GD82559ER Fast Ethernet**
PCI Controller
Networking Silicon
Datasheet
Product Features
■ Optimum Integration for Lowest Cost
■ High Performance Networking Functions
Solution
—Chained memory structure similar to the
82559,82558, 82557, and 82596
—Integrated IEEE 802.3 10BASE-T and
100BASE-TX compatible PHY
—Improved dynamic transmit chaining
with multiple priorities transmit queues
—Glueless 32-bit PCI master interface
—128 Kbyte Flash interface
—Thin BGA 15mm2 package
—Full Duplex support at both 10 and 100
Mbps
—IEEE 802.3u Auto-Negotiation support
—ACPI and PCI Power Management
—3 Kbyte transmit and 3 Kbyte receive
FIFOs
—Power management event on
“interesting” packets and link status
change support
—Fast back-to-back transmission support
with minimum interframe spacing
—Test Access Port
—IEEE 802.3x 100BASE-TX Flow
Control support
—Low Power Features
—Low power 3.3 V device
—Efficient dynamic standby mode
—Deep power down support
—Clockrun protocol support
Document Number: 714682-001
Revision 1.0
March 1999
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Networking Silicon — GD82559ER
Contents
1.
2.
INTRODUCTION.............................................................................................................................1
1.1 GD82559ER Overview .......................................................................................................1
1.2 Suggested Reading ............................................................................................................1
GD82559ER ARCHITECTURAL OVERVIEW ................................................................................3
2.1 Parallel Subsystem Overview.............................................................................................3
2.2 FIFO Subsystem Overview.................................................................................................4
2.3 10/100 Mbps Serial CSMA/CD Unit Overview....................................................................5
2.4 10/100 Mbps Physical Layer Unit .......................................................................................5
3.
SIGNAL DESCRIPTIONS...............................................................................................................7
3.1 Signal Type Definitions.......................................................................................................7
3.2 PCI Bus Interface Signals...................................................................................................7
3.2.1 Address and Data Signals..................................................................................7
3.2.2 Interface Control Signals ....................................................................................8
3.2.3 System and Power Management Signals...........................................................9
3.3 Local Memory Interface Signals .........................................................................................9
3.4 Testability Port Signals .....................................................................................................10
3.5 PHY Signals .....................................................................................................................11
4.
GD82559ER MEDIA ACCESS CONTROL FUNCTIONAL DESCRIPTION.................................13
4.1 82559ER Initialization.......................................................................................................13
4.1.1 Initialization Effects on 82559ER Units ............................................................13
4.2 PCI Interface.....................................................................................................................14
4.2.1 82559ER Bus Operations.................................................................................14
4.2.2 Clockrun Signal ................................................................................................22
4.2.3 Power Management Event Signal....................................................................22
4.2.4 Power States ....................................................................................................23
4.2.5 Wake-up Events...............................................................................................27
4.3 Parallel Flash Interface.....................................................................................................28
4.4 Serial EEPROM Interface.................................................................................................28
4.5 10/100 Mbps CSMA/CD Unit............................................................................................30
4.5.1 Full Duplex .......................................................................................................31
4.5.2 Flow Control .....................................................................................................31
4.5.3 Address Filtering Modifications.........................................................................31
4.5.4 Long Frame Reception.....................................................................................31
4.6 Media Independent Interface (MII) Management Interface...............................................32
5.
6.
GD82559ER TEST PORT FUNCTIONALITY ...............................................................................33
5.1 Introduction.......................................................................................................................33
5.2 Asynchronous Test Mode.................................................................................................33
5.3 Test Function Description.................................................................................................33
5.4 85/85.................................................................................................................................33
5.5 TriState .............................................................................................................................34
5.6 Nand - Tree ......................................................................................................................34
GD82559ER PHYSICAL LAYER FUNCTIONAL DESCRIPTION................................................37
6.1 100BASE-TX PHY Unit ....................................................................................................37
6.1.1 100BASE-TX Transmit Clock Generation ........................................................37
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6.1.2 100BASE-TX Transmit Blocks .........................................................................37
6.1.3 100BASE-TX Receive Blocks ..........................................................................40
6.1.4 100BASE-TX Collision Detection .....................................................................41
6.1.5 100BASE-TX Link Integrity and Auto-Negotiation Solution..............................41
6.1.6 Auto 10/100 Mbps Speed Selection.................................................................41
6.2 10BASE-T Functionality ...................................................................................................41
6.2.1 10BASE-T Transmit Clock Generation.............................................................41
6.2.2 10BASE-T Transmit Blocks..............................................................................42
6.2.3 10BASE-T Receive Blocks...............................................................................42
6.2.4 10BASE-T Collision Detection..........................................................................43
6.2.5 10BASE-T Link Integrity...................................................................................43
6.2.6 10BASE-T Jabber Control Function.................................................................43
6.2.7 10BASE-T Full Duplex .....................................................................................43
6.3 Auto-Negotiation Functionality..........................................................................................43
6.3.1 Description .......................................................................................................44
6.3.2 Parallel Detect and Auto-Negotiation ...............................................................44
6.4 LED Description................................................................................................................45
7.
PCI CONFIGURATION REGISTERS ...........................................................................................47
7.1 LAN (Ethernet) PCI Configuration Space.........................................................................47
7.1.1 PCI Vendor ID and Device ID Registers ..........................................................47
7.1.2 PCI Command Register ...................................................................................48
7.1.3 PCI Status Register..........................................................................................49
7.1.4 PCI Revision ID Register..................................................................................50
7.1.5 PCI Class Code Register .................................................................................50
7.1.6 PCI Cache Line Size Register..........................................................................50
7.1.7 PCI Latency Timer............................................................................................51
7.1.8 PCI Header Type..............................................................................................51
7.1.9 PCI Base Address Registers............................................................................51
7.1.10 PCI Subsystem Vendor ID and Subsystem ID Registers.................................53
7.1.11 Capability Pointer .............................................................................................53
7.1.12 Interrupt Line Register......................................................................................53
7.1.13 Interrupt Pin Register .......................................................................................54
7.1.14 Minimum Grant Register ..................................................................................54
7.1.15 Maximum Latency Register..............................................................................54
7.1.16 Capability ID Register.......................................................................................54
7.1.17 Next Item Pointer..............................................................................................54
7.1.18 Power Management Capabilities Register .......................................................54
7.1.19 Power Management Control/Status Register (PMCSR)...................................55
7.1.20 Data Register ...................................................................................................56
8.
CONTROL/STATUS REGISTERS................................................................................................57
8.1 LAN (Ethernet) Control/Status Registers..........................................................................57
8.1.1 System Control Block Status Word ..................................................................58
8.1.2 System Control Block Command Word............................................................59
8.1.3 System Control Block General Pointer.............................................................59
8.1.4 PORT ...............................................................................................................59
8.1.5 Flash Control Register......................................................................................59
8.1.6 EEPROM Control Register...............................................................................59
8.1.7 Management Data Interface Control Register..................................................59
8.1.8 Receive Direct Memory Access Byte Count.....................................................60
8.1.9 Early Receive Interrupt.....................................................................................60
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8.1.10 Flow Control Register.......................................................................................60
8.1.11 Power Management Driver Register ................................................................60
8.1.12 General Control Register..................................................................................61
8.1.13 General Status Register...................................................................................61
8.2 Statistical Counters...........................................................................................................62
9.
PHY UNIT REGISTERS................................................................................................................65
9.1 MDI Registers 0 - 7...........................................................................................................65
9.1.1 Register 0: Control Register Bit Definitions .....................................................65
9.1.2 Register 1: Status Register Bit Definitions .......................................................66
9.1.3 Register 2: PHY Identifier Register Bit Definitions ...........................................67
9.1.4 Register 3: PHY Identifier Register Bit Definitions ...........................................67
9.1.5 Register 4: Auto-Negotiation Advertisement Register Bit Definitions ..............67
9.1.6 Register 5: Auto-Negotiation Link Partner Ability Register Bit Definitions .......67
9.1.7 Register 6: Auto-Negotiation Expansion Register Bit Definitions ....................68
9.2 MDI Registers 8 - 15.........................................................................................................68
9.3 MDI Register 16 - 31 ........................................................................................................68
9.3.1 Register 16: PHY Unit Status and Control Register Bit Definitions .................68
9.3.2 Register 17: PHY Unit Special Control Bit Definitions .....................................69
9.3.3 Register 18: PHY Address Register.................................................................70
9.3.4 Register 19: 100BASE-TX Receive False Carrier Counter Bit Definitions ......70
9.3.5 Register 20: 100BASE-TX Receive Disconnect Counter Bit Definitions .........70
9.3.6 Register 21: 100BASE-TX Receive Error Frame Counter Bit Definitions ........70
9.3.7 Register 22: Receive Symbol Error Counter Bit Definitions ............................70
9.3.8 Register 23: 100BASE-TX Receive Premature End of Frame Error Counter
Bit Definitions ..................................................................................................71
9.3.9 Register 24: 10BASE-T Receive End of Frame Error Counter Bit Definitions .71
9.3.10 Register 25: 10BASE-T Transmit Jabber Detect Counter Bit Definitions ........71
9.3.11 Register 26: Equalizer Control and Status Bit Definitions ................................71
9.3.12 Register 27: PHY Unit Special Control Bit Definitions .....................................71
10. ELECTRICAL AND TIMING SPECIFICATIONS ..........................................................................73
10.1 Absolute Maximum Ratings..............................................................................................73
10.2 DC Specifications ............................................................................................................73
10.3 AC Specifications .............................................................................................................76
10.4 Timing Specifications........................................................................................................77
10.4.1 Clocks Specifications .......................................................................................77
10.4.2 Timing Parameters...........................................................................................78
12. PACKAGE AND PINOUT INFORMATION...................................................................................85
12.1 Package Information.........................................................................................................85
12.2 Pinout Information ............................................................................................................86
12.2.1 GD82559ER Pin Assignments ........................................................................86
12.2.2 GD82559ER Ball Grid Array Diagram .............................................................88
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Networking Silicon — GD82559ER
1.
Introduction
1.1
GD82559ER Overview
The 82559ER is part of Intel's second generation family of fully integrated 10BASE-T/100BASE-
TX LAN solutions. The 82559ER consists of both the Media Access Controller (MAC) and the
physical layer (PHY) combined into a single component solution. 82559 family members build on
the basic functionality of the 82558 and contain power management enhancements.
The 82559ER is a 32-bit PCI controller that features enhanced scatter-gather bus mastering
capabilities which enables the 82559ER to perform high-speed data transfers over the PCI bus.The
82559ER bus master capabilities enable the component to process high-level commands and
perform multiple operations, thereby off-loading communication tasks from the system CPU. Two
large transmit and receive FIFOs of 3 Kbytes each help prevent data underruns and overruns,
allowing the 82559ER to transmit data with minimum interframe spacing (IFS).
The 82559ER can operate in either full duplex or half duplex mode. In full duplex mode the
82559ER adheres to the IEEE 802.3x Flow Control specification. Half duplex performance is
enhanced by a proprietary collision reduction mechanism.
The 82559ER includes a simple PHY interface to the wire transformer at rates of 10BASE-T and
100BASE-TX, and Auto-Negotiation capability for speed, duplex, and flow control. These features
and others reduce cost, real estate, and design complexity.
The 82559ER also includes an interface to a serial (4-pin) EEPROM and a parallel interface to a
128 Kbyte Flash memory. The EEPROM provides power-on initialization for hardware and
software configuration parameters
1.2
Suggested Reading
The 82559 family of devices are designed to be compliant with PC industry power management
initiatives. This includes the ACPI, PCI Power Management Specification, Network Device Class
specification, etc. See the following publicaitons for more information about these topics.
• PCI Specification, PCI Special Interest Group.
• Network Device Class Reference, Revision 1.0, Intel Corporation, Microsoft Corporation, and
Toshiba.
• Advanced Configuration and Power Interface (ACPI) Specification, Intel Corporation,
Microsoft Corporation, Toshiba.
• Advanced Power Management (APM) Specification, Intel Corporation and Microsoft
Corporation.
• 82559 Fast Ethernet Multifunction PCI/CardBus Controller Datasheet, Intel Corporation.
• LAN On Motherboard (LOM) Design Guide Application Note (AP-391), Intel Corporation.
• Test Access Port Applications Note (AP-393), Intel Corporation.
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Networking Silicon — GD82559ER
2.
GD82559ER Architectural Overview
Figure 1 is a high level block diagram of the 82559ER. It is divided into four main subsystems: a
parallel subsystem, a FIFO subsystem, the 10/100 Mbps Carrier-Sense Multiple Access with
Collision Detect (CSMA/CD) unit, and the 10/100 Mbps physical layer (PHY) unit.
Local Memory
Interface
PCI Target and
Flash/EEPROM
3 Kbyte
Tx FIFO
Interface
Four Channel
Addressing Unit -
DMA
100BASE-TX/
10/100 Mbps
CSMA/CD
FIFO Control
TPE
Interface
10BASE-T
PHY
Micro-
machine
PCI Bus
Interface Unit
(BIU)
PCI
Interface
3 Kbyte
Rx FIFO
Dual
Ported
FIFO
Data Interface Unit
(DIU)
Figure 1. 82559ER Block Diagram
2.1
Parallel Subsystem Overview
The parallel subsystem is broken down into several functional blocks: a PCI bus master interface, a
micromachine processing unit and its corresponding microcode ROM, and a PCI Target Control/
Flash/EEPROM interface. The parallel subsystem also interfaces to the FIFO subsystem, passing
data (such as transmit, receive, and configuration data) and command and status parameters
between these two blocks.
The PCI bus master interface provides a complete glueless interface to a PCI bus and is compliant
with the PCI Bus Specification, Revision 2.2. The 82559ER provides 32 bits of addressing and
data, as well as the complete control interface to operate on a PCI bus. As a PCI target, it follows
the PCI configuration format which allows all accesses to the 82559ER to be automatically
mapped into free memory and I/O space upon initialization of a PCI system. For processing of
transmit and receive frames, the 82559ER operates as a master on the PCI bus, initiating zero wait
state transfers for accessing these data parameters.
The 82559ER Control/Status Register Block is part of the PCI target element. The Control/Status
Register block consists of the following 82559ER internal control registers: System Control Block
(SCB), PORT, Flash Control, EEPROM Control, and Management Data Interface (MDI) Control.
The micromachine is an embedded processing unit contained in the 82559ER. The micromachine
accesses the 82559ER microcode ROM working its way through the opcodes (or instructions)
contained in the ROM to perform its functions. Parameters accessed from memory such as pointers
to data buffers are also used by the micromachine during the processing of transmit or receive
frames by the 82559ER. A typical micromachine function is to transfer a data buffer pointer field
to the 82559ER DMA unit for direct access to the data buffer. The micromachine is divided into
two units, Receive Unit and Command Unit which includes transmit functions. These two units
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operate independently. Control is switched between the two units according to the microcode
instruction flow. The independence of the Receive and Command units in the micromachine allows
the 82559ER to interleave commands and receive incoming frames, with no real-time CPU
intervention.
The 82559ER contains an interface to an external Flash memory, and external serial EEPROM.
These two interfaces are multiplexed. The Flash interface, which could also be used to connect to
any standard 8-bit device, provides up to 128 Kbytes of addressing to the Flash. Both read and
write accesses are supported. The Flash may be used for remote boot functions, network statistical
and diagnostics functions, and management functions. The Flash is mapped into host system
memory (anywhere within the 32-bit memory address space) for software accesses. It is also
mapped into an available boot expansion ROM location during boot time of the system. More
information on the Flash interface is detailed in Section 4.3, “Parallel Flash Interface” on page 28.
The EEPROM is used to store relevant information for a LAN connection such as node address, as
well as board manufacturing and configuration information. Both read and write accesses to the
EEPROM are supported by the 82559ER. Information on the EEPROM interface is detailed in
Section 4.4, “Serial EEPROM Interface” on page 28.
2.2
FIFO Subsystem Overview
The 82559ER FIFO subsystem consists of a 3 Kbyte transmit FIFO and 3 Kbyte receive FIFO.
Each FIFO is unidirectional and independent of the other. The FIFO subsystem serves as the
interface between the 82559ER parallel side and the serial CSMA/CD unit. It provides a temporary
buffer storage area for frames as they are either being received or transmitted by the 82559ER,
which improves performance:
• Transmit frames can be queued within the transmit FIFO, allowing back-to-back transmission
within the minimum Interframe Spacing (IFS).
• The storage area in the FIFO allows the 82559ER to withstand long PCI bus latencies without
losing incoming data or corrupting outgoing data.
• The 82559ER transmit FIFO threshold allows the transmit start threshold to be tuned to
eliminate underruns while concurrent transmits are being performed (i.e. pending transmits
will not be affected by the change in FIFO threshold).
• The FIFO subsection allows extended PCI burst accesses with zero wait states to or from the
82559ER for both transmit and receive frames. This is because such the transfer is to the FIFO
storage area, rather than directly to the serial link.
• Transmissions resulting in errors (collision detection or data underrun) are retransmitted
directly from the 82559ER FIFO, therey increasing performance and eliminating the need to
re-access this data from the host system.
• Incoming runt receive frames (frames that are less than the legal minimum frame size) can be
discarded automatically by the 82559ER without transferring this faulty data to the host
system, and without host intervention.
• Bad Frames resolution can be selectively left to the 82559ER, or under software control.
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2.3
2.4
10/100 Mbps Serial CSMA/CD Unit Overview
The CSMA/CD unit of the 82559ER allows it to be connected to either a 10 or 100 Mbps Ethernet
network. The CSMA/CD unit performs all of the functions of the 802.3 protocol such as frame
formatting, frame stripping, collision handling, deferral to link traffic, etc. The CSMA/CD unit can
also be placed in a full-duplex mode, which allows simultaneous transmission and reception of
frames.
10/100 Mbps Physical Layer Unit
The Physical Layer (PHY) unit of the 82559ER allows connection to either a 10 or 100 Mbps
Ethernet network. The PHY unit supports Auto-Negotiation for 100BASE-TX Full Duplex,
100BASE-TX Half Duplex, 10BASE-T Full Duplex, and 10BASE-T Half Duplex. It also supports
three LED pins to indicate link status, network activity, and speed.The 82559ER does not support
external PHY devices and does not expose its internal MII bus.
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3.
Signal Descriptions
3.1
Signal Type Definitions
Type
IN
Name
Description
Input
The input pin is a standard input only signal.
The output pin is a Totem Pole Output pin and is a standard
active driver.
