage regulator is used, the maximum value is
1.284 V.
Table 7.
Power Specifications - D0a
D0a
unplugged no link
@10 Mbps
@100 Mbps
@ 1000 Mbps
Typ Icc
(mA)a
Max Icc
(mA)b
Typ Icc
(mA)a
Max Icc
(mA)b
Typ Icc
(mA)a
Max Icc
(mA)b
Typ Icc
(mA)a
Max Icc
(mA)b
3.3V
3
5
5
10
13
15
30
40
1.8V
14
15
85
85
110
115
315
320
1.2V
30
35
85
90
90
100
380
400
Total
Device
Power
75 mW
1.1 W
1.2 W
270 mW
355 mW
a. Typical conditions: operating temperature (TA) = 25 C, nominal voltages, moderate network traffic at full duplex,
and PCI 33 MHz system interface.
b. Maximum conditions: minimum operating temperature (TA) values, maximum voltage values, continuous network
traffic at full duplex, and PCI 33 MHz system interface.
Table 8.
Power Specifications - D3cold
D3cold - wake-up enableda
unplugged link
3.3V
18
@10 Mbps
@100 Mbps
D3cold-wake
disabled
Typ Icc
(mA)b
Max Icc
(mA)c
Typ Icc
(mA)a
Max Icc
(mA)b
Typ Icc
(mA)a
Max Icc
(mA)b
Typ Icc
(mA)a
Max Icc
(mA)b
2
3
2
3
2
3
4
5
82541ER Gigabit Ethernet Controller
Table 8.
Power Specifications - D3cold
D3cold - wake-up enableda
unplugged link
@10 Mbps
D3cold-wake
disabled
@100 Mbps
Typ Icc
(mA)b
Max Icc
(mA)c
Typ Icc
(mA)a
Max Icc
(mA)b
Typ Icc
(mA)a
Max Icc
(mA)b
Typ Icc
(mA)a
Max Icc
(mA)b
1.8V
14
15
20
25
110
115
1
2
1.2V
21
25
30
35
80
85
7
10
Total
Device
Power
60 mW
80 mW
305 mW
25 mW
a. The power consumption for 1000 Mbps is not shown since the controller moves to the 10/100 Mbps mode before
going into the D3 state to conserve power.
b. Typical conditions: operating temperature (TA) = 25 C, nominal voltages, moderate network traffic at full duplex,
and PCI 33 MHz system interface.
c. Maximum conditions: minimum operating temperature (TA) values, maximum voltage values, continuous network
traffic at full duplex, and PCI 33 MHz system interface.
Table 9.
Power Specifications D(r) Uninitialized)
D(r) Uninitialized (FLSH_SO/LAN_DISABLE # = 0)
Typ Icc (mA)
Max Icc (mA)
3.3V
5
10
1.8V
1
2
1.2V
12
15
Total
Device
Power
35 mW
Table 10. Power Specifications - Complete Subsystem
Complete Subsystem (Reference Design) Including Magnetics, LED, Regulator Circuits
D3cold - wake
disabled
3.3 V
D3cold wakeenabled @
10 Mbps
Typ Icc
(mA)a
Max
Icc
(mA)b
Typ Icc
(mA)a
Max
Icc
(mA)b
4
5
7
10
D0 @10 Mbps
active
Typ Icc
(mA)a
Max
Icc
(mA)b
D0 @100 Mbps
active
D0 @
1000 Mbps
active
Typ Icc
(mA)a
Max
Icc
(mA)b
Typ Icc
(mA)a
Max
Icc
(mA)b
12
15
33
45
19
82541ER Gigabit Ethernet Controller
Table 10. Power Specifications - Complete Subsystem
Complete Subsystem (Reference Design) Including Magnetics, LED, Regulator Circuits
D3cold - wake
disabled
D3cold wakeenabled @
10 Mbps
Typ Icc
(mA)a
Max
Icc
(mA)b
Typ Icc
(mA)a
Max
Icc
(mA)b
1
7
2
1.2 V
7
10
Subsystem
3.3V
Current
10
1.8 V
D0 @10 Mbps
active
Typ Icc
(mA)a
Max
Icc
(mA)b
Typ Icc
(mA)a
Max
Icc
(mA)b
30
35
135
140
410
30
35
80
85
380
Typ Icc
(mA)a
Max
Icc
(mA)b
D0 @
1000 Mbps
active
D0 @100 Mbps
active
40
120
710
a. Typical conditions: operating temperature (TA) = 25 C, nominal voltages, moderate network traffic at full duplex, and PCI 33 MHz
system interface.
b. Maximum conditions: minimum operating temperature (TA) values, maximum voltage values, continuous network traffic at full duplex, and PCI 33 MHz system interface.