OUT
T/S
Output
Tri-State
The tri-state pin is a bidirectional, input/output pin.
The sustained tri-state pin is an active low tri-state signal owned
and driven by one agent at a time. The agent asserting the S/T/
S pin low must drive it high at least one clock cycle before
floating the pin. A new agent can only assert an S/T/S signal low
one clock cycle after it has been tri-stated by the previous
owner.
S/T/S
Sustained Tri-State
The open drain pin allows multiple devices to share this signal
as a wired-OR.
O/D
Open Drain
A/I
A/O
B
Analog Input
Analog Output
Bias
The analog input pin is used for analog input signals.
The analog output pin is used for analog output signals.
The bias pin is an input bias.
3.2
PCI Bus Interface Signals
3.2.1
Address and Data Signals
Symbol
Type
Name and Function
Address and Data. The address and data lines are multiplexed on
the same PCI pins. A bus transaction consists of an address phase
followed by one or more data phases. During the address phase, the
address and data lines contain the 32-bit physical address. For I/O,
this is a byte address; for configuration and memory, it is a Dword
address. The 82559ER uses little-endian byte ordering (in other
words, AD[31:24] contain the most significant byte and AD[7:0]
contain the least significant byte). During the data phases, the address
and data lines contain data.
AD[31:0]
T/S
Command and Byte Enable. The bus command and byte enable
signals are multiplexed on the same PCI pins. During the address
phase, the C/BE# lines define the bus command. During the data
phase, the C/BE# lines are used as Byte Enables. The Byte Enables
are valid for the entire data phase and determine which byte lanes
carry meaningful data.
C/BE[3:0]#
T/S
T/S
Parity. Parity is even across AD[31:0] and C/BE[3:0]# lines. It is stable
and valid one clock after the address phase. For data phases, PAR is
stable and valid one clock after either IRDY# is asserted on a write
transaction or TRDY# is asserted on a read transaction.Once PAR is
valid, it remains valid until one clock after the completion of the current
data phase. The master drives PAR for address and write data
phases; and the target, for read data phases.
PAR
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3.2.2
Interface Control Signals
Symbol
Type
Name and Function
Cycle Frame. The cycle frame signal is driven by the current master
to indicate the beginning and duration of a transaction. FRAME# is
asserted to indicate the start of a transaction and de-asserted during
the final data phase.
FRAME#
S/T/S
Initiator Ready. The initiator ready signal indicates the bus master’s
ability to complete the current data phase and is used in conjunction
with the target ready (TRDY#) signal. A data phase is completed on
any clock cycle where both IRDY# and TRDY# are sampled asserted
(low) simultaneously.
IRDY#
S/T/S
S/T/S
Target Ready. The target ready signal indicates the selected device’s
ability to complete the current data phase and is used in conjunction
with the initiator ready (IRDY#) signal. A data phase is completed on
any clock cycle where both IRDY# and TRDY# are sampled asserted
(low) simultaneously.
TRDY#
Stop. The stop signal is driven by the target to indicate to the initiator
that it wishes to stop the current transaction. As a bus slave, STOP# is
driven by the 82559ER to inform the bus master to stop the current
transaction. As a bus master, STOP# is received by the 82559ER to
stop the current transaction.
STOP#
IDSEL
S/T/S
IN
Initialization Device Select. The initialization device select signal is
used by the 82559ER as a chip select during PCI configuration read
and write transactions. This signal is provided by the host in PCI
systems.
Device Select. The device select signal is asserted by the target once
it has detected its address. As a bus master, the DEVSEL# is an input
signal to the 82559ER indicating whether any device on the bus has
been selected. As a bus slave, the 82559ER asserts DEVSEL# to
indicate that it has decoded its address as the target of the current
transaction.
DEVSEL#
REQ#
S/T/S
T/S
Request. The request signal indicates to the bus arbiter that the
82559ER desires use of the bus. This is a point-to-point signal and
every bus master has its own REQ#.
Grant. The grant signal is asserted by the bus arbiter and indicates to
the 82559ER that access to the bus has been granted. This is a point-
to-point signal and every master has its own GNT#.
GNT#
INTA#
SERR#
IN
Interrupt A. The interrupt A signal is used to request an interrupt by
the 82559ER. This is an active low, level triggered interrupt signal.
O/D
O/D
System Error. The system error signal is used to report address
parity errors. When an error is detected, SERR# is driven low for a
single PCI clock.
Parity Error. The parity error signal is used to report data parity errors
during all PCI transactions except a Special Cycle. The parity error pin
is asserted two clock cycles after the error was detected by the device
receiving data. The minimum duration of PERR# is one clock for each
data phase where an error is detected. A device cannot report a parity
error until it has claimed the access by asserting DEVSEL# and
completed a data phase.
PERR#
S/T/S
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3.2.3
System and Power Management Signals
Symbol
Type
Name and Function
Clock. The Clock signal provides the timing for all PCI transactions
and is an input signal to every PCI device. The 82559ER requires a
PCI Clock signal (frequency greater than or equal to 16 MHz) for
nominal operation. The 82559ER supports Clock signal suspension
using the Clockrun protocol.
CLK
IN
Clockrun. The Clockrun signal is used by the system to pause or slow
down the PCI Clock signal. It is used by the 82559ER to enable or
disable suspension of the PCI Clock signal or restart of the PCI clock.
When the Clockrun signal is not used, this pin should be connected to
an external pull-down resistor.
IN/OUT
O/D
CLKRUN#
Reset. The PCI Reset signal is used to place PCI registers,
sequencers, and signals into a consistent state. When RST# is
asserted, all PCI output signals will be tri-stated.
RST#
PME#
IN
Power Management Event. The Power Management Event signal
indicates that a power management event has occurred in a PCI bus
system.
O/D
Isolate. The Isolate signal is used to isolate the 82559ER from the
PCI bus. When Isolate is active (low), the 82559ER does not drive its
PCI outputs (except PME#) or sample its PCI inputs (including CLK
and RST#). If the 82559ER is not powered by an auxiliary power
source, the ISOLATE# pin should be pulled high to the bus Vcc
through a 4.7K-62K resistor.
ISOLATE#
ALTRST#
VIO
IN
IN
Alternate Reset. The Alternate Reset signal is used to reset the
82559ER on power-up. In systems that support an auxiliary power
supply, ALTRST# should be connected to a power-up detection circuit.
Otherwise, ALTRST# should be tied to V
.
cc
Voltage Input/Output. The VIO pin is the a voltage bias pin for the
PCI interface. This pin should be connected to 5V ± 5% in a 5 volt PCI
system and 3.3 volts in a 3.3 volt PCI system. Be sure to install a 10K
pull-up resistor. This resistor acts as a current limit resistor in system
where the VIO bias voltage maybe shutdown. In this cases the
82559ER may consume additional current without a resistor.
B
IN
3.3
Local Memory Interface Signals
Symbol
FLD[7:0]
Type
T/S
Name and Function
Flash Data Input/Output. These pins are used for Flash data
interface.
Flash Address[16]/25 MHz Clock. This multiplexed pin is controlled
by the status of the Flash Address[7] (FLA[7]) pin. If FLA[7] is left
floating, this pin is used as FLA[16]; otherwise, if FLA[7] is connected
to a pull-up resistor, this pin is used as a 25 MHz clock.
FLA[16]/
CLK25
OUT
Flash Address[15]/EEPROM Data Output. During Flash accesses,
this multiplexed pin acts as the Flash Address [15] output signal.
During EEPROM accesses, it acts as the serial shift clock output to
the EEPROM.
FLA[15]/
EESK
OUT
Flash Address[14]/EEPROM Data Output. During Flash accesses,
this multiplexed pin acts as the Flash Address [14] output signal.
During EEPROM accesses, it acts as serial input data to the EEPROM
Data Output signal.
FLA[14]/
EEDO
IN/OUT
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Symbol
Type
Name and Function
Flash Address[13]/EEPROM Data Input. During Flash accesses,
this multiplexed pin acts as the Flash Address [13] output signal.
During EEPROM accesses, it acts as serial output data to the
EEPROM Data Input signal.
FLA[13]/
EEDI
OUT
OUT
Flash Address[12:8]. These pins are used as Flash address outputs
to support 128 Kbyte Flash addressing.
FLA[12:8]
Flash Address[7]/Clock Enable. This is a multiplexed pin and acts
as the Flash Address[7] output signal during nominal operation. When
the PCI RST# signal is active, this pin acts as input control over the
FLA[16]/CLK25 output signal. If the FLA[7]/CLKEN pin is connected to
a pull-up resistor (3.3 KΩ), a 25 MHz clock signal is provided on the
FLA[16]/CLK25 output; otherwise, it is used as FLA[16] output.
FLA[7]/
CLKENB
T/S
Flash Address[6:2]. These pins are used as Flash address outputs
to support 128 Kbyte Flash addressing.
FLA[6:2]
OUT
T/S
Flash Address[1]/Auxiliary Power. This multiplexed pin acts as the
Flash Address[1] output signal during nominal operation. When RST is
active (low), it acts as the power supply indicator. If the 82559ER is fed
PCI power, this pin should be connected to a pull-down resistor; if the
82559ER is fed by auxiliary power, this pin should be connected to a
pull-up resistor.
FLA[1]/
AUXPWR
Flash Address [0]. This pin acts as the Flash Address[0] output
signal during nominal operation.
FLA[0]
EECS
T/S
EEPROM Chip Select. The EEPROM Chip Select signal is used to
assert chip select to the serial EEPROM.
OUT
OUT
OUT
OUT
Flash Chip Select. The Flash Chip Select signal is active during
Flash.
FLCS#
FLOE#
FLWE#
Flash Output Enable. This pin provides an active low output enable
control (read) to the Flash memory.
Flash Write Enable. This pin provides an active low write enable
control to the Flash memory.
3.4
Testability Port Signals
Symbol
Type
Name and Function
Test. If this input pin is high, the 82559ER will enable the test port.
During nominal operation this pin should be connected to a pull-down
resistor.
TEST
IN
Testability Port Clock. This pin is used for the Testability Port Clock
signal.
TCK
TI
IN
Testability Port Data Input. This pin is used for the Testability Port
Data Input signal.
IN
Testability Port Execute Enable. This pin is used for the Testability
Port Execute Enable signal.
TEXEC
TO
IN
Testability Port Data Output. This pin is used for the Testability Port
Data Output signal.
OUT
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3.5
PHY Signals
Symbol
Type
Name and Function
Crystal Input One. X1 and X2 can be driven by an external 3.3 V 25
MHz crystal. Otherwise, X1 may be driven by an external metal-oxide
semiconductor (MOS) level 25 MHz oscillator when X2 is left floating.
X1
A/I
Crystal Input Two. X1 and X2 can be driven by an external 3.3 V 25
MHz crystal. Otherwise, X1 may be driven by an external MOS level
25 MHz oscillator when X2 is left floating.
X2
A/O
A/O
Analog Twisted Pair Ethernet Transmit Differential Pair. These
pins transmit the serial bit stream for transmission on the Unshielded
Twisted Pair (UTP) cable. The current-driven differential driver can be
two-level (10BASE-T) or three-level (100BASE-TX) signals depending
on the mode of operation. These signals interface directly with an
isolation transformer.
TDP
TDN
Analog Twisted Pair Ethernet Receive Differential Pair. Thesepins
receive the serial bit stream from the isolation transformer. The bit
stream can be two-level (10BASE-T) or three-level (100BASE-TX)
signals depending on the mode of operation.
RDP
RDN
A/I
Activity LED. The Activity LED pin indicates either transmit or receive
activity. When activity is present, the activity LED is on; when no
activity is present, the activity LED is off.
ACTLED#
LILED#
OUT
OUT
Link Integrity LED. The Link Integrity LED pin indicates link integrity.
If the link is valid in either 10 or 100 Mbps, the LED is on; if link is
invalid, the LED is off.
Speed LED. The Speed LED pin indicates the speed. The speed LED
will be on at 100 Mbps and off at 10 Mbps.
SPEEDLED# OUT
Reference Bias Resistor (100 Mbps). This pin controls the out
envelope of the 82559ERER when transmitting in the 10 Mbps mode
via the use of a pull-down resistor to ground. A value of 619 Ω pull-
down resistor is adequate is most applications.
RBIAS100
B
Reference Bias Resistor (10 Mbps). This pin controls the out
envelope of the 82559ER when transmitting in the 10 Mbps mode via
the use of a pull-down resistor to ground. A value of 549 Ω pull-down
resistor is adequate is most applications.
RBIAS10
VREF
B
B
Voltage Reference. This pin is connected to a 1.25 V ± 1% external
voltage reference generator. To use the internal voltage reference
source, this pin should be left floating.
Ω and 549 Ω for the RBIAS100 and RBIAS10, respectively, are only a recommended values and
NOTE: 619
should be fine tuned for various designs.
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4.
GD82559ER Media Access Control Functional
Description
4.1
82559ER Initialization
The 82559ER has four sources for initialization. They are listed according to their precedence:
1. ALTRST# Signal
2. PCI RST# Signal
3. Software Reset (Software Command)
4. Selective Reset (Software Command)
4.1.1
Initialization Effects on 82559ER Units
The following table shows the effect of each of the different initialization sources on major
portions of the 82559ER. The initialization sources are listed in order of precedence. For example,
any resource that is initialized by the Software Reset is also initialized by the D3 to D0 transition
and ALTRST# and PCI RST# but not necessarily by the selective reset.
ISOLATE
#
D3 to D0
Transition
Software
Reset
Selective
Reset
ALTRST# PCI RST#
EEPROM read and
initialization
3
3
3
3
3
3
3
3
3
--
3
--
3
3
3
--
3
3
3
--
--
--
3
Loadable microcode
decoded/reset
MAC configuration reset and
multicast hash
Memory pointers and
mircomachine state reset
--
PCI Configuration register
reset
3
3
3
3
3
3
--
--
--
--
PHY configuration reset
--
--
Clear only
if no
auxiliary
power
Power management event
reset
3
3
--
--
--
--
--
--
present
Statistic counters reset
3
3
3
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4.2
PCI Interface
4.2.1
82559ER Bus Operations
After configuration, the 82559ER is ready for normal operation. As a Fast Ethernet controller, the
role of the 82559ER is to access transmitted data or deposit received data. In both cases the
82559ER, as a bus master device, will initiate memory cycles via the PCI bus to fetch or deposit
the required data.
To perform these actions, the 82559ER is controlled and examined by the CPU via its control and
status structures and registers. Some of these control and status structures reside in the 82559ER
and some reside in system memory. For access to the 82559ER’s Control/Status Registers (CSR),
the 82559ER acts as a slave (in other words, a target device). The 82559ER serves as a slave also
while the CPU accesses its 128 Kbyte Flash buffer or its EEPROM. Section 4.2.1.1 describes the
82559ER slave operation. It is followed by a description of the 82559ER operation as a bus master
(initiator) in Section 4.2.1.2, “82559ER Bus Master Operation” on page 18.
4.2.1.1
82559ER Bus Slave Operation
The 82559ER serves as a target device in one of the following cases:
• CPU accesses to the 82559ER System Control Block (SCB) Control/Status Registers (CSR)
• CPU accesses to the EEPROM through its CSR
• CPU accesses to the 82559ER PORT address via the CSR
• CPU accesses to the MDI control register in the CSR
• CPU accesses to the Flash control register in the CSR
• CPU accesses to the 128 Kbyte Flash
The CSR and the Flash buffer are considered by the 82559ER as two totally separated memory
spaces. The 82559ER provides separate Base Address Registers (BARs) in the configuration space
to distinguish between them. The size of the CSR memory space is 4 Kbyte in the memory space
and 64 bytes in the I/O space. The 82559ER treats accesses to these memory spaces differently.
4.2.1.1.1 Control/Status Register (CSR) Accesses
The 82559ER supports zero wait-state single-cycle memory or I/O-mapped accesses to its CSR
space. Separate BARs request 4 Kbytes of memory space and 64 bytes of I/O space to accomplish
this. Based on its needs, the software driver will use either memory or I/O mapping to access these
registers. The 4 Kbytes of CSR space the 82559ER requests include the following elements:
• System Control Block (SCB) registers
• PORT register
• Flash control register
• EEPROM control register
• MDI control register
• Flow control registers
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The figures below show CSR zero wait-state I/O read and write cycles. In the case of accessing the
Control/Status Registers, the CPU is the initiator and the 82559ER is the target of the transaction.
CLK
1
2
3
4
5
6
7
8
9
FRAME#
AD
ADDR
I/O RD
DATA
BE#
C/BE#
IRDY#
TRDY#
DEVSEL#
STOP#
Figure 2. CSR I/O Read Cycle
Read Accesses: The CPU, as the initiator, drives address lines AD[31:0], the command and byte
enable lines C/BE#[3:0] and the control lines IRDY# and FRAME#. As a slave, the 82559ER
controls the TRDY# signal and provides valid data on each data access. The 82559ER allows the
CPU to issue only one read cycle when it accesses the Control/Status Registers, generating a
disconnect by asserting the STOP# signal. The CPU can insert wait states by de-asserting IRDY#
when it is not ready.
CLK
1
2
3
4
5
6
7
8
9
FRAME#
AD
ADDR
DATA
I/O WR
BE#
C/BE#
IRDY#
TRDY#
DEVSEL#
STOP#
Figure 3. CSR I/O Write Cycle
Write Accesses: The CPU, as the initiator, drives the address lines AD[31:0], the command and
byte enable lines C/BE#[3:0] and the control lines IRDY# and FRAME#. It also provides the
82559ER with valid data on each data access immediately after asserting IRDY#. The 82559ER
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controls the TRDY# signal and asserts it from the data access. The 82559ER allows the CPU to
issue only one I/O write cycle to the Control/Status Registers, generating a disconnect by asserting
the STOP# signal. This is true for both memory mapped and I/O mapped accesses.
4.2.1.1.2 Flash Buffer Accesses
The CPU accesses to the Flash buffer are very slow. For this reason the 82559ER issues a target-
disconnect at the first data access. The 82559ER asserts the STOP# signal to indicate a target-
disconnect. The figures below illustrate memory CPU read and write accesses to the 128 Kbyte
Flash buffer. The longest burst cycle to the Flash buffer contains one data access only.
CLK
FRAME#
ADDR
DATA
AD
MEM RD
BE#
C/BE#
IRDY#
TRDY#
DEVSEL#
STOP#
Figure 4. Flash Buffer Read Cycle
Read Accesses: The CPU, as the initiator, drives the address lines AD[31:0], the command and
byte enable lines C/BE#[3:0] and the control lines IRDY# and FRAME#. The 82559ER controls
the TRDY# signal and de-asserts it for a certain number of clocks until valid data can be read from
the Flash buffer. When TRDY# is asserted, the 82559ER drives valid data on the AD[31:0] lines.