Table 11. I/O Characteristics (Sheet 1 of 2)
Symbol
Parameter
Condition
Min
Max
Units
VIH
Input high voltage
3.3 V PCI
0.5 * VDD(3.3)
VDD(3.3) or
VIO
V
VIL
Input low voltage
3.3 V PCIa
VSS
0.3 * VDD(3.3)
V
Input current
0 < VIN < VDD(3.3)
-10
10
Input with pulldown resistor (50
KΩ)
VIN = VDD(3.3)
28
191
Inputs with pull-up
resistor (50 KΩ)
VIN = VSS
-28
-191
IIN
3.3 V PCI
IOL
Output low
current
0 ≤ VOUT ≤ 1.3V
100 * VOUT
IOH
VOH
5.7 * VOUT+ 55
-74 * (VDD VOUT)
0 ≤ (VDD-VOUT) ≤
1.2V
-32 * (VDD VOUT)
1.2V ≤ (VDD-VOUT) ≤
1.9V
-11 * (VDD VOUT)-25.2
1.9V ≤ (VDD-VOUT) ≤
3.6V
-1.8 * (VDD VOUT)-42.7
Output high
voltage:
3.3 V PCI
mA
48 * VOUT
0 ≤ (VDD-VOUT) ≤
3.6V
Output high
current:
µA
2.09
0 ≤ VOUT ≤ 3.6V
1.3V ≤ VOUT ≤ 3.6V
20
Typ
mA
V
IOH = -500 mA
0.9 * VDD(3.3)
82541ER Gigabit Ethernet Controller
Table 11. I/O Characteristics (Sheet 2 of 2) (Continued)
Symbol
VOL
Parameter
Condition
Min
Typ
Max
Units
Output low
voltage:
V
3.3 V PCI
IOL = 1500 mA
IOZ
Off-state output
leakage current
VO = VDD or VSS
IOS
Output short
circuit current
CIN
Input
capacitanceb
0.1 * VDD(3.3)
10
µA
-250
mA
-10
Input and bidirectional buffers
8
pF
a. The maximum VIL is 0.6 V for the following Pins: A13, C5, C8, J4, L7, L12, L13, M8, M12, M13, N10, N11, N13, N14, P9, and P13.
b. VDD (3.3) = 0 V; TA = 25 C; f = 1 Mhz
4.4
AC Characteristics
Table 12. AC Characteristics: 3.3 V Interfacing
Symbol
PCICLK
Parameter
Min
Typ
Clock frequency in PCI mode
Max
Unit
66
MHz
Table 13. 25 MHz Clock Input Requirements
Specifications
Symbol
Parameter
Units
Min
Typ
Max
f0
Frequency
25
df0
Frequency variation
-50
+30
Dc
Duty cycle
40
60
%
tr
Rise time
5
ns
tf
Fall time
5
ns
250
ps
70
°C
1.3
V
a
Jptp
Clock jitter (peak-to-peak)
Cin
Input capacitance
T
Operating temperature
Aptp
Input clock amplitude (peak-to-peak)
Vcm
Clock common mode
MHz
20
1.0
1.2
0.6
ppm
pF
V
a. Clock jitter is defined according to the recommendations of part 40.6.1.2.5 IEEE 1000BASE-T Standard (at least
105 clock edges, filtered by HPF with cut off frequency 5000 Hz).
21
82541ER Gigabit Ethernet Controller
Table 14. Reference Crystal Specification Requirements
Specification
Value
Vibrational Mode
Fundamental
Nominal Frequency
25.000 MHz at 25° C
Frequency Tolerance
±30 ppm
Temperature Stability
±30 ppm at 0° C to 70° C
Calibration Mode
Parallel
Load Capacitance
20 pF to 24 pF
Shunt Capacitance
6 pF maximum
Series Resistance, Rs
50 W maximum
Drive Level
0.5 mW maximum
Aging
±5.0 ppm per year maximum
Insulation Resistance
500 MΩ at DC 100 V
Table 15. Link Interface Clock Requirements
Symbol
fGTX
a
Parameter
Min
GTX_CLK frequency
Typ
Max
125
Unit
MHz
a. GTX_CLK is used externally for test purposes only.
Table 16. EEPROM Interface Clock Requirements
Symbol
Parameter
Min
Typ
Max
Unit
Microwire EEPROM Clock
1
MHz
SPI EEPROM Clock
2
MHz
fSK
Table 17. AC Test Loads for General Output Pins
Symbol
22
Signal Name
Value
Units
CL
TDO
10
pF
CL
SDP[3:0]
16
pF
CL
EEDI, EESK
18
pF
CL
LED[3:0]
20
pF
82541ER Gigabit Ethernet Controller
CL
Figure 2. AC Test Loads for General Output Pins
4.5
Timing Specifications
4.5.1
PCI Bus Interface
4.5.1.1
PCI Bus Interface Clock
Table 18. PCI Bus Interface Clock Parameters
PCI 66 MHz
PCI 33 MHz
Parametera
Symbol
Units
Min
Max
Min
30
30
ns
11
ns
TCYC
CLK cycle time
15
TH
CLK high time
6
TL
CLK low time
6
CLK slew rate
1.5
RST# slew rateb
50
Max
11
4
1
ns
4
V/ns
50
mV/ns
a. Rise and fall times are specified in terms of the edge rate measured in V/ns. This slew rate must be met across the
minimum peak-to-peak portion of the clock waveform as shown.
b. The minimum RST# slew rate applies only to the rising (de-assertion) edge of the reset signal and ensures that system
noise cannot render a monotonic signal to appear bouncing in the switching range.
Tcyc
3.3 V Clock
Th
0.6 Vcc
0.5 Vcc
0.4 Vcc p-to-p
(minimum)
0.4 Vcc
0.3 Vcc
0.2 Vcc
Tl
PCI Clock Timing.vsd
Figure 3. PCI Clock Timing
23
82541ER Gigabit Ethernet Controller
4.5.1.2
PCI/PCI-X Bus Interface Timing
Table 19. PCI Bus Interface Timing Parameters
PCI 66MHz
Symbol
PCI 33 MHz
Parameter
Units
Min
Max
Min
Max
TVAL
CLK to signal valid delay: bussed
signals
2
6
2
11
ns
TVAL(ptp)
CLK to signal valid delay: pointto-point signals
2
6
2
12
ns
TON
Float to active delay
2
TOFF
Active to float delay
TSU
Input setup time to CLK: bussed
signals
3
7
ns
TSU(ptp)
Input setup time to CLK: point-topoint signals
5
10, 12
ns
TH
Input hold time from CLK
0
0
ns
2
14
ns
28
ns
NOTES:
1. Output timing measurements are as shown.
2. REQ# and GNT# signals are point-to-point and have different output valid delay and input setup times than
bussed signals. GNT# has a setup of 10 ns; REQ# has a setup of 12 ns. All other signals are bussed.
3. Input timing measurements are as shown.
VTH
PCI_CLK
VTEST
VTL
Output
Delay
VTEST
VSTEP (3.3V Signalling)
output current ≤ leakage current
Tri-State
Output
TON
TOFF
Figure 4. PCI Bus Interface Output Timing Measurement
24
82541ER Gigabit Ethernet Controller
VTH
PCI_CLK
VTEST
VTL
TSU
TH
VTH
Input
Input
Valid
VTEST
VMAX
VTEST
VTL
Figure 5. PCI Bus Interface Input Timing Measurement Conditions
Table 20. PCI Bus Interface Timing Measurement Conditions
Symbol
Parameter
PCI 66 MHz
3.3 v
Unit
0.6 * VCC
V
VTH
Input measurement test voltage (high)
VTL
Input measurement test voltage (low)
0.2 * VCC
V
VTEST
Output measurement test voltage
0.4 * VCC
V
1.5
V/ns
Input signal slew rate
Pin
Test
Point
1/2 inch max.
25Ω
10 pF
Figure 6. TVAL (max) Rising Edge Test Load
25
82541ER Gigabit Ethernet Controller
Pin
Test
Point
1/2 inch max.