The CPU can also insert wait states by de-asserting IRDY# until it is ready. Flash buffer read
accesses can be byte or word length.
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CLK
FRAME#
AD
DATA
BE#
ADDR
MEM WR
C/BE#
IRDY#
TRDY#
DEVSEL#
STOP#
Figure 5. Flash Buffer Write Cycle
Write Accesses: The CPU, as the initiator, drives the address lines AD[31:0], the command and
byte enable lines C/BE#[3:0] and the control lines IRDY# and FRAME#. It also provides the
82559ER with valid data immediately after asserting IRDY#. The 82559ER controls the TRDY#
signal and de-asserts it for a certain number of clocks until valid data is written to the Flash buffer.
By asserting TRDY#, the 82559ER signals the CPU that the current data access has completed.
Flash buffer write accesses can be byte length only.
4.2.1.1.3 Retry Premature Accesses
The 82559ER responds with a Retry to any configuration cycle accessing the 82559ER before the
completion of the automatic read of the EEPROM. The 82559ER may continue to Retry any
configuration accesses until the EEPROM read is complete. The 82559ER does not enforce the
rule that the retried master must attempt to access the same address again to complete any delayed
transaction. Any master access to the 82559ER after the completion of the EEPROM read will be
honored. Figure 6 depicts the operation of a Retry cycle.
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CLK
FRAME#
IRDY#
TRDY#
DEVSEL#
STOP#
Figure 6. PCI Retry Cycle
Note: The 82559ER is considered the target in the above diagram; thus, TRDY# is not asserted.
4.2.1.1.4 Error Handling
Data Parity Errors: The 82559ER checks for data parity errors while it is the target of the
transaction. If an error was detected, the 82559ER always sets the Detected Parity Error bit in the
PCI Configuration Status register, bit 15. The 82559ER also asserts PERR#, if the Parity Error
Response bit is set (PCI Configuration Command register, bit 6). The 82559ER does not attempt to
terminate a cycle in which a parity error was detected. This gives the initiator the option of
recovery.
Target-Disconnect: The 82559ER prematurely terminate a cycle in the following cases:
• After accesses to the Flash buffer
• After accesses to its CSR
• After accesses to the configuration space
System Error: The 82559ER reports parity error during the address phase using the SERR# pin. If
the SERR# Enable bit in the PCI Configuration Command register or the Parity Error Response bit
are not set, the 82559ER only sets the Detected Parity Error bit (PCI Configuration Status register,
bit 15). If SERR# Enable and Parity Error Response bits are both set, the 82559ER sets the
Signaled System Error bit (PCI Configuration Status register, bit 14) as well as the Detected Parity
Error bit and asserts SERR# for one clock.
The 82559ER, when detecting system error, will claim the cycle if it was the target of the
transaction and continue the transaction as if the address was correct.
Note: The 82559ER will report a system error for any parity error during an address phase, whether or
not it is involved in the current transaction.
4.2.1.2
82559ER Bus Master Operation
As a PCI Bus Master, the 82559ER initiates memory cycles to fetch data for transmission or
deposit received data and for accessing the memory resident control structures. The 82559ER
performs zero wait state burst read and write cycles to the host main memory. Figure 7 and Figure
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8 depict memory read and write burst cycles. For bus master cycles, the 82559ER is the initiator
and the host main memory (or the PCI host bridge, depending on the configuration of the system) is
the target.
CLK
1
2
3
4
5
6
7
8
9
10
FRAME#
AD
ADDR
DATA
DATA
DATA
DATA
DATA
MR
BE#
BE#
C/BE#
IRDY#
TRDY#
DEVSEL#
Figure 7. Memory Read Burst Cycle
CLK
1
2
3
4
5
6
7
8
9
10
FRAME#
AD
ADDR
DATA
DATA
DATA
DATA
DATA
MW
BE#
BE#
C/BE#
IRDY#
TRDY#
DEVSEL#
Figure 8. Memory Write Burst Cycle
The CPU provides the 82559ER with action commands and pointers to the data buffers that reside
in host main memory. The 82559ER independently manages these structures and initiates burst
memory cycles to transfer data to and from them. The 82559ER uses the Memory Read Multiple
(MR Multiple) command for burst accesses to data buffers and the Memory Read Line (MR Line)
command for burst accesses to control structures. For all write accesses to the control structure, the
82559ER uses the Memory Write (MW) command. For write accesses to data structure, the
82559ER may use either the Memory Write or Memory Write and Invalidate (MWI) commands.
Read Accesses: The 82559ER performs block transfers from host system memory to perform
frame transmission on the serial link. In this case, the 82559ER initiates zero wait state memory
read burst cycles for these accesses. The length of a burst is bounded by the system and the
82559ER’s internal FIFO. The length of a read burst may also be bounded by the value of the
Transmit DMA Maximum Byte Count in the Configure command. The Transmit DMA Maximum
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Byte Count value indicates the maximum number of transmit DMA PCI cycles that will be
completed after an 82559ER internal arbitration. (Details on the Configure command are described
in the Software Developer’s Manual.)
The 82559ER, as the initiator, drives the address lines AD[31:0], the command and byte enable
lines C/BE#[3:0] and the control lines IRDY# and FRAME#. The 82559ER asserts IRDY# to
support zero wait state burst cycles. The target signals the 82559ER that valid data is ready to be
read by asserting the TRDY# signal.
Write Accesses: The 82559ER performs block transfers to host system memory during frame
reception. In this case, the 82559ER initiates memory write burst cycles to deposit the data, usually
without wait states. The length of a burst is bounded by the system and the 82559ER’s internal
FIFO threshold. The length of a write burst may also be bounded by the value of the Receive DMA
Maximum Byte Count in the Configure command. The Receive DMA Maximum Byte Count value
indicates the maximum number of receive DMA PCI transfers that will be completed before the
82559ER internal arbitration. (Details on the Configure command are described in the Software
Developer’s Manual.)
The 82559ER, as the initiator, drives the address lines AD[31:0], the command and byte enable
lines C/BE#[3:0] and the control lines IRDY# and FRAME#. The 82559ER asserts IRDY# to
support zero wait state burst cycles. The 82559ER also drives valid data on AD[31:0] lines during
each data phase (from the first clock and on). The target controls the length and signals completion
of a data phase by de-assertion and assertion of TRDY#.
Cycle Completion: The 82559ER completes (terminates) its initiated memory burst cycles in the
following cases:
• Normal Completion: All transaction data has been transferred to or from the target device
(for example, host main memory).
• Backoff: Latency Timer has expired and the bus grant signal (GNT#) was removed from the
82559ER by the arbiter, indicating that the 82559ER has been preempted by another bus
master.
• Transmit or Receive DMA Maximum Byte Count: The 82559ER burst has reached the
length specified in the Transmit or Receive DMA Maximum Byte Count field in the Configure
command block. (Details relating to this field and the Configure command are described in the
Software Developer’s Manual.)
• Target Termination: The target may request to terminate the transaction with a target-
disconnect, target-retry, or target-abort. In the first two cases, the 82559ER initiates the cycle
again. In the case of a target-abort, the 82559ER sets the Received Target-Abort bit in the PCI
Configuration Status field (PCI Configuration Status register, bit 12) and does not re-initiate
the cycle.
• Master Abort: The target of the transaction has not responded to the address initiated by the
82559ER (in other words, DEVSEL# has not been asserted). The 82559ER simply de-asserts
FRAME# and IRDY# as in the case of normal completion.
• Error Condition: In the event of parity or any other system error detection, the 82559ER
completes its current initiated transaction. Any further action taken by the 82559ER depends
on the type of error and other conditions.
4.2.1.2.1 Memory Write and Invalidate
The 82559ER has four Direct Memory Access (DMA) channels. Of these four channels, the
Receive DMA is used to deposit the large number of data bytes received from the link into system
memory. The Receive DMA uses both the Memory Write (MW) and the Memory Write and
Invalidate (MWI) commands. To use MWI, the 82559ER must guarantee the following:
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1. Minimum transfer of one cache line
2. Active byte enable bits (or BE#[3:0] are all low) during MWI access
3. The 82559ER may cross the cache line boundary only if it intends to transfer the next cache
line too.
To ensure the above conditions, the 82559ER may use the MWI command only if the following
conditions hold:
1. The Cache Line Size (CLS) written in the CLS register during PCI configuration is 8 or 16
Dwords.
2. The accessed address is cache line aligned.
3. The 82559ER has at least 8 or 16 Dwords of data in its receive FIFO.
4. There are at least 8 or 16 Dwords of data space left in the system memory buffer.
5. The MWI Enable bit in the PCI Configuration Command register, bit 4, should is set to 1b.
6. The MWI Enable bit in the 82559ER Configure command should is set to 1b. (Details on the
Configure command are described in the Software Developer’s Manual.)
If any one of the above conditions does not hold, the 82559ER will use the MW command. If a
MWI cycle has started and one of the conditions is no longer valid (for example, the data space in
the memory buffer is now less than CLS), then the 82559ER terminates the MWI cycle at the end
of the cache line. The next cycle will be either a MW or MWI cycle depending on the conditions
listed above.
If the 82559ER started a MW cycle and reached a cache line boundary, it either continues or
terminates the cycle depending on the Terminate Write on Cache Line configuration bit of the
82559ER Configure command (byte 3, bit 3). If this bit is set, the 82559ER terminates the MW
cycle and attempts to start a new cycle. The new cycle is a MWI cycle if this bit is set and all of the
above listed conditions are met. If the bit is not set, the 82559ER continues the MW cycle across
the cache line boundary if required. (Details on the Configure command are described in the
Software Developer’s Manual.)
4.2.1.2.2 Read Align
The Read Align feature enhances the 82559ER’s performance in cache line oriented systems. In
these particular systems, starting a PCI transaction on a non-cache line aligned address may cause
low performance.
To resolve this performance anomaly, the 82559ER attempts to terminate transmit DMA cycles on
a cache line boundary and start the next transaction on a cache line aligned address. This feature is
enabled when the Read Align Enable bit is set in the 82559ER Configure command (byte 3, bit 2).
(Details on the Configure command are described in the Software Developer’s Manual.)
If this bit is set, the 82559ER operates as follows:
• When the 82559ER is almost out of resources on the transmit DMA (that is, the transmit FIFO
is almost full), it attempts to terminate the read transaction on the nearest cache line boundary
when possible.
• When the arbitration counter’s feature is enabled (in other words, the Transmit DMA
Maximum Byte Count value is set in the Configure command), the 82559ER switches to other
pending DMAs on the cache line boundary only.
Note the following:
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• This feature is not recommended for use in non-cache line oriented systems since it may cause
shorter bursts and lower performance.
• This feature should be used only when the CLS register in PCI Configuration space is set to 8
or 16 Dwords.
• The 82559ER reads all control data structures (including Receive Buffer Descriptors) from the
first Dword (even if it is not required) to maintain cache line alignment.
4.2.1.2.3 Error Handling
Data Parity Errors: As an initiator, the 82559ER checks and detects data parity errors that occur
during a transaction. If the Parity Error Response bit is set (PCI Configuration Command register,
bit 6), the 82559ER also asserts PERR# and sets the Data Parity Detected bit (PCI Configuration
Status register, bit 8). In addition, if the error was detected by the 82559ER during read cycles, it
sets the Detected Parity Error bit (PCI Configuration Status register, bit 15).
4.2.2
Clockrun Signal
The CLKRUN# signal is used to control the PCI clock as defined in the PCI Mobile design guide
and is compliant with the PCI Mobile design guide. The Clockrun signal is an open drain I/O
signal. It is used as a bidirectional channel between the host and the devices.
• The host de-asserts the CLKRUN# signal to indicate that the PCI clock is about to be stopped
or slowed down to a non-operational frequency.
• The host asserts the CLKRUN# signal when the interface clock is either running at a normal
operating frequency or about to be started.
• The 82559ER asserts the CLKRUN# signal to indicate that it needs the PCI clock to prevent
the host from stopping the PCI clock or to request that the host restore the clock if it was
previously stopped.
Proper operation requires that the system latency from the nominal PCI CLK to CLKRUN#
assertion should be less than 0.5 µs. If the system latency is longer than 0.5 µs, the occurrence of
receive overruns increases. For use in these types of systems, the Clockrun functionality should be
disabled (see Section 8.1.12, “General Control Register” on page 61). In this case, the 82559ER
will claim the PCI clock even during idle time. If the CLKRUN# signal is not used, it should be
connected to a pull-down resistor (62KΩ). The value of the resistor selected is dependent on the
ND-TREE set-up used (i.e. the test fixture must be able to overdrive pull-down).
4.2.3
Power Management Event Signal
The 82559ER supports power management indications in the PCI mode. The PME# output pin
provides an indication of a power management event to the system. PCI Power Management
In addition to the base functionality of the 82558 B-step, the 82559 family supports a larger set of
wake-up packets and the capability to wake the system on a link status change from a low power
state. The 82559ER enables the host system to be in a sleep state and remain virtually connected to
the network. After a power management event or link status change is detected, the 82559ER will
wake the host system. The sections below describe these events, the 82559ER power states, and
estimated power consumption at each power state.
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4.2.4
Power States
The 82559ER’s power management register implements all four power states as defined in the
Power Management Network Device Class Reference Specification, Revision 1.0. The four states,
D0 through D3, vary from maximum power consumption at D0 to the minimum power
consumption at D3. PCI transactions are only allowed in the D0 state, except for host accesses to
the 82559ER’s PCI configuration registers. The D1 and D2 power management states enable
intermediate power savings while providing the system wake-up capabilities. In the D3cold state,
the 82559ER can provide wake-up capabilities only if auxiliary power is supplied. Wake-up
indications from the 82559ER are provided by the Power Management Event (PME#).
4.2.4.1
D0 Power State
As defined in the Network Device Class Reference Specification, the device is fully functional in
the D0 power state. In this state, the 82559ER receives full power and should be providing full
functionality. In the 82559ER the D0 state is partitioned into two substates, D0 Uninitialized (D0u)
and D0 Active (D0a).
D0u is the 82559ER’s initial power state following a PCI RST#. While in the D0u state, the
82559ER has PCI slave functionality to support its initialization by the host and supports wake up
events. Initialization of the CSR, Memory, or I/O Base Address Registers in the PCI Configuration
space switches the 82559ER from the D0u state to the D0a state.
In the D0a state, the 82559ER provides its full functionality and consumes its nominal power. In
addition, the 82559ER supports wake on link status change (see Section 4.2.5, “Wake-up Events”
on page 27). While it is active, the 82559ER requires a nominal PCI clock signal (in other words, a
clock frequency greater than 16 MHz) for proper operation. During idle time, the 82559ER
supports a PCI clock signal suspension using the Clockrun signal mechanism. The 82559ER
supports a dynamic standby mode. In this mode, the 82559ER is able to save almost as much
power as it does in the static power-down states. The transition to or from standby is done
dynamically by the 82559ER and is transparent to the software.
4.2.4.2
D1 Power State
In order for a device to meet the D1 power state requirements, as specified in the Advanced
Configuration and Power Interface (ACPI) Specification, Revision 1.0, it must not allow bus
transmission or interrupts; however, bus reception is allowed. Therefore, device context may be
lost and the 82559ER does not initiate any PCI activity. In this state, the 82559ER responds only to
PCI accesses to its configuration space and system wake-up events.
The 82559ER retains link integrity and monitors the link for any wake-up events such as wake-up
packets or link status change. Following a wake-up event, the 82559ER asserts the PME# signal to
alert the PCI based system.
4.2.4.3
D2 Power State
The ACPI D2 power state is similar in functionality to the D1 power state. If the bus is in the B2
state, the 82559ER will consume less current than it does in the D1 state. In addition to D1
functionality, the 82559ER can provide a lower power mode with wake-on-link status change
capability. The 82559ER may enter this mode if the link is down while the 82559ER is in the D2
state. In this state, the 82559ER monitors the link for a transition from an invalid link to a valid
link. The 82559ER will not attempt to keep the link alive by transmitting idle symbols or link
integrity pulses.1 The sub-10 mA state due to an invalid link can be enabled or disabled by a
configuration bit in the Power Management Driver Register (PMDR).
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4.2.4.4
D3 Power State
In the D3 power state, the 82559ER has the same capabilities and consumes the same amount of
power as it does in the D2 state. However, it enables the PCI system to be in the B3 state. If the PCI
system is in the B3 state (in other words, no PCI power is present), the 82559ER provides wake-up
capabilities if it is connected to an auxiliary power source in the system. If PME is disabled, the
82559ER does not provide wake-up capability or maintain link integrity. In this mode the 82559ER
consumes its minimal power.
The 82559ER enables a system to be in a sub-5 watt state (low power state) and still be virtually
connected. More specifically, the 82559ER supports full wake-up capabilities while it is in the
D3cold state. The 82559ER can be connected to an auxiliary power source (VAUX), which enables it
to provide wake-up functionality while the PCI power is off. The typical current consumption of
the 82559ER is 125 mA at 3.3 V. Thus, a dual power plane is not required. If connected to an
auxiliary power source, the 82559ER receives all of its power from the auxiliary source in all
power states.
4.2.4.5
Understanding Power Requirements
When running the 82559ER off a 3.3V_standby power source, the actual power consumption will
scale with network traffic. In other words, if the 82559ER is monitoring the network for ACPI
“Interesting Packets” only the PCI bus specific circuitry will be disabled. As an a example the
8259ER will typically draw approximately 120mA, in D1-D3 under a full Ethernet load. In the D0
state, the 82559ER will typically consume 125mA under the same load conditions.
The tables below summarizes the 82559ER’s functionality and power consumption at the different
power states
Power State
D0
Conditions
100 Mbs
175 mA
10 Mbs
140 mA
Maximum
D0
D0
Average (5 Mbs)
125 mA
120 mA
115 mA
55 mA
Dynamic standby
(With Network Load)
PCI CLK
10 mA
3 mA
10 mA
3 mA
D2/D3 (link
down)
w/o PCI CLK
PCI CLK
10 mA
3 mA
10 mA
3 mA
Dx (x>0 with
PME# disabled)
w/o PCI CLK
All values shown for the D3 state assume the availability of 3.3 V Standby available to the
device.
NOTE:
1. For a topology of two 82559ER devices connected by a crossed twisted-pair Ethernet cable, the deep power-down mode should be
disabled. If it is enabled, the two devices may not detect each other if the operating system places them into a low power state before both
nodes become active.