25Ω
10 pF
VCC
Figure 7. TVAL (max) Falling Edge Test Load
Figure 8. TVAL (min) Test Load
Pin
1/2 inch max.
Test
Point
50 pF
Figure 9. TVAL Test Load (PCI 5 V Signaling Environment)
NOTE: Note: 50 pF load used for maximum times. Minimum times are specified with 0 pF load.
26
82541ER Gigabit Ethernet Controller
4.5.2
Link Interface Timing
Table 21. Rise and Fall Times
Symbol
Parameter
Condition
Min
Max
Unit
TR
Clock rise time
0.8 V to 2.0 V
0.7
ns
TF
Clock fall time
2.0 V to 0.8 V
0.7
ns
TR
Data rise time
0.8 to 2.0 V
0.7
ns
TF
Data fall time
2.0 V to 0.8 V
0.7
ns
2.0 V
0.8 V
TR
TF
Figure 10. Link Interface Rise/Fall Timing
4.5.3
EEPROM Interface
Table 22. Link Interface Clock Requirements
Symbol
Parametera
Min
Typ
Max
TPERIOD x
64
Microwire EESK pulse width
Unit
ns
TPW
TPERIOD x
SPI EESK pulse width
ns
32
a. The EEPROM clock is derived from a 125 MHz internal clock.
Table 23. Link Interface Clock Requirements
Symbol
Parametera
Min
Typ
Max
Unit
TDOS
EEDO setup time
TCYC*2
ns
TDOH
EEDO hold time
0
ns
a. The EE_DO setup and hold time is a function of the PCI bus clock cycle time but is referenced to O_EE_SK.
27
82541ER Gigabit Ethernet Controller
Note:
28
This page is intentionally left blank.
82541ER Gigabit Ethernet Controller
5.0
Package and Pinout Information
This section describes the device physical characteristics. The pin number-to-signal mapping is
indicated beginning with Table 25.
5.1
Package Information
The 82541ER device is a 196-lead plastic ball grid array (BGA) measuring 15 mm by 15 mm. The
package dimensions are detailed below. The nominal ball pitch is 1 mm.
1.56 +/-0.19
0.85
0.40 +/-0.10
30
o
Seating Plate
0.32 +/-0.04
Figure 11. 82541ER Mechanical Specifications
Note:
No changes to existing soldering processes are needed for the 0.32 mm substrate change.
29
82541ER Gigabit Ethernet Controller
Detail Area
0.45
Solder Resist Opening
0.60
Metal Diameter
Figure 12. 196 PBGA Package Pad Detail
As illustrated in Figure 12, the Ethernet controller package uses solder mask defined pads. The
copper area is 0.60 mm and the opening in the solder mask is 0.45mm. The nominal ball sphere
diameter is 0.50 mm.
30
82541ER Gigabit Ethernet Controller
5.2
Thermal Specifications
The 82541ER device is specified for operation when the ambient temperature (TA) is within the
range of 0° C to 70° C.
TC (case temperature) is calculated using the equation:
TC = TA + P (θJA - θJC)
TJ (junction temperature) is calculated using the equation:
TJ = TA + P θJA
P (power consumption) is calculated by using the typical ICC and nominal VCC. The preliminary
thermal resistances are shown in Table 24.
Table 24. Thermal Characteristics
Symbol
Parameter
θJA
Thermal resistance, junction-to-ambient
θJC
Thermal resistance, junction-to-case
Preliminary Value at specified
airflow (m/s)
Units
0
1
2
29
25.0
23.5
C/Watt
11.1
11.1
11.1
C/Watt
Thermal resistances are determined empirically with test devices mounted on standard thermal test
boards. Real system designs may have different characteristics due to board thickness, arrangement
of ground planes, and proximity of other components. The case temperature measurements should
be used to assure that the 82541ER device is operating under recommended conditions.
31
82541ER Gigabit Ethernet Controller
5.3
Pinout Information
Table 25. PCI Address, Data and Control Signals
Signal
Pin
Signal
Pin
Pin
AD[0]
N7
AD[16]
K1
C/BE#[0]
M4
AD[1]
M7
AD[17]
E3
C/BE#[1]
L3
AD[2]
P6
AD[18]
D1
C/BE#[2]
F3
AD[3]
P5
AD[19]
D2
C/BE#[3]
C4
AD[4]
N5
AD[20]
D3
PAR
J1
AD[5]
M5
AD[21]
C1
FRAME#
F2
AD[6]
P4
AD[22]
B1
IRDY#
F1
AD[7]
N4
AD[23]
B2
TRDY#
G3
AD[8]
P3
AD[24]
B4
STOP#
H1
AD[9]
N3
AD[25]
A5
DEVSEL#
H3
AD[10]
N2
AD[26]
B5
IDSEL
A4
AD[11]
M1
AD[27]
B6
VIO
G2
AD[12]
M2
AD[28]
C6
AD[13]
M3
AD[29]
C7
AD[14]
L1
AD[30]
A8
AD[15]
L2
AD[31]
B8
Table 26. PCI Arbitration Signals
Signal
Pin
REQ#
C3
GNT#
J3
Table 27. Interrupt Signals
Signal
INTA#
Pin
H2
Table 28. System Signals
Signal
32
Signal
Pin
CLK
G1
M66EN
C2
Signal
RST#
Pin
B9
82541ER Gigabit Ethernet Controller
Table 29. Error Reporting Signals
Signal
Pin
SERR#
Signal
A2
Pin
PERR#
J2
Table 30. Power Management Signals
Signal
Pin
LAN_PWR_GOOD
A9
AUX_PWR
J12
Table 31. Serial EEPROM Interface Signals
Signal
Pin
Signal
EESK
M10
EEDI
EEDO
N10
EEMODE
Pin
P10
Signal
EECS
Pin
P7
J4
Table 32. Serial FLASH Interface Signals
Signal
Pin
FLSH_SCK
N9
FLSH_SO/LAN_DISABLE#
P9
Signal
Pin
FLSH_SI
M11
Signal
FLSH_CE#
Pin
M9
Table 33. LED Signals
Signal
Pin
Signal
Pin
LINK_UP#
A12
LINK100#
B11
ACTIVITY#
C11
LINK1000#
B12
Table 34. Other Signals
Signal
Pin
Signal
Pin
SDP[0]
N14
SDP[2]
N13
SDP[1]
P13
SDP[3]
M12
33
82541ER Gigabit Ethernet Controller
Table 35. IEEE Test Signals
Signal
Pin
Signal
Pin
IEEE_TEST-
D14
IEEE_TEST+
B14
Table 36. PHY Signals
Signal
Pin
Signal
Pin
Signal
Pin
MDI[0]-
C14
MDI[2]-
F14
XTAL1
K14
MDI[0]+
C13
MDI[2]+
F13
XTAL2
J14
MDI[1]-
E14
MDI[3]-
H14
MDI[1]+
E13
MDI[3]+
H13
Table 37. Test Interface Signals
Signal
Pin
Signal
Pin
Signal
Pin
JTAG_TCK
L14
JTAG_TDO
M14
JTAG_TRST#
L13
JTAG_TDI
M13
JTAG_TMS
L12
TEST
A13
Table 38. Digital Power Signals
Signal
3.3V
34
Pin
A3
Signal
1.2V
Pin
G5
Signal
Pin
1.2V
J9
3.3V
A7
1.2V
G6
1.2V
K10
3.3V
A11
1.2V
H5
1.2V
K11
3.3V
E1
1.2V
H6
1.2V
K5
3.3V
K3
1.2V
H7
1.2V
K6
3.3V
K4
1.2V
H8
1.2V
K7
3.3V
K13
1.2V
J10
1.2V
K8
3.3V
N6
1.2V
J11
1.2V
K9
3.3V
N8
1.2V
J5
1.2V
L10
3.3V
P2
1.2V
J6
1.2V
L4
3.3V
P12
1.2V
J7
1.2V
L5
1.2V
J8
1.2V
L9
82541ER Gigabit Ethernet Controller
Table 39. Analog Power Signals
Signal
Pin
Signal
Pin
Signal
Pin
ANALOG_1.2V
E11
ANALOG_1.8V
D11
CLKR_1.8V
D12
ANALOG_1.2V
E12
ANALOG_1.8V
G12
XTAL_1.8V
J13
ANALOG_1.2V
G13
PLL_1.2V
G4
ANALOG_1.2V
H11
PLL_1.2V
H4
Table 40. Grounds and No Connect Signals
Signal
Pin
Signal
Pin
Signal
Pin
Signal
Pin
VSS
B3
VSS
F5
VSS
M6
NC
L8
VSS
B7
VSS
F6
VSS
N1
NC
P1
VSS
C10
VSS
F7
VSS
N12
NC
P14
A10
VSS
D5
VSS
F8
VSS
P8
Pull up to
VCCa
VSS
D6
VSS
F9
AVSS
C12
Pull up to
VCCa
B10
VSS
D7
VSS
F10
AVSS
D13
Pull up to
VCCa
C9
VSS
D8
VSS
G7
AVSS
F11
VSS
D4
VSS
E10
VSS
G8
AVSS
G11
VSS
E4
VSS
E2
VSS
G9
AVSS
G14
NC
A6
VSS
E5
VSS
G10
AVSS
K12
NC
C5
VSS
E6
VSS
H9
NC
A1
NC
F12
VSS
E7
VSS
H10
NC
A14
NC
L7
VSS
E8
VSS
K2
NC
D9
NC
M8
VSS
E9
VSS
L6
NC
D10
NC
N11
VSS
F4
VSS
L11
NC
H12
NC
C8
a. Use a 1 K Ω resistor.