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.
Power State
D0u
Link
82559ER Functionality
•
•
Power-up state
PCI slave access
Don’t care
Full functionality at full power and wake on invalid
link
Valid
D0a
D1
Invalid
Full functionality at full power and wake on valid link
•
•
Wake-up on “interesting” packets and link
invalid
Valid
PCI configuration access
•
•
Wake on link valid
Invalid
PCI configuration access
Valid
Same functionality as D1 (link valid)
Detection for valid link and no link integrity
Same functionality as D1 (link valid)
Detection for valid link and no link integrity
D2
Invalid
Valid
D3 (with power)
Invalid
Dx (x>0 without
PME#)
Don’t Care
No wake-up functionality
4.2.4.6
Auxiliary Power Signal
The 82559ER senses whether it is connected to the PCI power supply or to an auxiliary power
supply (VAUX) via the FLA1/AUXPWR pin. The auxiliary power detection pin (multiplexed with
FLA1) is sampled when the PCI RST# or ALTRST# signals are active. An external pull-up resistor
should be connected to the 82559ER if it is fed by VAUX; otherwise, the FLA1/AUXPWR pin
should be left floating. The presence of AUXPWR affects the value reported in the Power
Management Capability Register (PCI Configuration Space, offset DEH). The Power Management
Capability Register is described in more detail in Section 7.1.18, “Power Management Capabilities
Register” on page 54.
4.2.4.7
Alternate Reset Signal
The 82559ER’s ALTRST# input pin functions as a power-on reset input. Following ALTRST#
being driven low, the 82559ER is initialized to a known state. In systems that support auxiliary
power, this pin should be connected to the auxiliary power’s power stable signal (power good) of
the 82559ER’s power source. In a LAN on Motherboard solution, this signal is available on the
system. In network adapter implementations, an external analog device connected to the auxiliary
power supply can be used to produce this signal. In systems that do not have an auxiliary power
source, the ALTRST# signal should be tied to a pull-up resistor.
4.2.4.7.1 Isolate Signal
When the 82559ER is connected to VAUX, it may be powered on while the PCI bus is powered off.
In this case, the 82559ER isolates itself from the PCI bus. The 82559ER has a dedicated
ISOLATE# pin that should be connected to the PCI power source’s stable power signal (power
good). Whenever the PCI Bus is in the B3 state, the PCI power good signal becomes inactive and
the 82559ER isolates itself from the PCI bus. During this state, the 82559ER ignores all PCI
signals including the RST# and CLK signals. It also tri-states all PCI outputs, except the PME#
signal. In the transition to an active PCI power state (in other words, from B3 power state to B0
power state), the PCI power good signal shifts high.
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In a LAN on Motherboard solution, the PCI power good signal is supplied by the system. In
network adapter implementations, the PCI power good signal can be either generated locally using
an external analog device, or connected directly to the PCI reset signal. In designs, that use both the
ISOLATE# and RST# pins of the 82559ER, the PCI power good signal should envelope
ISOLATE#, as shown below. For designs that use the PCI reset signal, the RST# pin on the
82559ER should be tied to the PCI power rail (through a 4.7ΚΩ), and the PCI reset signal should
be connected to the 82559ER’s ISOLATE# pin.
PCI power good signal
Required ISOLATE#
signal behavior
Figure 9. Isolate Signal Behavior to PCI Power Good Signal
In many systems, the PCI RST# signal is asserted low whenever the PCI bus is inactive. In these
systems, the 82559ER B-step device and later devices allow the ISOLATE# pin to be driven from
the PCI RST# signal. In this case, the ALTRST# pin on the 82559ER should be pulled high to the
PCI bus high voltage level.
4.2.4.7.2 PCI Reset Signal
The PCI RST# signal may be activated in one of the following cases:
• Power-up
• Warm boot
• Wake-up (B3 to B0 transition)
• Set to power-down (B0 to B3 transition)
If PME is enabled (in the PCI power management registers), the RST# signal does not affect any
PME related circuits (in other words, PCI power management registers, and the wake-up packet
would not be affected). While the RST# signal is active, the 82559ER ignores other PCI signals
and floats its outputs. However, if AUXPWR is asserted, the RST# signal has no affect on any
circuitry.
While the 82559ER is in the D0, D1, or D2 power state, it is initialized by the RST# level. When
the 82559ER is in the D3 power state, the system bus may be in the B3 bus power state. In the B3
power state, the PCI RST# signal is undefined; however, the auxiliary power source proposal for
the PCI Specification, Revision 2.2 is for the PCI RST# signal to be an active low. Therefore, the
82559ER uses the PCI RST# similarly to the ISOLATE# signal in D3 power state. Following the
trailing edge of the PCI RST#, the 82559ER is initialized while preserving the PME# signal and its
context.
Note: According to the PCI specification, during the B3 state, the RST# signal is undefined.
The transition from the B3 power state to the B0 power state occurs on the trailing edge of the
RST# signal.
The initialization signal is generated internally in the following cases:
• Active RST# signal while the 82559ER is the D0, D1, or D2 power state
• RST# trailing edge while the 82559ER is in the D3 power state
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• ISOLATE# trailing edge
The internal initialization signal resets the PCI Configuration Space, MAC configuration, and
memory structure.
The behavior of the PCI RST# signal and the internal 82559ER initialization signal are shown in
the figure below.
D0 - D2 power state
PCI RST#
Internal hardware
reset
D3 power state
PCI RST#
Internal hardware
reset
640 ns
Internal reset
due to ISOLATE#
ISOLATE#
Internal hardware
reset
640 ns
Figure 10. 82559ER Initialization upon PCI RST# and ISOLATE#
4.2.5
Wake-up Events
There are two types of wake-up events: “Interesting” Packets and Link Status Change. These two
events are detailed below.
Note: The wake-up event is supported only if the PME Enable bit in the Power Management Control/
Status (PMCSR) register is set. (The PMCSR is described in Section 7.1.19, “Power Management
Control/Status Register (PMCSR)” on page 55.)
4.2.5.1
“Interesting” Packet Events
In the power-down state, the 82559ER is capable of recognizing “interesting” packets. The
82559ER supports pre-defined and programmable packets that can be defined as any of the
following:
• ARP Packets (with Multiple IP addresses)
• Direct Packets (with or without type qualification)
• Neighbor Discovery Multicast Address Packet (‘ARP’ in IPv6 environment)
• NetBIOS over TCP/IP (NBT) Query Packet (under IPv4)
• Internetwork Package Exchange* (IPX) Diagnostic Packet
This allows the 82559ER to handle various packet types. In general, the 82559ER supports
programmable filtering of any packet in the first 128 bytes.
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4.2.5.2
Link Status Change Event
The 82559ER link status indication circuit is capable of issuing a PME on a link status change from
a valid link to an invalid link condition or vice versa. The 82559ER reports a PME link status event
in all power states. The PME# signal is gated by the PME Enable bit in the PMCSR and the CSMA
Configure command, which is described in the Software Developer’s Manual.
4.3
Parallel Flash Interface
The 82559ER’s parallel interface is used primarily as a Flash interface. The 82559ER supports a
glueless interface to an 8-bit wide, 128 Kbyte, parallel memory device.
The Flash (or boot PROM) is read from or written to whenever the host CPU performs a read or a
write operation to a memory location that is within the Flash mapping window. All accesses to the
Flash, except read accesses, require the appropriate command sequence for the device used. (Refer
to the specific Flash data sheet for more details on reading from or writing to the Flash device.) The
accesses to the Flash are based on a direct decode of CPU accesses to a memory window defined in
either the 82559ER Flash Base Address Register (PCI Configuration space at offset 18H) or the
Expansion ROM Base Address Register (PCI Configuration space at offset 30H). The 82559ER
asserts control to the Flash when it decodes a valid access.
The 82559ER supports an external Flash memory (or boot PROM) of up to 128 Kbyte. The
Expansion ROM BAR can be separately disabled by setting the corresponding bit in the EEPROM,
word AH.
Note: Flash accesses must always be assembled or disassembled by the 82559ER whenever the access is
greater than a byte-wide access. Due to slow access times to a typical Flash and to avoid violating
PCI bus holding specifications (no more than 16 wait states inserted for any cycles that are not
system initiation cycles), the maximum data size is either one word or one byte for a read operation
and one byte only for a write operation.
4.4
Serial EEPROM Interface
The serial EEPROM stores configuration data for the 82559ER and is a serial in/serial out device.
The 82559ER supports a either a 64 register or 256 register size EEPROM and automatically
detects the EEPROM’s size. The EEPROM should operate at a frequency of at least 1 MHz.
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All accesses, either read or write, are preceded by a command instruction to the device. The
address field is six bits for a 64 register EEPROM or eight bits for a 256 register EEPROM. The
end of the address field is indicated by a dummy zero bit from the EEPROM, which indicates the
entire address field has been transferred to the device. An EEPROM read instruction waveform is
shown in the figure below.
EESK
EECS
A5
A4
A2
A1
A0
A3
EEDI
READ OP code
D15
D0
EEDO
Figure 11. 64 Word EEPROM Read Instruction Waveform
The 82559ER performs an automatic read of seven words (0H, 1H, 2H, AH, Bh, Ch and DH) of the
EEPROM after the de-assertion of Reset.
The 82559ER EEPROM format is shown below in Figure 12.
Word 15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0H
1H
2H
AH
IA Byte 2
IA Byte 4
IA Byte 6
IA Byte 1
IA Byte 3
IA Byte 5
00b
Sig
ID
0b
BD
Rev ID
1b
DPD
0b
0b
STB
Ena
0b
BH
CH
DH
Subsystem ID
Subsystem Vendor ID
Reserved
Figure 12. 82559ER EEPROM Format
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Note that word 0Ah contains several configuration bits. Bits from word 0Ah, FBh through FEh,
and certain bits from word 0Dh are described as follows:
Table 1. EEPROM Words Field Descriptions
Word
Bits
5:14
Name
Signature
Description
The Signature field is a signature of 01b, indicating to the 82559ER that there is
a valid EEPROM present. If the Signature field is not 01b, the other bits are
ignored and the default values are used.
13
12
11
Reserved
Reserved Default value is 0b.
Reserved
This bit is reserved and should be set to 0b.
Boot Disable
The Boot Disable bit disables the Expansion ROM Base Address Register (PCI
Configuration space, offset 30H) when it is set. Default value is 0b.
10:8
Revision ID
These three bits are used as the three least significant bits of the device
revision, if bits 15, 14, and 13 equal 011b and the ID was set as described in
Section 7.1.10, “PCI Subsystem Vendor ID and Subsystem ID Registers” on
page 53. The default value depends on the silicon revision.
7
6
Reserved
Reserved and should be set to 0b
Deep Power
Down
This bit is used as the Deep Power Down enable/disable bit. When the DPD bit
equals 0b, deep power down is enabled in the D3 power state while PME is
disabled. If the DPD bit equals 1b, deep power down is disabled in the D3
power state while PME is disabled.
5
Reserved
Reserved
Reserved and should be set to 0b.
4:3
2
These are reserved and should be set to 00b.
1
Standby Enable
The Standby Enable bit enables the 82559ER to enter standby mode. When
this bit equals 1b, the 82559ER is able to recognize an idle state and can enter
standby mode (some internal clocks are stopped for power saving purposes).
The 82559ER does not require a PCI clock signal in standby mode. If this bit
equals 0b, the idle recognition circuit is disabled and the 82559ER always
remains in an active state. Thus, the 82559ER will always request PCI CLK
using the Clockrun mechanism.
0
Reserved
Reserved
Reserved
Reserved
Set this bit equal to 0b for compatibility.
Reserved.
11:8
7:0
D
FBh - ALL
FEh
Note: The IA read from the EEPROM is used by the 82559ER until an IA Setup command is issued by
software. The IA defined by the IA Setup command overrides the IA read from the EEPROM.
4.5
10/100 Mbps CSMA/CD Unit
The 82559ER CSMA/CD unit implements both the IEEE 802.3 Ethernet 10 Mbps and IEEE
802.3u Fast Ethernet 100 Mbps standards. It performs all the CSMA/CD protocol functions such as
transmission, reception, collision handling, etc. The 82559ER CSMA/CD unit interfaces the
internal PHY unit through a standard Media Independent Interface (MII), as specified by IEEE
802.3, Chapter 22. This is a 10/100 Mbps mode in which the data stream is nibble-wide and the
serial clocks run at either 25 or 2.5 MHz.
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4.5.1
Full Duplex
When operating in full duplex mode the 82559ER can transmit and receive frames simultaneously.
Transmission starts regardless of the state of the internal receive path. Reception starts when the
internal PHY detects a valid frame on the receive differential pair of the PHY.
The 82559ER operates in either half duplex mode or full duplex mode. For proper operation, both
the 82559ER CSMA/CD module and the PHY unit must be set to the same duplex mode. The
CSMA duplex mode is set by the 82559ER Configure command or forced by automatically
tracking the mode in the PHY unit.
The PHY duplex mode is set either by Auto-Negotiation or, if Auto-Negotiation is disabled, by
setting the full duplex bit in the Management Data Interface (MDI) Register 0, bit 8. By default, the
internal PHY unit advertises full duplex ability in the Auto-Negotiation process regardless of the
duplex setting of the CSMA unit. The CSMA configuration should match the result of the Auto-
Negotiation.
The selection of duplex operation (full or half) and flow control is done in two levels: MAC and
PHY. The MAC duplex selection is done only through CSMA configuration mechanism (in other
words, the Configure command from software).
4.5.2
Flow Control
The 82559ER supports IEEE 802.3x frame based flow control frames only in both full duplex and
half duplex switched environments. The 82559ER flow control feature is not intended to be used in
shared media environments.
Flow control is optional in full duplex mode and can be selected through software configuration.
There are three modes of flow control that can be selected: frame based transmit flow control,
frame based receive flow control, and none.
The PHY unit’s duplex and flow control enable can be selected using NWay* Auto-Negotiation
algorithm or through the Management Data Interface.
4.5.3
Address Filtering Modifications
The 82559ER can be configured to ignore one bit when checking for its Individual Address (IA) on
incoming receive frames. The address bit, known as the Upper/Lower (U/L) bit, is the second least
significant bit of the first byte of the IA. This bit may be used, in some cases, as a priority
indication bit. When configured to do so, the 82559ER passes any frame that matches all other 47
address bits of its IA, regardless of the U/L bit value.
This configuration only affects the 82559ER specific IA and not multicast, multi-IA or broadcast
address filtering. The 82559ER does not attribute any priority to frames with this bit set, it simply
passes them to memory regardless of this bit.
4.5.4
Long Frame Reception
The 82559ER supports the reception of long frames, specifically frames longer than 1518 bytes,
including the CRC, if software sets the Long Receive OK bit in the Configuration command
(described in the Software Developer’s Manual). Otherwise, “long” frames are discarded.
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4.6
Media Independent Interface (MII) Management Interface
The MII management interface allows the CPU to control the PHY unit via a control register in the
82559ER. This allows the software driver to place the PHY in specific modes such as full duplex,
loopback, power down, etc., without the need for specific hardware pins to select the desired mode.
This structure allows the 82559ER to query the PHY unit for status of the link. This register is the
MDI Control Register and resides at offset 10h in the 82559ER CSR. (The MDI registers are
described in detail in Section 9., “PHY Unit Registers” on page 65.) The CPU writes commands to
this register and the 82559ER reads or writes the control/status parameters to the PHY unit through
the MDI register. Although the 82559ER follows the MII format, the MI bus is not accessible on
external pins.
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5.
GD82559ER Test Port Functionality
5.1
Introduction
The 82559ER’s NAND-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. The port pro-
vides two functions:
1) The the synchronous IC validation mode used in the production of the device. This mode gives
the signals their names (i.e TCK, Testability Port Clock).
2) In addition to the synchronous test mode, the 82559ER supports asynchonous testing modes.
These test modes support the validation of connections at the board level.
5.2
Asynchronous Test Mode
Four asynchronous test modes are supported for system level design use. The modes are selected
through the use of Test Port input pin in static combinations. The Test Port pins are: TEST, TI,
TEXEC and TCK. During normal operation the Test pin 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 design-
ers discretion.
5.3
5.4
Test Function Description
The 82559 TAP mode supports several tests that can be used in board level design. These tests can
help in the verification of basic functionality. As well as test the integrity of solder connection on
the board. The tests are as follows:
85/85
The 85/85 test provides the same functionality to the board level designer as the Tristate mode.
This mode is normal used during chip the chip burn-in cycling. The 82559ER is placed in this
mode during the 85o/85% humidity test cycling. Test Pin Combinations: TEST = ‘1, TCK = ‘0,
TEXEC = ‘1, TI = ‘1
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5.5
5.6
TriState
This command set all 82559ER Input and Output pins into a TRI-state (HIGH-Z) mode, all internal
pull-ups and pull-downs are disabled. This mode is entered by setting the following Test Pin Com-
binations: TEST = ‘1, TCK = ‘0, TEXEC = ‘0, TI = ‘1, and resetting the device.
Nand - Tree
The NAND-Tree test mode is the most useful of the asynchronous test modes. The test enables the
placement of the 82559ER to be validated at board test. NAND-Tree was chosen for its speed
advantages. Modern automated test equipment can complete a complete peripheral scan without
support at the board level. This command connects all the outputs of the input-buffers in the device
periphery into a NAND - tree scheme. All the output drivers of the output-buffers except the TOUT
pin, are put into HIGH-Z mode. These pins can then be driven to affect the output of the tree. There
are two separate chains and associated outputs for speed. Any hard strapped pins will prevent the
tester from scanning correctly. This mode is enter by placing the Test Pin in the following Combi-
nations: TEST = ‘1, TCK = ‘0, TEXEC = ‘1, TI = ‘0
There are two nand-tree chains with two separate outputs assigned to FLOE# (Chain 1) and
FLWE# (Chain 2).