Table 41. Voltage Regulation Control Signals
Signal
CTRL18
Pin
B13
Signal
CTRL12
Pin
P11
35
82541ER Gigabit Ethernet Controller
Table 42. Signal Names in Pin Order (Sheet 1 of 6)
Signal Name
NC
A1
SERR#
A2
3.3V
A3
IDSEL
A4
AD[25]
A5
NC
A6
3.3V
A7
AD[30]
A8
LAN_PWR_GOOD
A9
Pull up to VCCa
A10
3.3V
A11
LINK_LED#
A12
TEST
A13
NC
A14
AD[22]
B1
AD[23]
B2
VSS
B3
AD[24]
B4
AD[26]
B5
AD[27]
B6
VSS
B7
AD[31]
B8
RST#
Pull up to VCC
36
Pin
B9
a
B10
LINK100#
B11
LINK1000#
B12
CTRL18
B13
IEEE_TEST+
B14
AD[21]
C1
M66EN
C2
REQ#
C3
C/BE#[3]
C4
NC
C5
AD[28]
C6
82541ER Gigabit Ethernet Controller
Table 42. Signal Names in Pin Order (Sheet 2 of 6) (Continued)
AD[29]
C7
NC
C8
Pull up to VCCa
C9
VSS
C10
ACTIVITY#
C11
AVSS
C12
MDI[0]+
C13
MDI[0]-
C14
AD[18]
D1
AD[19]
D2
AD[20]
D3
VSS
D4
VSS
D5
VSS
D6
VSS
D7
VSS
D8
NC
D9
NC
D10
ANALOG_1.8V
D11
CLKR_1.8V
D12
AVSS
D13
IEEE_TEST-
D14
3.3V
E1
VSS
E2
AD[17]
E3
VSS
E4
VSS
E5
VSS
E6
VSS
E7
VSS
E8
VSS
E9
VSS
E10
ANALOG_1.2V
E11
ANALOG_1.2V
E12
MDI[1]+
E13
MDI[1]-
E14
37
82541ER Gigabit Ethernet Controller
Table 42. Signal Names in Pin Order (Sheet 3 of 6) (Continued)
38
IRDY#
F1
FRAME#
F2
C/BE#[2]
F3
VSS
F4
VSS
F5
VSS
F6
VSS
F7
VSS
F8
VSS
F9
VSS
F10
AVSS
F11
NC
F12
MDI[2]+
F13
MDI[2]-
F14
CLK
G1
VIO
G2
TRDY#
G3
PLL_1.2V
G4
1.2V
G5
1.2V
G6
VSS
G7
VSS
G8
VSS
G9
VSS
G10
AVSS
G11
ANALOG_1.8V
G12
ANALOG_1.2V
G13
AVSS
G14
STOP#
H1
INTA#
H2
DEVSEL#
H3
PLL_1.2V
H4
1.2V
H5
1.2V
H6
1.2V
H7
1.2V
H8
VSS
H9
82541ER Gigabit Ethernet Controller
Table 42. Signal Names in Pin Order (Sheet 4 of 6) (Continued)
VSS
H10
ANALOG_1.2V
H11
NC
H12
MDI[3]+
H13
MDI[3]-
H14
PAR
J1
PERR#
J2
GNT#
J3
EEMODE
J4
1.2V
J5
1.2V
J6
1.2V
J7
1.2V
J8
1.2V
J9
1.2V
J10
1.2V
J11
AUX_PWR
J12
XTAL_1.8V
J13
XTAL2
J14
AD[16]
K1
VSS
K2
3.3V
K3
3.3V
K4
1.2V
K5
1.2V
K6
1.2V
K7
1.2V
K8
1.2V
K9
1.2V
K10
1.2V
K11
AVSS
K12
3.3V
K13
XTAL1
K14
AD[14]
L1
AD[15]
L2