Table 2. Nand - Tree Chains
Chain Order
Chain 1
Chain 2
1
2
RST#
IDSEL
REQ#
AD23
LILED
ACTLED#
SPEEDLED
ISOLATE#
ALTRST#
CLKRUN#
AD31
3
4
5
SERR#
AD22
6
7
AD21
8
AD20
AD30
9
AD19
AD29
10
11
12
13
14
15
16
17
18
AD18
AD28
AD17
AD27
C/BE2#
FRAME#
IRDY#
TRDY#
CLK
PME#
AD26
AD25
C/BE3#
AD24
DEVSEL#
INTA#
FLD0
FLD1
NAND-Tree Output
FLOE#
FLWE#
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Table 2. Nand - Tree Chains
Chain Order
Chain 1
Chain 2
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
37
39
40
41
42
43
44
45
46
STOP#
GNT#
PERR#
PAR
FLD2
FLD3
FLD4
FLD5
AD16
C/BE1#
AD15
AD14
AD13
AD12
AD11
AD10
AD9
FLD6
FLD7
FLA0
FLA1
FLA2
FLA3
FLA4
FLA5
FLA6
AD8
FLA7
C/BE0#
AD7
FLA8
FLA9
AD6
FLA10
FLA11
FLA12
FLA13/EEDI
FLA14/EEDO
FLA15/EESK
FLA16
FLCS#
AD5
AD4
AD3
AD2
AD1
AD0
EECS
NAND-Tree Output
FLOE#
FLWE#
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6.
GD82559ER Physical Layer Functional Description
6.1
100BASE-TX PHY Unit
6.1.1
100BASE-TX Transmit Clock Generation
A 25 MHz crystal or a 25 MHz oscillator is used to drive the PHY unit’s X1 and X2 pins. The PHY
unit derives its internal transmit digital clocks from this crystal or oscillator input. The internal
Transmit Clock signal is a derivative of the 25 MHz internal clock. The accuracy of the external
crystal or oscillator must be ± 0.0005% (50 PPM).
6.1.2
100BASE-TX Transmit Blocks
The transmit subsection of the PHY unit accepts nibble-wide data from the CSMA/CD unit. The
transmit 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 5-
bit-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.
6.1.2.1
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.
The table below illustrates the 4B/5B encoding scheme associated with the given symbol.
Table 3. 4B/5B Encoder
Symbol
5B Symbol Code
4B Nibble Code
0
1
2
3
4
5
6
7
8
9
A
B
C
D
11110
01001
10100
10101
01010
01011
01110
01111
10010
10011
10110
10111
11010
11011
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
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Table 3. 4B/5B Encoder
Symbol
5B Symbol Code
4B Nibble Code
E
F
11100
11101
1110
1111
Inter Packet Idle Symbol
(No 4B)
I
11111
11000
1st Start of Packet Symbol
0101
J
2nd Start of Packet Symbol
0101
K
T
10001
01101
00111
1st End of Packet Symbol
2nd End of Packet Symbol
and Flow Control
R
V
V
V
V
H
V
V
V
V
V
V
00000
00001
00010
00011
00100
00101
00110
01000
01100
10000
11001
INVALID
INVALID
INVALID
INVALID
INVALID
INVALID
INVALID
INVALID
INVALID
PHY based Flow Control
INVALID
6.1.2.2
100BASE-TX Scrambler and MLT-3 Encoder
Data is scrambled in 100BASE-TX 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 PHY unit 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 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 NRZI
coding, but three levels are output instead of two. There are three output levels: 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.
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Clock
NRZ
1
1
0
0
1
0
0
1
1
1
1
1
0
0
0
0
1
1
0
0
0
0
1
1
NRZ1
MLT-3
Figure 13. NRZ to MLT-3 Encoding Diagram
6.1.2.3
6.1.2.4
100BASE-TX Transmit Framing
The PHY unit does not differentiate between the fields of the MAC frame containing preamble,
Start of Frame Delimiter, data and Cyclic Redundancy Check (CRC). The PHY unit 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 PHY unit scrambles and
serializes the data into a 125 Mbps stream, encodes it as MLT-3, and drives it onto the wire.
Transmit Driver
The transmit differential pair lines are implemented with a digital slope controlled current driver
that meets the TP-PMD specifications. Current is sinked from the isolation transformer by the TDP
and TDN pins. The conceptual transmit differential waveform for 100 Mbps is illustrated in the
following figure.
(VTDP -VTDN
)
+1V
0V
t
-1V
Figure 14. Conceptual Transmit Differential Waveform
The magnetics module that is external to the PHY unit converts ITDP and ITDN to the 2.0 Vpp, as
required by the TP-PMD specification. The same magnetics used for 100BASE-TX mode should
also work in 10BASE-T mode. The following is a list of current magnetics modules available from
several vendors:
Table 4. Magnetics Modules
Vendor
Model/Type
100BASE-TX
10BASE-T
Delta
LF8200A
PE-68515
H1012
Yes
Yes
Yes
Yes
Yes
Yes
Pulse Engineering
Pulse Engineering
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6.1.3
100BASE-TX Receive Blocks
The receive subsection of the PHY unit accepts 100BASE-TX MLT-3 data on the receive
differential pair. Due to the advanced digital signal processing design techniques employed, the
PHY unit will accurately receive valid data from Category-5 (CAT5) UTP and Type 1 STP cable of
length well in excess of 100 meters.
6.1.3.1
6.1.3.2
6.1.3.3
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.
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.
MLT-3 Decoder, Descrambler, and Receive Digital Section
The PHY unit first decodes the MLT-3 data; afterwards, the descrambler reproduces the 5B
symbols originated in the transmitter. The descrambling is based on synchronization to the transmit
11-bit Linear Feedback Shift Register (LFSR) during idle. The data is decoded at the 4B/5B
decoder. Once the 4B symbols are obtained, the PHY unit outputs the receive data to the CSMA
unit.
6.1.3.4
100BASE-TX Receive Framing
The PHY unit does not differentiate between the fields of the MAC frame containing preamble,
start of frame delimiter, data and CRC. During 100 Mbps reception, the PHY unit differentiates
between the idle condition ("L" symbols on the wire) and the preamble or start of frame delimiter.
When two non-consecutive bits are 0b within 10 bits (125 Mbps 5B data coding) the PHY unit
immediately asserts carrier sense. When the “JK” symbols (“11000, 10001”) are fully recognized,
the PHY unit provides the received data to the CSMA unit. If the “JK” symbol is not recognized
(“false carrier sense”), the carrier sense is immediately de-asserted and a receive error is indicated.
6.1.3.5
100BASE-TX Receive Error Detection and Reporting
In 100BASE-TX mode, the PHY unit 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 (SSD) “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).
When any of the above error conditions occurs, the PHY unit immediately asserts its receive error
indication to the CSMA unit. The receive error indication is held active as long as the receive error
condition persists on the receive pair.
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6.1.4
6.1.5
100BASE-TX Collision Detection
100BASE-TX collisions in half duplex mode only are detected similarly to 10BASE-T collision
detection, via simultaneous transmission and reception.
100BASE-TX Link Integrity and Auto-Negotiation Solution
The 82559 Auto-Negotiation function automatically configures the device to the technology,
media, and speed to operate with its link partner. Auto-Negotiation is widely described in IEEE
specification 802.3u, clause 28. The PHY unit supports 10BASE-T half duplex, 10BASE-T full
duplex, 100BASE-TX half duplex, and 100BASE-TX full duplex.
The PHY unit has two Physical Media Attachment (PMA) technologies with its link integrity
function, 10BASE-T and 100BASE-TX.
6.1.5.1
6.1.5.2
Link Integrity
In 100BASE-TX, the link integrity function is determined by a stable signal status coming from the
TP-PMD block. Signal status is asserted when the PMD detects breaking squelch energy and the
right bit error rate according to the ANSI specification.
Auto-Negotiation
The PHY unit fully supports IEEE 802.3u, clause 28. The technology, 10BASE-T or 100BASE-
TX, is determined by the Auto-Negotiation result.
Speed and duplex auto-select are functions of Auto-Negotiation. However, these parameters may
be manually configured via the MII management interface (MDI registers).
6.1.6
Auto 10/100 Mbps Speed Selection
The MAC may either allow the PHY unit to automatically select its operating speed or force the
PHY into 10 Mbps or 100 Mbps mode. The Management Data Interface (MDI) can control the
PHY unit speed mode.
The PHY unit auto-select function determines the operation speed of the media based on the link
integrity pulses it receives. If no Fast Link Pulses (FLPs) are detected and Normal Link Pulses
(NLPs) are detected, the PHY unit defaults to 10 Mbps operation. If the PHY unit detects a speed
change, it dynamically changes its transmit clock and receive clock frequencies to the appropriate
value. This change takes a maximum of five milliseconds.
6.2
10BASE-T Functionality
6.2.1
10BASE-T Transmit Clock Generation
The 20 MHz and 10 MHz clocks needed for 10BASE-T are synthesized from the external 25 MHz
crystal or oscillator. The PHY unit provides the transmit clock and receive clock to the internal
MAC at 2.5 MHz.
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6.2.2
10BASE-T Transmit Blocks
6.2.2.1
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. If the
value is 1b then the transition is from low to high. If the value is 0b then the transition is from high
to low. The boundary transition occurs only when the data changes from bit to bit. For example, if
the value is 10b, then the change is from high to low; if 01b, then the change is from low to high.
6.2.2.2
10BASE-T Driver and Filter
Since 10BASE-T and 100BASE-TX have different filtration needs, both filters are implemented
inside the chip. This allows the two technologies to share the same magnetics. The PHY unit
supports both technologies through one pair of TD pins and by externally sharing the same
magnetics.
In 10 Mbps mode, the PHY unit begins transmitting the serial Manchester bit stream within 3 bit
times (300 nanoseconds) after the MAC asserts TXEN. 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” (100ns) Manchester pulses and maintain a full drive level during all narrow
(50ns) pulses and the first half of the wide pulses. This reduces line overcharging during wide
pulses, a major source of jitter.
6.2.3
10BASE-T Receive Blocks
10BASE-T Manchester Decoder
6.2.3.1
The PHY unit performs Manchester decoding and timing recovery when in 10 Mbps mode. The
Manchester-encoded data stream is decoded from the RD pair to separate Receive Clock and
Receive Data from the differential signal. This data is transferred to the CSMA unit at 2.5 MHz/
nibble. The high-performance circuitry of the PHY unit exceeds the IEEE 802.3 jitter
requirements.
6.2.3.2
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 PHY unit 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:
• 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
nanoseconds) of silence.
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All other activity is determined to be either data, link test pulses, Auto-Negotiation fast link pulses,
or the idle condition. When activity is detected, the carrier sense signal is asserted to the MAC.
6.2.3.3
10BASE-T Error Detection and Reporting
In 10 Mbps mode, the PHY unit can detect errors in the receive data. The following condition is
considered an error:
The receive pair’s voltage level drops to the idle state during reception before the end-of-frame
bit is detected (250 nanoseconds without mid-bit transitions).
6.2.4
6.2.5
10BASE-T Collision Detection
Collision detection in 10 Mbps mode is indicated by simultaneous transmission and reception. If
the PHY unit detects this condition, it asserts a collision indication to the CSMA/CD unit.
10BASE-T Link Integrity
The link integrity in 10 Mbps works with link pulses. The PHY unit senses and differentiates those
link pulses from fast link pulses and from 100BASE-TX idles. The 10 Mbps link pulses or normal
link pulses are driven in the transmit differential pair line but are 100 ns wide and have levels from
0 V to 5 V. The link beat pulse is also used to determine if the receive pair polarity is reversed. If it
is, the polarity is corrected internally.
6.2.6
6.2.7
10BASE-T Jabber Control Function
The PHY unit contains a jabber control function that inhibits transmission after a specified time
window when enabled. In 10 Mbps mode, the jabber timer is set to a value between 26.2 ms and 39
ms. If the PHY unit detects continuous transmission that is greater than this time period, it prevents
further transmissions from onto the wire until it detects that the MAC transmit enable signal has
been inactive for at least 314 ms.
10BASE-T Full Duplex
The PHY unit supports 10 Mbps full duplex by disabling the collision function, the squelch test,
and the carrier sense transmit function. This allows the PHY unit to transmit and receive
simultaneously, achieving up to 20 Mbps of network bandwidth. The configuration can be achieved
through Auto-Negotiation. Full duplex should only be used in point-to-point connections (no
shared media).
6.3
Auto-Negotiation Functionality
The PHY unit supports Auto-Negotiation. Auto-Negotiation is an automatic configuration scheme
designed to manage interoperability in multifunctional LAN environments. It allows two stations
with “N” different modes of communication to establish a common mode of operation. At power-
up, Auto-Negotiation automatically establishes a link that takes advantage of an Auto-Negotiation
capable device. An Auto-Negotiation capable device can detect and automatically configure its
port to take maximum advantage of common modes of operation without user intervention or prior
knowledge by either station. The possible common modes of operation are: 100BASE-TX,
100BASE-TX Full Duplex, 10BASE-T, and 10BASE-T Full Duplex.
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6.3.1
Description
Auto-Negotiation selects the fastest operating mode (in other words, the highest common
denominator) available to hardware at both ends of the cable. A PHY’s capability is encoded by
bursts of link pulses called Fast Link Pulses (FLPs). Connection is established by FLP exchange
and handshake during link initialization time. Once the link is established by this handshake, the
native link pulse scheme resumes (that is, 10BASE-T or 100BASE-TX link pulses). A reset or
management renegotiate command (through the MDI interface) will restart the process. To enable
Auto-Negotiation, bit 12 of the MDI Control Register must be set. If the PHY unit cannot perform
Auto-Negotiation, it will set this bit to a 0 and determine the speed using Parallel Detection.
The PHY unit supports four technologies: 100BASE-Tx Full and Half Duplex and 10BASE-T Full
and Half Duplex. Since only one technology can be used at a time (after every re-negotiate
command), a prioritization scheme must be used to ensure that the highest common denominator
ability is chosen. Each bit in this table is set according to what the PHY is capable of supporting. In
the case of the 82559’s PHY unit, bits 0, 1, 2, 3, and 5 (10BASE-T, 10BASE-T full duplex,
100BASE-TX, 100BASE-TX full duplex and pause [frame based flow control], respectively) are
set.
To detect the correct technology, the two register fields, technology ability and technology priority,
should be ANDed together to obtain the highest common denominator. This value should then be
used to map into a priority resolution table used by the MAC driver to use the appropriate
technology.
6.3.2
Parallel Detect and Auto-Negotiation
The PHY unit automatically determines the speed of the link either by using Parallel Detect or
Auto-Negotiation. Upon a reset, a link status fail, or a Negotiate/Re-negotiate command, the PHY
unit inserts a long delay during which no link pulses are transmitted. This period, known as
Force_Fail, insures that the PHY unit‘s link partner has gone into a Link Fail state before Auto-
Negotiation or Parallel Detection begins. Thus, both sides (PHY unit and PHY unit’s link partner)
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will perform Auto-Negotiation or Parallel Detection with no data packets being transmitted.
Connection is then established either by FLP exchange or Parallel Detection. The PHY unit will
look for both FLPs and link integrity pulses. The following diagram illustrates this process.
Force_Fail
Ability detect either by
parallel detect or auto-
negotiation.
Parallel Detection
Auto-Negotiation
10Base-T or
100Base-TX Link
Ready
FLP capable
Look at Link Pulse;
Auto-Negotiation capable = 0
Auto-Negotiation capable = 1
Ability Match
LINK PASS
Auto-Negotiation Complete bit set
Figure 15. Auto-Negotiation and Parallel Detect
6.4
LED Description
The PHY unit supports three LED pins to indicate link status, network activity and network speed.
Each pin can source 10 mA.
• Link: This LED is off until a valid link has been detected. After a valid link has been detected,
the LED will remain on (active-low).
• Activity: This LED blinks on and off when activity is detected on the wire.
• Speed: This LED will be on if a 100BASE-TX link is detected and off if a 10BASE-T link is
detected. If the link fails while in Auto-Negotiation, this LED will keep the last valid link
state. If 100BASE-TX link is forced this LED will be on, regardless of the link status. This
LED will be of if the 10BASE-T link is forced, regardless of the link status.
MDI register 27 in Section 9.3.12, “Register 27: PHY Unit Special Control Bit Definitions” on
page 71 details the information for LED function mapping and support enhancements.
Figure 16 on page 46 provides possible schematic diagrams for configurations using two and three
LEDs.
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VCC
LILED
ACTLED
SpeedLED
82559ER
LILED
ACTLED
SpeedLED
Figure 16. Two and Three LED Schematic Diagram
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7.
PCI Configuration Registers
The 82559ER acts as both a master and a slave on the PCI bus. As a master, the 82559ER interacts
with the system main memory to access data for transmission or deposit received data. As a slave,
some 82559ER control structures are accessed by the host CPU to read or write information to the
on-chip registers. The CPU also provides the 82559ER with the necessary commands and pointers
that allow it to process receive and transmit data.
7.1
LAN (Ethernet) PCI Configuration Space
The 82559ER PCI configuration space is configured as 16 Dwords of Type 0 Configuration Space
Header, as defined in the PCI Specification, Revision 2.1. A small section is also configured
according to its device specific configuration space. The configuration space header is depicted
below in Figure 17.
Device ID
Status
Vendor ID
Command
00H
04H
08H
0CH
10H
14H
18H
1CH
20H
24H
28H
2CH
30H
34H
38H
3CH
DCH
E0H
Class Code
Revision ID
Cache Line Size
BIST
Header Type
Latency Timer
CSR Memory Mapped Base Address Register
CSR I/O Mapped Base Address Register
Flash Memory Mapped Base Address Register
Reserved Base Address Register
Reserved Base Address Register
Reserved Base Address Register
Reserved
Subsystem ID
Subsystem Vendor ID
Expansion ROM Base Address Register
Reserved
Reserved
Cap_Ptr
Max_Lat
Min_Gnt
Interrupt Pin
Next Item Ptr
Interrupt Line
Capability ID
Power Management Capabilities
Reserved Data
Power Management CSR
Figure 17. PCI Configuration Registers
7.1.1
PCI Vendor ID and Device ID Registers
The Vendor ID and Device ID of the 82559ER are both read only word entities. Their HARD-
CODED values are:
Vendor ID: 8086H
Device ID: 1209H
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7.1.2
PCI Command Register
The 82559ER Command register at word address 04h in the PCI configuration space provides
control over the 82559ER’s ability to generate and respond to PCI cycles. If a 0His written to this
register, the 82559ER is logically disconnected from the PCI bus for all accesses except
configuration accesses. The format of this register is shown in the figure below.
15
10
7
6
5
4
3
2
1
0
9
8
Reserved
0
0
0
0
SERR# Enable
Parity Error Response
Memory Write and Invalidate Enable
Bus Master Enable
Memory Space
IO space
Figure 18. PCI Command Register
Note that bits three, five, seven, and nine are set to 0b. The table below describes the bits of the PCI
Command register.
Table 5. PCI Command Register Bits
Bits
Name
Reserved
Description
15:10
These bits are reserved and should be set to 000000b.