C/BE#[1]
L3
1.2V
L4
39
82541ER Gigabit Ethernet Controller
Table 42. Signal Names in Pin Order (Sheet 5 of 6) (Continued)
40
1.2V
L5
VSS
L6
NC
L7
NC
L8
1.2V
L9
1.2V
L10
VSS
L11
JTAG_TMS
L12
JTAG_TRST#
L13
JTAG_TCK
L14
AD[11]
M1
AD[12]
M2
AD[13]
M3
C/BE#[0]#
M4
AD[5]
M5
VSS
M6
AD[1]
M7
NC
M8
FLSH_CE#
M9
EESK
M10
FLSH_SI
M11
SDP[3]
M12
JTAG_TDI
M13
JTAG_TDO
M14
VSS
N1
AD[10]
N2
AD[9]
N3
AD[7]
N4
AD[4]
N5
3.3V
N6
AD[0]
N7
3.3V
N8
FLSH_SCK
N9
EEDO
N10
NC
N11
VSS
N12
SDP[2]
N13
82541ER Gigabit Ethernet Controller
Table 42. Signal Names in Pin Order (Sheet 6 of 6) (Continued)
SDP[0]
N14
NC
P1
3.3V
P2
AD[8]
P3
AD[6]
P4
AD[3]
P5
AD[2]
P6
EECS
P7
VSS
P8
FLSH_SO
P9
EEDI
P10
CTRL12
P11
3.3V
P12
SDP[1]
P13
NC
P14
a. Use a 1 K Ω resistor.
41
82541ER Gigabit Ethernet Controller
5.4
Visual Pin Assignments
A
B
1
NC
AD[22]
2
SERR#
AD[23]
3
3.3V
VSS
4
IDSEL
AD[24]
5
AD[25]
6
NC
7
8
AD[18]
E
3.3V
F
G
H
J
IRDY#
CLK
STOP#
PAR
PERR#
L
M
N
P
AD[16]
AD[14]
AD[11]
VSS
NC
VSS
AD[15]
AD[12]
AD[10]
3.3V
3.3V
C/B3#[1]
AD[13]
AD[9]
AD[8]
3.3V
1.2V
C/BE#[0]
AD[7]
AD[6]
1.2V
AD[5]
AD[4]
AD[3]
VSS
VSS
3.3V
AD[2]
VSS
FRAME#
VIO
INTA#
REQ#
AD[20]
AD[17]
C/BE#[2]
TRDY#
DVSEL#
C/BE#[3]
VSS
VSS
VSS
PLL_1.2V
PLL_1.2V
AD[26]
NC
VSS
VSS
VSS
1.2V
AD[27]
AD[28]
VSS
VSS
VSS
1.2V
1.2V
1.2V
3.3V
VSS
AD[29]
VSS
VSS
VSS
VSS
1.2V
1.2V
1.2V
NC
AD[1]
AD[0]
EECS
AD[30]
AD[31]
NC
VSS
VSS
VSS
VSS
1.2V
1.2V
1.2V
NC
NC
3.3V
VSS
NC
VSS
VSS
VSS
VSS
1.2V
1.2V
1.2V
FLSH_CE#
NC
VSS
VSS
VSS
VSS
1.2V
1.2V
1.2V
EESK
AVSS
1.2V
VSS
FLSH_SI
10
Pull Up To
VCC
3.3V
LINK_LED#
RST#
Pull Up To
VCC
LINK100#
LINK1000#
13
TEST
CTRL18
14
NC
IEEE_TEST+
Pull Up To
VCC
VSS
1.2V
ANALOG_
1.8V
ANALOG_
1.2V
AVSS
AVSS
CLKR_
1.8V
ANALOG_
1.2V
NC
ANALOG_
1.8V
NC
MDI[0]+
AVSS
MDI[1]+
MDI[2]+
ANALOG_
1.2V
MDI[3]+
MDI[1]-
MDI[2]-
AVSS
MDI[3]-
ACTIVITY#
MDI[0]-
IEEE_TEST-
Pins A10, B-10, and C9 - Use 1K ohm resistors.