This bit controls a device’s ability to enable the SERR# driver. A value of 0b
disables the SERR# driver. A value of 1b enables the SERR# driver. This
bit must be set to report address parity errors. In the 82559ER, this bit is
configurable and has a default value of 0b.
8
6
SERR# Enable
This bit controls a device’s response to parity errors. A value of 0b causes
the device to ignore any parity errors that it detects and continue normal
operation. A value of 1b causes the device to take normal action when a
parity error is detected. This bit must be set to 0b after RST# is asserted. In
the 82559ER, this bit is configurable and has a default value of 0b.
Parity Error Control
This bit controls a device’s ability to use the Memory Write and Invalidate
command. A value of 0b disables the device from using the Memory Write
and Invalidate Enable command. A value of 1b enables the device to use
the Memory Write and Invalidate command. In the 82559ER, this bit is
configurable and has a default value of 0b.
Memory Write and
Invalidate Enable
4
This bit controls a device’s ability to act as a master on the PCI bus. A
value of 0b disables the device from generating PCI accesses. A value of
1b allows the device to behave as a bus master. In the 82559ER, this bit is
configurable and has a default value of 0b.
2
1
0
Bus Master
Memory Space
I/O Space
This bit controls a device’s response to the memory space accesses. A
value of 0b disables the device response. A value of 1b allows the device
to respond to memory space accesses. In the 82559ER, this bit is
configurable and its default value of 0b.
This bit controls a device’s response to the I/O space accesses. A value of
0b disables the device response. A value of 1b allows the device to
respond to I/O space accesses. In the 82559ER, this bit is configurable and
the default value of 0b.
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7.1.3
PCI Status Register
The 82559ER Status register is used to record status information for PCI bus related events. The
format of this register is shown in the figure below.
31 30
29 28 27 26 25 24 23 22 21 20
19
16
0
0
1
1
0
0
1
Reserved
Detected Parity Error
Signaled System Error
Received Master Abort
Received Target Abort
Signaled Target Abort
Devsel Timing
Parity Error Detected
Fast Back To Back (target)
Capabilities List
Figure 19. PCI Status Register
Note that bits 21, 22, 26, and 27 are set to 0b and bits 20, 23, and 25 are set to 1b. The PCI Status
register bits are described in the table below.
Table 6. PCI Status Register Bits
Bits
Name
Description
This bit indicates whether a parity error is detected. This bit must be
asserted by the device when it detects a parity error, even if parity error
handling is disabled (as controlled by the Parity Error Response bit in the
PCI Command register, bit 6). In the 82559ER, the initial value of the
Detected Parity Error bit is 0b. This bit is set until cleared by writing a 1b.
31
Detected Parity Error
This bit indicates when the device has asserted SERR#. In the 82559ER,
30
29
Signaled System Error the initial value of the Signaled System Error bit is 0b. This bit is set until
cleared by writing a 1b.
This bit indicates whether or not a master abort has occurred. This bit must
Received Master
Abort
be set by the master device when its transaction is terminated with a
master abort. In the 82559ER, the initial value of the Received Master
Abort bit is 0b. This bit is set until cleared by writing a 1b.
This bit indicates that the master has received the target abort. This bit
must be set by the master device when its transaction is terminated by a
target abort. In the 82559ER, the initial value of the Received Target Abort
bit is 0b. This bit is set until cleared by writing a 1b.
28
27
Received Target Abort
This bit indicates whether a transaction was terminated by a target abort.
Signaled Target Abort This bit must be set by the target device when it terminates a transaction
with target abort. In the 82559ER, this bit is always set to 0b.
These two bits indicate the timing of DEVSEL#:
00b - Fast
01b - Medium
DEVSEL# Timing
26:25
10b - Slow
11b - Reserved
In the 82559ER, these bits are always set to 01b, medium.
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Table 6. PCI Status Register Bits
Bits
Name
Description
This bit indicates whether a parity error has been detected. This bit is set to
1b when the following three conditions are met:
1. The bus agent asserted PERR# itself or observed PERR# asserted.
2. The agent setting the bit acted as the bus master for the operation in
which the error occurred.
24
Parity Error Detected
3. The Parity Error Response bit in the command register (bit 6) is set.
In the 82559ER, the initial value of the Parity Error Detected bit is 0b. This
bit is set until cleared by writing a 1b.
This bit indicates a device’s ability to accept fast back-to-back transactions
when the transactions are not to the same agent. A value of 0b disables
fast back-to-back ability. A value of 1b enables fast back-to-back ability. In
the 82559ER, this bit is read only and is set to 1b.
23
Fast Back-to-Back
This bit indicates whether the 82559ER implements a list of new
capabilities such as PCI Power Management. A value of 0b means that this
function does not implement the Capabilities List. If this bit is set to 1b, the
Cap_Ptr register provides an offset into the 82559ER PCI Configuration
space pointing to the location of the first item in the Capabilities List. This
bit is set only if the power management bit in the EEPROM is set.
20
Capabilities List
Reserved
19:16
These bits are reserved and should be set to 0000b.
7.1.4
7.1.5
PCI Revision ID Register
The Revision ID is an 8-bit read only register with a default value of 08h for the 82559ER. The
three least significant bits of the Revision ID can be overridden by the ID and Revision ID fields in
the EEPROM (Section 4.4, “Serial EEPROM Interface” on page 28).
PCI Class Code Register
The Class Code register is read only and is used to identify the generic function of the device and,
in some cases, specific register level programming interface. The register is broken into three byte
size fields. The upper byte is a base class code and specifies the 82559ER as a network controller,
2H. The middle byte is a subclass code and specifies the 82559ER as an Ethernet controller, 0H.
The lower byte identifies a specific register level programming interface and the 82559ER always
returns a 0h in this field.
7.1.6
PCI Cache Line Size Register
In order for the 82559ER to support the Memory Write and Invalidate (MWI) command, the
82559ER must also support the Cache Line Size (CLS) register in PCI Configuration space. The
register supports only cache line sizes of 8 and 16 Dwords. Any value other than 8 or 16 that is
written to the register is ignored and the 82559ER does not use the MWI command. If a value other
than 8 or 16 is written into the CLS register, the 82559ER returns all zeroes when the CLS register
is read. The figure below illustrates the format of this register.
7
6
5
4
3
2
1
0
0
0
0
RW
RW
0
0
0
Figure 20. Cache Line Size Register
50
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Note: Bit 3 is set to 1b only if the value 00001000b (8H) is written to this register, and bit 4 is set to 1b
only if the value of 00010000b (16H) is written to this register. All other bits are read only and will
return a value of 0b on read.
This register is expected to be written by the BIOS and the 82559ER driver should not write to it.
7.1.7
7.1.8
7.1.9
PCI Latency Timer
The Latency Timer register is a byte wide register. When the 82559ER is acting as a bus master,
this register defines the amount of time, in PCI clock cycles, that it may own the bus.
PCI Header Type
The Header Type register is a byte read only register. It is hard-coded to equal to 00h for a single
function card.
PCI Base Address Registers
One of the most important functions for enabling superior configurability and ease of use is the
ability to relocate PCI devices in address spaces. The 82559ER contains three types of Base
Address Registers (BARs). Two are used for memory mapped resources, and one is used for I/O
mapping. Each register is 32 bits wide. The least significant bit in the BAR determines whether it
represents a memory or I/O space. The figures below show the layout of a BAR for both memory
and I/O mapping. After determining this information, power-up software can map the memory and
I/O controllers into available locations and proceed with system boot. To do this mapping in a
device independent manner, the base registers for this mapping are placed in the predefined header
portion of configuration space. Device drivers can then access this configuration space to
determine the mapping of a particular device.
4 3 2 1 0
0
31
Base Address
Prefetchable
Set to 0b in 82559ER
Type
00 - locate anywhere in 32-bit address space
01 - locate below 1 Mbyte
10 - locate anywhere in 64-bit address space
11 - reserved
Memory space indicator
Figure 21. Base Address Register for Memory Mapping
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2 1 0
0 1
31
Base Address
Reserved
I/O space indicator
Figure 22. Base Address Register for I/O Mapping
Note: Bit 0 in all base registers is read only and used to determine whether the register maps into memory
or I/O space. Base registers that map to memory space must return a 0b in bit 0. Base registers that
map to I/O space must return 1b in bit 0.
Base registers that map into I/O space are always 32 bits wide with bit 0 hardwired to a 1b, bit 1 is
reserved and must return 0b on reads, and the other bits are used to map the device into I/O space.
The number of upper bits that a device actually implements depends on how much of the address
space the device will respond to. For example, a device that wants a 1 Mbyte memory address
space would set the most significant 12 bits of the base address register to be configurable, setting
the other bits to 0b.
The 82559ER contains BARs for the Control/Status Register (CSR), Flash, and Expansion ROM.
7.1.9.1
CSR Memory Mapped Base Address Register
The 82559ER requires one BAR for memory mapping. Software determines which BAR, memory
or I/O, is used to access the 82559ER CSR registers.
The memory space for the 82559ER CSR Memory Mapped BAR is 4 Kbyte. It is marked as
prefetchable space and is mapped anywhere in the 32-bit memory address space.
7.1.9.2
7.1.9.3
CSR I/O Mapped Base Address Register
The 82559ER requires one BAR for I/O mapping. Software determines which BAR, memory or
I.O, is used to access the 82559ER CSR registers. The I/O space for the 82559ER CSR I/O BAR is
64 bytes.
Flash Memory Mapped Base Address Register
The Flash Memory BAR is a Dword register. The 82559ER physically supports up to a 128 Kbyte
Flash device, and requests a 128Kbyte window. The 82559ER always claims a Flash memory
window, regardless of whether or not a Flash device is connected (i.e. Flash Base Address Register
cannot be disabled).
7.1.9.4
Expansion ROM Base Address Register
The Expansion ROM BAR is a Dword register and supports a 128 Kbyte memory via the 82559ER
local bus. The Expansion ROM BAR can be disabled by setting the Boot Disable bit of the
EEPROM (word AH, bit 11). The 82559ER requests a 1MB window for expansion ROM. If the
Boot Disable bit is set, the 82559ER returns a 0b for all bits in this address register, avoiding
request of memory allocation for this space.
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7.1.10
PCI Subsystem Vendor ID and Subsystem ID Registers
The Subsystem Vendor ID field identifies the vendor of an 82559ER-based solution. The
Subsystem Vendor ID values are based upon the vendor’s PCI Vendor ID and is controlled by the
PCI Special Interest Group (SIG).
The Subsystem ID field identifies the 82559ER-based specific solution implemented by the vendor
indicated in the Subsystem Vendor ID field.
The 82559ER provides support for configurable Subsystem Vendor ID and Subsystem ID fields.
After hardware reset is de-asserted, the 82559ER automatically reads addresses Ah through Ch of
the EEPROM. The first of these 16-bit values is used for controlling various 82559ER functions.
The second is the Subsystem ID value, and the third is the Subsystem Vendor ID value. Again, the
default values for the Subsystem ID and Subsystem Vendor ID are 0h and 0H, respectively.
The 82559ER checks bit numbers 15, 14, and 13 in the EEPROM, word Ah and functions
according to Table 7 below.
Table 7. 82559ER ID Fields Programming
Subsystem
Vendor ID
Bits 15, 14
Bit 13
Device ID
Vendor ID
Revision ID Subsystem ID
11b, 10b,
00b
X
1209H
8086H
09H
0000H
0000H
(Default)
(Default)
Word CH
Word CH
01b
01b
0b
1b
1209H
1209H
8086H
8086H
09H
Word BH
Word BH
Word AH,
bits 10:8
Note: The Revision ID is subject to change according to the silicon stepping.
The above table implies that if the 82559ER detects the presence of an EEPROM (as indicated by a
value of 01b in bits 15 and 14), then bit number 13 determines whether the values read from the
EEPROM, words Bh and CH, will be loaded into the Subsystem ID (word BH) and Subsystem
Vendor ID (word CH) fields. If bits 15 and 14 equal 01b and bit 13 equals 1b, the three least
significant bits of the Revision ID field are programmed by bits 8-10 of the first EEPROM word,
word AH.
Between the de-assertion of reset and the completion of the automatic EEPROM read, the
82559ER does not respond to any PCI configuration cycles. If the 82559ER happens to be accessed
during this time, it will Retry the access. More information on Retry is provided in Section
4.2.1.1.3, “Retry Premature Accesses” on page 17.
7.1.11
7.1.12
Capability Pointer
The Capability Pointer is a hard coded byte register with a value of DCH. It provides an offset
within the Configuration Space for the location of the Power Management registers.
Interrupt Line Register
The Interrupt Line register identifies which system interrupt request line on the interrupt contoller
the device’s PCI interrupt request pin (as defined in the Interrupt Pin register) is routed to.
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7.1.13
7.1.14
Interrupt Pin Register
The Interrupt Pin register is read only and defines which of the four PCI interrupt request pins,
INTA# through INTD#, a PCI device is connected to. The 82559ER is connected the INTA# pin.
Minimum Grant Register
The Minimum Grant (Min_Gnt) register is an optional read only register for bus masters and is not
applicable to non-master devices. It defines the amount of time the bus master wants to retain PCI
bus ownership when it initiates a transaction. The default value of this register for the 82559ER is
08h. This can be converted to an actual time using the PCI specification (8* 1/PCIclk), to a value of
242ns.
7.1.15
7.1.16
Maximum Latency Register
The Maximum Latency (Max_Lat) register is an optional read only register for bus masters and is
not applicable to non-master devices. This register defines how often a device needs to access the
PCI bus. The default value of this register for the 82559ER is 18h. This can be converted to an
actual time using the PCI specification (18h* 1/PCIclk), to a value of 1µs.
Capability ID Register
The Capability ID is a byte register. It signifies whether the current item in the linked list is the
register defined for PCI Power Management. PCI Power Management has been assigned the value
of 01H.
7.1.17
7.1.18
Next Item Pointer
The Next Item Pointer is a byte register. It describes the location of the next item in the 82559ER’s
capability list. Since power management is the last item in the list, this register is set to 0b.
Power Management Capabilities Register
The Power Management Capabilities register is a word read only register. It provides information
on the capabilities of the 82559ER related to power management. The 82559ER reports a value of
FE21h if it is connected to an auxiliary power source and 7E21h otherwise. It indicates that the
82559ER supports wake-up in the D3 state if power is supplied, either Vcc or VAUX
.
Table 8. Power Management Capability Register
Bits
Default
Read/Write
Description
31:27
00011b
Read Only
PME Support. This five bit field indicates the power states in which
the 82559ER may assert PME#. The 82559ER supports wake-up in
(no V
)
AUX
all power states if it is fed by an auxiliary power supply (V
) and
11111b
(V
AUX
D0, D1, D2, and D3 if it is fed by PCI power.
)
hot
AUX
26
25
1b
Read Only
Read Only
D2 Support. If this bit is set, the 82559ER supports the D2 power
state.
1b
D1 Support. If this bit is set, the 82559ER supports the D1 power
state.
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Table 8. Power Management Capability Register
Bits
Default
000b
Read/Write
Description
24:22
Read Only
Auxiliary Current. This field reports whether the 82559ER
implements the Data registers. The auxiliary power consumption is
the same as the current consumption reported in the D3 state in the
Data register.
21
20
1b
Read Only
Read Only
Device Specific Initialization (DSI). The DSI bit indicates whether
special initialization of this function is required (beyond the standard
PCI configuration header) before the generic class device driver is
able to use it. DSI is required for the 82559ER after D3-to-D0 reset.
0b (PCI)
Reserved (PCI). When this bit is set to ‘1’, it indicates that the
82559ER requires auxiliary power supplied by the system for wake-
up from the D3
state.
cold
19
0b
Read Only
Read Only
PME Clock. The 82559ER does not require a clock to generate a
power management event.
18:16
010b
Version. A value of indicates that the 82559ER complies with the PCI
Power Management Specification, Revision 2.2.
7.1.19
Power Management Control/Status Register (PMCSR)
The Power Management Control/Status is a word register. It is used to determine and change the
current power state of the 82559ER and control the power management interrupts in a standard
manner.
Table 9. Power Management Control and Status Register
Bits
15
Default
0b
Read/Write
Description
Read/Clear
PME Status. This bit is set upon a wake-up event. It is independent of
the state of the PME Enable bit. If 1b is written to this bit, the bit will be
cleared. It also de-asserts the PME# signal and clears the PME status
bit in the Power Management Driver Register. When the PME# signal
is enabled, the PME# signal reflects the state of the PME status bit.
14:13
12:9
00b
Read Only
Read Only
Data Scale. This field indicates the data register scaling factor. It
equals 10b for registers zero through eight and 00b for registers nine
through fifteen.
0000b
Data Select. This field is used to select which data is reported through
the Data register and Data Scale field.
8
0b
Read Clear
Read Only
Read Only
PME Enable. This bit enables the 82559ER to assert PME#.
Reserved. These bits are reserved and should be set to 000b.
7:5
4
000b
0b
Dynamic Data. The 82559ER does not support the ability to monitor
the power consumption dynamically.
3:2
1:0
00b
00b
Read Only
Read/Write
Reserved. These bits are reserved and should be set to 00b.
Power State. This 2-bit field is used to determine the current power
state of the 82559ER and to set the 82559ER into a new power state.
The definition of the field values is as follows.
00 - D0
01 - D1
10 - D2
11 - D3
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7.1.20
Data Register
The data register is an 8-bit read only register that provides a mechanism for the 82559ER to report
state dependent maximum power consumption and heat dissipation. The value reported in this
register depends on the value written to the Data Select field in the PMCSR register. The power
measurements defined in this register have a dynamic range of 0 to 2.55 W with 0.01 W resolution
according to the Data Scale. The value in this register is hard coded in the silicon. The structure of
the data register is presented below.
Table 10. Ethernet Data Register
Data Select
Data Scale
Data Reported
0
1
2
2
2
2
2
2
2
2
2
0
D0 Power Consumption = 60 (600 mW)
D1 Power Consumption = 42 (420 mW)
D2 Power Consumption = 42 (420 mW)
D3 Power Consumption = 42 (420 mW)
D0 Power Dissipated = 58 (580 mW)
D1 Power Dissipated = 40 (400 mW)
D2 Power Dissipated = 40 (400 mW)
D3 Power Dissipated = 40 (400 mW)
Common Function Power Dissipated = 00
Reserved (00H)
2
3
4
5
6
7
8
9-15
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8.
Control/Status Registers
8.1
LAN (Ethernet) Control/Status Registers
The 82559ER’s Control/Status Register (CSR) is illustrated in the figure below.
D31
Upper Word
D16
D15
Lower Word
D0
Offset
SCB Command Word
SCB Status Word
00H
04H
08H
0CH
10H
14H
18H
1CH
20H
24H
28H
2CH
30H
34H
38H
3CH
System Control Block General Pointer
PORT
EEPROM Control Register
Flash Control Register
Management Data Interface (MDI) Control Register
Receive Direct Memory Access Byte Count
Flow Control Register
PMDR
Early Receive Int
General Control
Reserved
General Status
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Figure 23. 82559ER Control/Status Register
NOTE: In Figure 23 above, SCB is defined as the System Control Block of the 82559ER, and PMDR is defined
as the Power Management Driver Register.
SCB Status Word:
SCB Command Word:
SCB General Pointer:
PORT Interface:
The 82559ER places the status of its Command and Receive units
and interrupt indications in this register for the CPU to read.
The CPU places commands for the Command and Receive units in
this register. Interrupts are also acknowledged in this register.
The SCB General Pointer register points to various data structures
in main memory depending on the current SCB Command word.
The PORT interface allows the CPU to reset the 82559ER, force the
82559ER to dump information to main memory, or perform an
internal self test.
Flash Control Register:
The Flash Control register allows the CPU to enable writes to an
external Flash.
EEPROM Control Register:
The EEPROM Control register allows the CPU to read and write to
an external EEPROM.
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MDI Control Register:
The MDI Control register allows the CPU to read and write
information from the PHY unit (or an external PHY component)
through the Management Data Interface.
Receive DMA Byte Count:
Flow Control Register:
PMDR:
The Receive DMA Byte Count register keeps track of how many
bytes of receive data have been passed into host memory via DMA.
This register holds the flow control threshold value and indicates
the flow control commands to the 82559ER.
The Power Management Driver Register provides an indication in
memory and I/O space that a wake-up interrupt has occurred. The
PMDR is described in further detail in Section 8.1.11, “Power
Management Driver Register” on page 60.
General Control:
General Status:
The General Control register allows the 82559ER to enter the deep
power-down state and provides the ability to disable the Clockrun
functionality. The General Control register is described in further
detail in Section 8.1.12, “General Control Register” on page 61.
The General Status register describes the status of the 82559ER’s
duplex mode, speed, and link. The General Status register is
detailed in Section 8.1.13, “General Status Register” on page 61.
8.1.1
System Control Block Status Word
The System Control Block (SCB) Status Word contains status information relating to the
82559ER’s Command and Receive units.
Bits
Name
Description
Command Unit (CU) Executed. The CX bit indicates that the CU has
completed executing a command with its interrupt bit set.
15
14
13
CX
Frame Received. The FR bit indicates that the Receive Unit (RU) has
finished receiving a frame.
FR
CU Not Active. The CNA bit is set when the CU is no longer active and in
either an idle or suspended state.
CNA
Receive Not Ready. The RNR bit is set when the RU is not in the ready
state. This may be caused by an RU Abort command, a no resources
situation, or set suspend bit due to a filled Receive Frame Descriptor.
12
RNR
Management Data Interrupt. The MDI bit is set when a Management Data
Interface read or write cycle has completed. The management data interrupt
is enabled through the interrupt enable bit (bit 29 in the Management Data
Interface Control register in the CSR).
11
10
MDI
SWI
Software Interrupt. The SWI bit is set when software generates an
interrupt.
9
8
ER
Early Receive. The ER bit is used for early receive interrupts.
FCP
Flow Control Pause. The FCP bit is used as the flow control pause bit.
Command Unit Status. The CUS field contains the status of the Command
Unit.
7:6
CUS
RUS
5:2
1:0
Receive Unit Status. The RUS field contains the status of the Receive Unit.
Reserved
These bits are reserved and should be set to 00b.
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8.1.2
System Control Block Command Word
Commands for the 82559ER’s Command and Receive units are placed in this register by the CPU.
Bits
Name
Description
Specific Interrupt Mask. Setting this bit to 1b causes the 82559ER to stop
generating an interrupt (in other words, de-assert the INTA# signal) on the
corresponding event.
Specific
31:26
Interrupt Mask
SI
Software Generated Interrupt. Setting this bit to 1b causes the 82559ER
to generate an interrupt. Writing a 0b to this bit has no effect.
25
24
Interrupt Mask. If the Interrupt Mask bit is set to 1b, the 82559ER will not
assert its INTA# pin. The M bit has higher precedence that the Specific
Interrupt Mask bits and the SI bit.
M
23:20
19
CUC
Command Unit Command. This field contains the CU command.
This bit is reserved and should be set to 0b.
Reserved
RUC
18:16
Receive Unit Command. This field contains the RU command.
8.1.3
8.1.4
System Control Block General Pointer
The System Control Block (SCB) General Pointer is a 32-bit field that points to various data
structures depending on the command in the CU Command or RU Command field.
PORT
The PORT interface allows software to perform certain control functions on the 82559ER. This
field is 32 bits wide:
• Address and Data (bits 32:4)
• PORT Function Selection (bits 3:0)
The 82559ER supports four PORT commands: Software Reset, Self-test, Selective Reset, and
Dump.
8.1.5
8.1.6
Flash Control Register
The Flash Control Register is a 32-bit field that allows access to an external Flash device.
EEPROM Control Register
The EEPROM Control Register is a 32-bit field that enables a read from and a write to the external
EEPROM.
8.1.7
Management Data Interface Control Register
The Management Data Interface (MDI) Control register is a 32-bit field and is used to read and
write bits from the MDI.
Bits
31:30
Description
These bits are reserved and should be set to 00b.
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Bits
Description
Interrupt Enable. When this bit is set to 1b by software, the 82559ER asserts an interrupt to
indicate the end of an MDI cycle.
29
28
Ready. This bit is set to 1b by the 82559ER at the end of an MDI transaction. It should be
reset to 0b by software at the same time the command is written.
Opcode. These bits define the opcode: 01 for MDI write and 10 for MDI read. All other values
(00 and 11) are reserved.
27:26
25:21
20:16
PHY Address. This field of bits contains the PHY address (Default = 00001b).
PHY Register Address. This field of bits contains the address of the PHY Register to be
accessed.
Data. In a write command, software places the data bits in this field, and the 82559ER
transfers the data to the PHY unit. During a read command, the 82559ER reads these bits
serially from the PHY register (specified by bits 20:16), and software reads the data from this
location.
15:0
8.1.8
8.1.9
Receive Direct Memory Access Byte Count
The Receive DMA Byte Count register keeps track of how many bytes of receive data have been
passed into host memory via DMA.
Early Receive Interrupt
The Early Receive Interrupt register allows the 82559ER to generate an early interrupt depending
on the length of the frame. An early interrupt is indicated by the ER bit in the SCB Status Word and
the assertion of the INTA# signal.
8.1.10
Flow Control Register
The Flow Control Register contains the following fields:
• Flow Control Command
The Flow Control Command field describes the action of the flow control process (for
example, pause, on, or off).
• Flow Control Threshold
The Flow Control Threshold field contains the threshold value (in other words, the number of
free bytes in the Receive FIFO).
8.1.11
Power Management Driver Register
The 82559ER provides an indication in memory and I/O space that a wake-up event has occurred.
It is located in the PMDR.
Table 11. Power Management Driver Register
Bits
31
Default
0b
Read/Write
Description
Read/Clear
Link Status Change Indication. The link status change bit is set
following a change in link status and is cleared by writing a 1b to it.
30
0b
Read
Not Supported, will always read as a ‘0’.
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Table 11. Power Management Driver Register
Bits
29
Default
0b
Read/Write
Description
Read/Clear
Interesting Packet. This bit is set when an “interesting” packet is
received. Interesting packets are defined by the 82559ER packet
filters. This bit is cleared by writing 1b to it.
28:26
25
000b
0b
Read Only
Read/Clear
Reserved. These bits are reserved and should be set to 000b.
Reserved. These bit is reserved and should be set to 0b.
24
0b
Read/Clear
PME Status. This bit is a reflection of the PME Status bit in the Power
Management Control/Status Register (PMCSR). It is set upon a wake-
up event and is independent of the PME Enable bit.
This bit is cleared by writing 1b to it. This also clears the PME Status
bit in the PMCSR and de-asserts the PME signal. I
Note: The PMDR is initialized at ALTRST# reset only.
8.1.12
General Control Register
The General Control register is a byte register and is described below.
Table 12. General Control Register
Bits
7:2
Default
Read/Write
Description
000000b
0b
Read Only
Read/Write
Reserved. These bits are reserved and should be set to 000000b.
1
Deep Power-Down on Link Down Enable. If a 1b is written to this
field, the 82559ER may enter a deep power-down state (sub-3 mA) in
the D2 and D3 power states while the link is down.
In this state, the 82559ER does not keep link integrity. This state is not
supported for point-to-point connection of two end stations.
0
0b
Read/Write
Clockrun Signal Disable. If this bit is set to 1b, then the 82559ER will
always request the PCI clock signal. This mode can be used to
overcome potential receive overruns caused by Clockrun signal
latencies over 5 µs.
8.1.13
General Status Register
The General Status register is a byte register which indicates the link status of the 82559ER.
Table 13. General Status Register
Bits
7:3
Default
Read/Write
Description
00000b
--
Read Only
Read Only
Reserved. These bits are reserved and should be set to 00000b.
2
1
0
Duplex Mode. This bit indicates the wire duplex mode: full duplex (1b)
or half duplex (0b).
--
Read Only
Read Only
Speed. This bit indicates the wire speed: 100 Mbps (1b) or 10 Mbps
(0b).
0b
Link Status Indication. This bit indicates the status of the link: valid
(1b) or invalid (0b).
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GD82559ER — Networking Silicon
8.2
Statistical Counters
The 82559ER provides information for network management statistics by providing on-chip
statistical counters that count a variety of events associated with both transmit and receive. The
counters are updated by the 82559ER when it completes the processing of a frame (that is, when it
has completed transmitting a frame on the link or when it has completed receiving a frame). The
Statistical Counters are reported to the software on demand by issuing the Dump Statistical
Counters command or Dump and Reset Statistical Counters command in the SCB Command Unit
Command (CUC) field.
Table 14. 82559ER Statistical Counters
ID
Counter
Description
0
Transmit Good Frames
This counter contains the number of frames that were
transmitted properly on the link. It is updated only after the
actual transmission on the link is completed, not when the
frame was read from memory as is done for the Transmit
Command Block status.
4
8
Transmit Maximum Collisions
(MAXCOL) Errors
This counter contains the number of frames that were not
transmitted because they encountered the configured
maximum number of collisions.
Transmit Late Collisions (LATECOL) This counter contains the number of frames that were not
Errors
transmitted since they encountered a collision later than the
configured slot time.
12 Transmit Underrun Errors
A transmit underrun occurs because the system bus cannot
keep up with the transmission. This counter contains the
number of frames that were either not transmitted or
retransmitted due to a transmit DMA underrun. If the 82559ER
is configured to retransmit on underrun, this counter may be
updated multiple times for a single frame.
16 Transmit Lost Carrier Sense (CRS) This counter contains the number of frames that were
transmitted by the 82559ER despite the fact that it detected
the de-assertion of CRS during the transmission.
20 Transmit Deferred
This counter contains the number of frames that were deferred
before transmission due to activity on the link.
24 Transmit Single Collisions
28 Transmit Multiple Collisions
32 Transmit Total Collisions
This counter contains the number of transmitted frames that
encountered one collision.
This counter contains the number of transmitted frames that
encountered more than one collision.
This counter contains the total number of collisions that were
encountered while attempting to transmit. This count includes
late collisions and frames that encountered MAXCOL.
36 Receive Good Frames
40 Receive CRC Errors
This counter contains the number of frames that were
received properly from the link. It is updated only after the
actual reception from the link is completed and all the data
bytes are stored in memory.
This counter contains the number of aligned frames discarded
because of a CRC error. This counter is updated, if needed,
regardless of the Receive Unit state. The Receive CRC Errors
counter is mutually exclusive of the Receive Alignment Errors
and Receive Short Frame Errors counters.
44 Receive Alignment Errors
This counter contains the number of frames that are both
misaligned (for example, CRS de-asserts on a non-octal
boundary) and contain a CRC error. The counter is updated, if
needed, regardless of the Receive Unit state. The Receive
Alignment Errors counter is mutually exclusive of the Receive
CRC Errors and Receive Short Frame Errors counters.
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Table 14. 82559ER Statistical Counters
ID
Counter
Description
48 Receive Resource Errors
This counter contains the number of good frames discarded
due to unavailability of resources. Frames intended for a host
whose Receive Unit is in the No Resources state fall into this
category. If the 82559ER is configured to Save Bad Frames
and the status of the received frame indicates that it is a bad
frame, the Receive Resource Errors counter is not updated.
52 Receive Overrun Errors
This counter contains the number of frames known to be lost
because the local system bus was not available. If the traffic
problem persists for more than one frame, the frames that
follow the first are also lost; however, because there is no lost
frame indicator, they are not counted.
56 Receive Collision Detect (CDT)
60 Receive Short Frame Errors
This counter contains the number of frames that encountered
collisions during frame reception.
This counter contains the number of received frames that are
shorter than the minimum frame length. The Receive Short
Frame Errors counter is mutually exclusive to the Receive
Alignment Errors and Receive CRC Errors counters. A short
frame will always increment only the Receive Short Frame
Errors counter.
64 Flow Control Transmit Pause
68 Flow Control Receive Pause
This counter contains the number of Flow Control frames
transmitted by the 82559ER. This count includes both the Xoff
frames transmitted and Xon (PAUSE(0)) frames transmitted.
This counter contains the number of Flow Control frames
received by the 82559ER. This count includes both the Xoff
frames received and Xon (PAUSE(0)) frames received.
72 Flow Control Receive Unsupported This counter contains the number of MAC Control frames
received by the 82559ER that are not Flow Control Pause
frames. These frames are valid MAC control frames that have
the predefined MAC control Type value and a valid address
but has an unsupported opcode.
The Statistical Counters are initially set to zero by the 82559ER after reset. They cannot be preset
to anything other than zero. The 82559ER increments the counters by internally reading them,
incrementing them and writing them back. This process is invisible to the CPU and PCI bus. In
addition, the counters adhere to the following rules:
• The counters are wrap-around counters. After reaching FFFFFFFFh the counters wrap around
to 0.
• The 82559ER updates the required counters for each frame. It is possible for more than one
counter to be updated as multiple errors can occur in a single frame.
• The counters are 32 bits wide and their behavior is fully compatible with the IEEE 802.1
standard. The 82559ER supports all mandatory and recommend statistics functions through
the status of the receive header and directly through these Statistical Counters.
The CPU can access the counters by issuing a Dump Statistical Counters SCB command. This
provides a “snapshot”, in main memory, of the internal 82559ER statistical counters. The 82559ER
supports 21 counters. .
The counters are initialized by power-up reset driven on the ALTRST# pin.
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Networking Silicon — GD82559ER
9.
PHY Unit Registers
The 82559ER provides status and accepts management information via the Management Data
Interface (MDI) within the CSR space.
Acronyms mentioned in the registers are defined as follows:
SC -
RO -
E -
self cleared
read only
EEPROM setting affects content
latch low
LL -
LH -
latch high
9.1
MDI Registers 0 - 7
9.1.1
Register 0: Control Register Bit Definitions
Bit(s)
15
Name
Description
Default R/W
Reset
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
1 = PHY Reset
14
Loopback
This bit enables loopback of transmit data nibbles from
the TXD[3:0] signals to the receive data path. The PHY
unit’s receive circuitry is isolated from the network.
0
RW
Note that this may cause the descrambler to lose
synchronization and produce 560 nanoseconds of “dead
time.”
Note also that the loopback configuration bit takes priority
over the Loopback MDI bit.
1 = Loopback enabled
0 = Loopback disabled (Normal operation)
13
12
Speed Selection
This bit controls speed when Auto-Negotiation is disabled
and is valid on read when Auto-Negotiation is disabled.
1
1
RW
RW
1 = 100 Mbps
0 = 10 Mbps
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.
1 = Auto-Negotiation enabled
0 = Auto-Negotiation disabled
11
10
Power-Down
Reserved
This bit sets the PHY unit into a low power mode. In low
power mode, the PHY unit consumes no more than 30
mA.
0
0
RW
RW
1 = Power-Down enabled
0 = Power-Down disabled (Normal operation)
This bit is reserved and should be set to 0b.
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Bit(s)
Name
Description
Default R/W
9
8
Restart Auto-
Negotiation
This bit restarts the Auto-Negotiation process and is self-
clearing.
0
RW
SC
1 = Restart Auto-Negotiation process
Duplex Mode
This bit controls the duplex mode when Auto-Negotiation
is disabled. If the PHY reports that it is only able to
operate in one duplex mode, the value of this bit shall
correspond to the mode which the PHY can operate.
0
RW
When the PHY is placed in Loopback mode, the behavior
of the PHY shall not be affected by the status of this bit,
bit 8.
1 = Full Duplex
0 = Half Duplex
7
Collision Test
Reserved
This bit will force a collision in response to the assertion
of the transmit enable signal.
0
0
RW
RW
1 = Force COL
0 = Do not force COL
6:0
These bits are reserved and should be set to 0000000b.
9.1.2
Register 1: Status Register Bit Definitions
Bit(s)
15
Name
Reserved
Description
Default
R/W
This bit is reserved and should be set to 0b.
0
RO
E
14
13
12
11
100BASE-TX Full 1 = PHY able to perform full duplex 100BASE-TX
Duplex
1
1
1
1
RO
100 Mbps Half
Duplex
1 = PHY able to perform half duplex 100BASE-TX
RO
RO
RO
10 Mbps Full
Duplex
1 = PHY able to operate at 10Mbps in full duplex
mode
10 Mbps Half
Duplex
1 = PHY able to operate at 10 Mbps in half duplex
mode
10:7
6
Reserved
These bits are reserved and should be set to 0000b.