Figure 13. Visual Pin Assignments
42
K
AD[19]
LAN_PWR_
GOOD
12
AD[21]
D
M66EN
9
11
C
ANALOG_
1.2V
GNT#
EEMODE
1.2V
1.2V
AUX_PWR
1.2V
1.2V
AVSS
JTAG_TMS
SDP[3]
XTAL_1.8V
3.3V
JTAG_TRST#
JTAG_TDI
XTAL2
XTAL1
JTAG_TCK
JTAG_TDO
FLSH_SCK
EEDO
NC
VSS
SDP[2]
SDP[0]
FLSH_SO
EEDI
CTRL12
3.3V
SDP[1]
NC
82541ER Gigabit Ethernet Controller
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
Absolute Maximum Ratings ................................................................................ 15
Recommended Operating Conditions ................................................................ 15
3.3V Supply Voltage Ramp................................................................................. 16
1.8V Supply Voltage Ramp................................................................................. 16
1.2V Supply Voltage Ramp................................................................................. 17
DC Characteristics.............................................................................................. 18
Power Specifications - D0a................................................................................. 18
Power Specifications - D3cold ............................................................................ 18
Power Specifications D(r) Uninitialized).............................................................. 19
Power Specifications - Complete Subsystem ..................................................... 19
I/O Characteristics .............................................................................................. 20
AC Characteristics: 3.3 V Interfacing.................................................................. 21
25 MHz Clock Input Requirements ..................................................................... 21
Reference Crystal Specification Requirements .................................................. 22
Link Interface Clock Requirements..................................................................... 22
EEPROM Interface Clock Requirements............................................................ 22
AC Test Loads for General Output Pins ............................................................. 22
PCI Bus Interface Clock Parameters .................................................................. 23
PCI Bus Interface Timing Parameters ................................................................ 24
PCI Bus Interface Timing Measurement Conditions........................................... 25
Rise and Fall Times ............................................................................................ 27
Link Interface Clock Requirements..................................................................... 27
Link Interface Clock Requirements..................................................................... 27
Thermal Characteristics...................................................................................... 31
PCI Address, Data and Control Signals.............................................................. 32
PCI Arbitration Signals........................................................................................ 32
Interrupt Signals.................................................................................................. 32
System Signals ................................................................................................... 32
Error Reporting Signals ...................................................................................... 33
Power Management Signals............................................................................... 33
Serial EEPROM Interface Signals ...................................................................... 33
Serial FLASH Interface Signals .......................................................................... 33
LED Signals ........................................................................................................ 33
Other Signals ...................................................................................................... 33
IEEE Test Signals............................................................................................... 34
PHY Signals........................................................................................................ 34
Test Interface Signals ......................................................................................... 34
Digital Power Signals.......................................................................................... 34
Analog Power Signals......................................................................................... 35
Grounds and No Connect Signals ...................................................................... 35
Voltage Regulation Control Signals .................................................................... 35
Signal Names in Pin Order ................................................................................. 36
Datasheet
1
82541ER Gigabit Ethernet Controller
2
Datasheet
82541ER Gigabit Ethernet Controller
1
1
2
3
4
5
6
7
8
9
10
11
12
82541ER Block Diagram ...................................................................................... 3
AC Test Loads for General Output Pins ............................................................. 23
PCI Clock Timing ................................................................................................ 23
PCI Bus Interface Output Timing Measurement ................................................. 24
PCI Bus Interface Input Timing Measurement Conditions.................................. 25
TVAL (max) Rising Edge Test Load ................................................................... 25
TVAL (max) Falling Edge Test Load................................................................... 26
TVAL (min) Test Load......................................................................................... 26
TVAL Test Load (PCI 5 V Signaling Environment) ............................................. 26
Link Interface Rise/Fall Timing ........................................................................... 27
82541ER Mechanical Specifications .................................................................. 29
196 PBGA Package Pad Detail .......................................................................... 30
Visual Pin Assignments ...................................................................................... 42
Datasheet
1