0
0
RO
RO
Management
0 = PHY will not accept management frames with
Frames Preamble preamble suppressed
Suppression
5
Auto-Negotiation
Complete
1 = Auto-Negotiation process completed
0
RO
0 = Auto-Negotiation process has not completed
0 = No remote fault condition detected
4
3
Remote Fault
0
1
RO
RO
Auto-Negotiation
Ability
1 = PHY is able to perform Auto-Negotiation
2
1
0
Link Status
1 = Valid link has been established
0 = Invalid link detected
0
0
1
RO
LL
Jabber Detect
1 = Jabber condition detected
0 = No jabber condition detected
RO
LH
Extended
Capability
1 = Extended register capabilities enabled
RO
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9.1.3
Register 2: PHY Identifier Register Bit Definitions
Bit(s)
Name
Description
Default
R/W
RO
15:0
PHY ID (high
byte)
Value: 02A8H
--
9.1.4
9.1.5
Register 3: PHY Identifier Register Bit Definitions
Bit(s)
Name
Description
Default
R/W
RO
15:0
PHY ID (low byte) Value: 0154H
--
Register 4: Auto-Negotiation Advertisement Register Bit Definitions
Bit(s)
15
Name
Next Page
Description
Default
R/W
RO
Constant 0 = Transmitting primary capability data
page
0
14
13
Reserved
This bit is reserved and should be set to 0b.
0
0
RO
Remote Fault
1 = Indicate link partner’s remote fault
0 = No remote fault
RW
12:5
4:0
TechnologyAbility Technology Ability Field is an 8-bit field containing
00101111 RW
Field
information indicating supported technologies specific
to the selector field value.
Selector Field
The Selector Field is a 5-bit field identifying the type of
message to be sent via Auto-Negotiation. This field is
read only in the 82559ER and contains a value of
00001b, IEEE Standard 802.3.
00001
RO
9.1.6
Register 5: Auto-Negotiation Link Partner Ability Register Bit
Definitions
Bit(s)
15
Name
Next Page
Description
Default
R/W
This bit reflects the PHY’s link partner’s Auto-
Negotiation ability.
--
RO
RO
14
Acknowledge
Remote Fault
This bit is used to indicate that the 82559ER’s PHY
unit has successfully received its link partner’s Auto-
Negotiation advertising ability.
--
13
This bit reflects the PHY’s link partner’s Auto-
Negotiation ability.
--
--
--
RO
RO
RO
12:5
4:0
TechnologyAbility This bit reflects the PHY’s link partner’s Auto-
Field
Negotiation ability.
Selector Field
This bit reflects the PHY’s link partner’s Auto-
Negotiation ability.
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9.1.7
Register 6: Auto-Negotiation Expansion Register Bit Definitions
Bit(s)
Name
Reserved
Description
Default
R/W
RO
15:5
4
These bits are reserved and should be set to 0b.
0
0
Parallel Detection 1 = Fault detected via parallel detection (multiple link
Fault
RO
SC
LH
fault occurred)
0 = No fault detected via parallel detection
This bit will self-clear on read
3
2
1
Link Partner Next 1 = Link Partner is Next Page able
0
0
0
RO
RO
page Able
0 = Link Partner is not Next Page able
Next Page Able
Page Received
1 = Local drive is Next Page able
0 = Local drive is not Next Page able
1 = New Page received
RO
SC
LH
0 = New Page not received
This bit will self-clear on read.
0
Link Partner Auto- 1 = Link Partner is Auto-Negotiation able
0
RO
Negotiation Able
0 = Link Partner is not Auto-Negotiation able
9.2
MDI Registers 8 - 15
Registers eight through fifteen are reserved for IEEE.
9.3
MDI Register 16 - 31
9.3.1
Register 16: PHY Unit Status and Control Register Bit Definitions
Bit(s)
Name
Reserved
Description
Default
R/W
RW
15:14
13
These bits are reserved and should be set to 00b
00
0
Carrier Sense
Disconnect
Control
This bit enables the disconnect function.
1 = Disconnect function enabled
0 = Disconnect function disabled
RW
12
Transmit Flow
Control Disable
This bit enables Transmit Flow Control
1 = Transmit Flow Control enabled
0 = Transmit Flow Control disabled
0
RW
11
10
Receive De-
Serializer In-Sync De-Serializer In-Sync.
Indication
This bit indicates status of the 100BASE-TX Receive
--
1
RO
RO
100BASE-TX
Power-Down
This bit indicates the power state of 100BASE-TX
PHY unit.
1 = Power-Down
0 = Normal operation
9
10BASE-T
Power-Down
This bit indicates the power state of 100BASE-TX
PHY unit.
1
RO
1 = Power-Down
0 = Normal operation
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Bit(s)
Name
Polarity
Description
Default
R/W
RO
8
This bit indicates 10BASE-T polarity.
1 = Reverse polarity
--
0 = Normal polarity
7:2
1
Reserved
Speed
These bits are reserved and should be set to 0B.
000000
--
RO
RO
This bit indicates the Auto-Negotiation result.
1 = 100 Mbps
0 = 10 Mbps
0
Duplex Mode
This bit indicates the Auto-Negotiation result.
1 = Full Duplex
--
RO
0 = Half Duplex
9.3.2
Register 17: PHY Unit Special Control Bit Definitions
Bit(s)
15
Name
Description
1 = By-pass Scrambler
Default
R/W
Scrambler By-
pass
0
RW
RW
RW
RW
RW
0 = Normal operations
14
13
12
11
By-pass 4B/5B
1 = 4 bit to 5 bit by-pass
0 = Normal operation
0
0
0
0
Force Transmit H- 1 = Force transmit H-pattern
Pattern
0 = Normal operation
Force 34 Transmit 1 = Force 34 transmit pattern
Pattern
0 = Normal operation
Good Link
1 = 100BASE-TX link good
0 = Normal operation
10
9
Reserved
This bit is reserved and should be set to 0b.
0
0
RW
RW
Transmit Carrier
Sense Disable
1 = Transmit Carrier Sense disabled
0 = Transmit Carrier Sense enabled
8
7
6
5
4
3
2
1
Disable Dynamic
Power-Down
1 = Dynamic Power-Down disabled
0
0
0
0
0
0
0
0
RW
RW
RW
RW
RW
RW
RW
RW
0 = Dynamic Power-Down enabled (normal)
Auto-Negotiation
Loopback
1 = Auto-Negotiation loopback
0 = Auto-Negotiation normal mode
MDI Tri-State
Filter By-pass
1 = MDI Tri-state (transmit driver tri-states)
0 = Normal operation
1 = By-pass filter
0 = Normal filter operation
Auto Polarity
Disable
1 = Auto Polarity disabled
0 = Normal polarity operation
Squelch Disable
1 = 10BASE-T squelch test disable
0 = Normal squelch operation
Extended
Squelch
1 = 10BASE-T Extended Squelch control enabled
0 = 10BASE-T Extended Squelch control disabled
Link Integrity
Disable
1 = Link disabled
0 = Normal Link Integrity operation
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Bit(s)
Name
Description
Default
R/W
RW
0
Jabber Function
Disable
1 = Jabber disabled
0 = Normal Jabber operation
0
9.3.3
9.3.4
Register 18: PHY Address Register
Bit(s)
Name
Reserved
Description
Default
R/W
RO
15:5
These bits are reserved and should be set to a
constant ‘0’
0
4:0
PHY Address
These bits are set to the PHY’s address, 00001b.
1
RO
Register 19: 100BASE-TX Receive False Carrier Counter Bit
Definitions
Bit(s)
Name
Description
Default
R/W
15:0
Receive False
Carrier
These bits are used for the false carrier counter.
--
RO
SC
9.3.5
9.3.6
Register 20: 100BASE-TX Receive Disconnect Counter Bit Definitions
Bit(s)
Name
Description
Default
R/W
15:0
Disconnect Event This field contains a 16-bit counter that increments for
each disconnect event. The counter freezes when full
and self-clears on read
--
RO
SC
Register 21: 100BASE-TX Receive Error Frame Counter Bit
Definitions
Bit(s)
Name
Description
Default
R/W
15:0
Receive Error
Frame
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 freezes when full and self-clears
on read.
--
RO
SC
9.3.7
Register 22: Receive Symbol Error Counter Bit Definitions
Bit(s)
Name
Description
Default
R/W
15:0
Symbol Error
Counter
This field contains a 16-bit counter that increments for
each symbol error. The counter freezes when full and
self-clears on read.
--
RO
SC
In a frame with a bad symbol, each sequential six bad
symbols count as one.
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9.3.8
9.3.9
9.3.10
Register 23: 100BASE-TX Receive Premature End of Frame Error
Counter Bit Definitions
Bit(s)
Name
Description
Default
R/W
15:0
Premature End of This field contains a 16-bit counter that increments for
--
RO
SC
Frame
each premature end of frame event. The counter
freezes when full and self-clears on read.
Register 24: 10BASE-T Receive End of Frame Error Counter Bit
Definitions
Bit(s)
Name
Description
Default
R/W
15:0
End of Frame
Counter
This is a 16-bit counter that increments for each end
of frame error event. The counter freezes when full
and self-clears on read.
--
RO
SC
Register 25: 10BASE-T Transmit Jabber Detect Counter Bit
Definitions
Bit(s)
Name
Description
Default
R/W
15:0
Jabber Detect
Counter
This is a 16-bit counter that increments for each
jabber detection event. The counter freezes when full
and self-clears on read.
--
RO
SC
9.3.11
9.3.12
Register 26: Equalizer Control and Status Bit Definitions
Bit(s)
Name
Description
Reserved for Future Use
Default
R/W
RW
15:0
RFU
--
Register 27: PHY Unit Special Control Bit Definitions
Bit(s)
Name
Reserved
Description
Default
R/W
15:3
2:0
These bits are reserved and should be set to 0b.
0
RW
RW
LED Switch
Control
Value
000
001
010
011
100
101
110
111
ACTLED
Activity
Speed
Speed
Activity
Off
LILED
Link
000
Collision
Link
Collision
Off
Off
On
On
Off
On
On
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10.
Electrical and Timing Specifications
10.1
Absolute Maximum Ratings
Maximum ratings are listed below:
Case Temperature under Bias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0 C to 85 C
Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -65 C to 140 C
Outputs and Supply Voltages (except PCI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.5 V to 5.0 V
PCI Output Voltages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.50 V to 5.25 V
Transmit Data Output Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.5 V to 8.0 V
Input Voltages (except PCI). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -1.0 V to 5.0 V
PCI Input Voltages. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.5 V 6.0 V
Stresses above the listed absolute maximum ratings may cause permanent damage to the 82559ER
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.
10.2
DC Specifications
Table 15. General DC Specifications
Symbol
Parameter
Condition
Min
Typical
Max
Units
Notes
V
V
Supply Voltage
3.0
3.3
3.5
V
CC
Periphery Clamp
Voltage
PCI
4.75
5.0
5.25
195
V
1
2
IO
I
Power Supply
125
mA
CC
NOTES:
1. The VIO pin is the a voltage bias pin for the PCI interface. This pin should be connected to 5V ± 5% in a 5 volt
PCI system and 3.3 volts in a 3.3 volt PCI system. Be sure to install a 10K pull-up resistor. This resistor acts
as a current limit resistor in system where the VIO bias voltage maybe shutdown. In this cases the 82559ER
may consume additional current without a resistor.
2. Typical current consumption is in nominal operating conditions (V = 3.3 V) and average link activity.
CC
Maximum current consumption is in maximum V and maximum link activity.
CC
The 82559ER supports the PCI interface standards. The 82559ER’s PCI interface is five volts
tolerant and supports both 5 V and 3.3 V signaling environments.
Table 16. PCI Interface DC Specifications
Symbol
Parameter
Condition
Min
Max
+ 0.5
Units
Notes
V
V
V
V
I
Input High Voltage
Input Low Voltage
0.475V
-0.5
V
V
V
IHP
CC
IO
0.325V
ILP
CC
Input Pull-up Voltage
Input Pull-down Voltage
0.7V
V
1
1
2
IPUP
IPDP
CC
0.2V
V
CC
Input Leakage Current 0 < V < V
CC
±10
µA
ILP
in
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Table 16. PCI Interface DC Specifications
I
I
= -2 mA
2.4
V
V
PCI
out
out
V
V
Output High Voltage
= -500 µA
0.9V
OHP
CC
I
I
= 3 mA, 6 mA
0.55
0.1V
V
V
3, PCI
out
out
Output Low Voltage
= 1500 µA
OLP
CC
C
C
C
Input Pin Capacitance
CLK Pin Capacitance
IDSEL Pin Capacitance
Pin Inductance
10
12
8
pF
pF
pF
nH
4
4
4
4
INP
5
CLKP
IDSEL
PINP
L
12
NOTES:
1. These values are only applicable in 3.3 V signaling environments. Outside of this limit the input buffer must
consume its minimum current.
2. Input leakage currents include high-Z output leakage for all bidirectional buffers with tri-state outputs.
3. Signals without pull-up resistors have 3 mA low output current; and signals requiring pull-up resistors, 6 mA.
The signals requiring pull-up resistors include: FRAME#, TRDY#, IRDY#, DEVSEL#, STOP#, SERR# and
PERR#.
4. This value is characterized but not tested.
Table 17. Flash/EEPROM Interface DC Specifications
Symbol
Parameter
Condition
Min
Max
+ 0.5
CC
Units
Notes
V
V
Input High Voltage
Input Low Voltage
2.0
V
V
V
IHL
-0.5
0.8
ILL
Input Low Leakage
Current
I
0 < V < V
CC
±20
µA
ILL
in
V
V
Output High Voltage
Output Low Voltage
Input Pin Capacitance
I
I
= -1 mA
= 2mA
2.4
V
V
OHL
out
out
0.4
10
OLL
C
pF
1
INL
1. This value is characterized but not tested.
Table 18. LED Voltage/Current Characteristics
Symbol
Parameter
Condition
Min
Typical
Max
Units
Notes
V
V
Output High Voltage
Output Low Voltage
I
I
= -10 mA
= 10 mA
2.4
V
V
OHLED
out
out
0.7
OLLED
Table 19. 100BASE-TX Voltage/Current Characteristics
Symbol
Parameter
Condition
Min
Typical
Max
Units
Notes
Input Differential
Impedance
R
DC
10
KΩ
ID100
Input Differential
Accept Peak Voltage
V
±500
0.7
mV
IDA100
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Networking Silicon — GD82559ER
Table 19. 100BASE-TX Voltage/Current Characteristics
Input Differential
Reject Peak Voltage
V
V
V
I
±100
mV
V
IDR100
ICM100
OD100
Input Common Mode
Voltage
V
/2
CC
Output Differential
Peak Voltage
0.95
1.00
20
1.05
V
Line Driver Supply
Peak Current
RBIAS100 = 619 Ω
mA
1
CCT100
NOTES: Current is measured on all V pins (V = 3.3 V).
CC
CC
1. Transmitter peak current is attained by dividing the measured maximum differential output peak voltage by
the load resistance value.
Rbias100
585 0hm
619 Ohm
650 Ohm
20 mA
Icct100
21mA
19mA
Figure 24. RBIAS100 Resistance Versus Transmitter Current
NOTES: Current is measured on all V pins (V = 3.3 V).
CC
CC
Table 20. 10BASE-T Voltage/Current Characteristics
Symbol
Parameter
Condition
10 MHz
Min
Typical
Max
Units
Notes
Input Differential
Impedance
R
10
KΩ
ID10
Input Differential
Accept Peak Voltage
V
5 MHz ≤ f ≤ 10 MHz
5 MHz ≤ f ≤ 10 MHz
±585
0
±440
±440
±3100
±300
mV
mV
V
IDA10
IDR10
ICM10
OD10
Input Differential
Reject Peak Voltage
V
V
V
I
Input Common Mode
Voltage
V
/2
CC
Output Differential
Peak Voltage
RL = 100 Ω
2.2
2.8
V
Line Driver Supply
Peak Current
RBIAS10 = 549 Ω
48
mA
1
CCT10
1. Transmitter peak current is attained by dividing the measured maximum differential output peak voltage by
the load resistance value.
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GD82559ER — Networking Silicon
Rbias10
621.5 0hm
549 Ohm
576 Ohm
20 mA
Icct10
21mA
19mA
Figure 25. RBIAS10 Resistance Versus Transmitter Current
10.3
AC Specifications
Table 21. AC Specifications for PCI Signaling
Symbol
Parameter
Condition
0 < V ≤ 1.4
Min
Max
Units Notes
-44
mA
mA
mA
mA
mA
mA
mA
mA
1
1
2
2
1
1
2
2
out
Switching
1.4 < V < 0.9V
-17.1(V - V
)
out
CC
CC
out
Current High
I
OH(AC)
0.7V < V < V
Eqn A
CC
out
CC
CC
(Test Point)
V
= 0.7V
-32V
CC
out
V
≥ 2.2
95
out
Switching
2.2 > V > 0.1V
V
/0.023
out
CC
out
Current Low
I
OL(AC)
0.18V > V > 0
Eqn B
CC
out
CC
(Test Point)
V
= 0.18V
38V
out
CC
Low Clamp
Current
-25 + (V + 1)/
in
I
I
-3 < V ≤ -1
mA
mA
3
3
CL
in
0.015
High Clamp
Current
25 + (V -V -1)/
in CC
V
+4 > V ≥ V +1
in CC
CH
CC
0.015
PCI Output Rise
Slew Rate
slew
slew
0.4 V to 2.4 V
2.4 V to 0.4 V
1
4
4
V/ns
V/ns
RP
FP
PCI Output Fall
Slew Rate
1
NOTES:
1. Switching Current High specifications are not relevant to PME#, SERR#, or INTA#, which are open drain
outputs.
2. Maximum current requirements will be met as drivers pull beyond the first step voltage (AC drive point).
Equations defining these maximums (A and B) are provided. To facilitate component testing, a maximum
current test point is defined for each side of the output driver.
Equation A.
Equation B.
I
I
= (98/V ) (V - V ) (V + 0.4V ), for V > V > 0.7V
CC * out CC * out CC CC out CC
OH
OL
= (256/V ) (V ) (V - V ), for 0 < V < 0.18V
CC
CC * out * CC
out
out
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Networking Silicon — GD82559ER
10.4
Timing Specifications
10.4.1
Clocks Specifications
PCI Clock Specifications
10.4.1.1
The 82559ER uses the PCI Clock signal directly. Figure 26 shows the clock waveform and required
measurement points for the PCI Clock signal. Table 22 summarizes the PCI Clock specifications.
0.6VCC
0.475VCC
0.4VCC
0.325VCC
0.4VCC p-to-p
(minimum)
0.2VCC
T_low
T_high
T_cyc
Figure 26. PCI Clock Waveform
Table 22. PCI Clock Specifications
Symbol
Parameter
Min
Max
Units
Notes
T1
T2
T3
T4
T
T
T
T
CLK Cycle Time
CLK High Time
CLK Low Time
CLK Slew Rate
30
11
11
1
ns
ns
1
cyc
high
low
ns
4
V/ns
2
slew
NOTES:
1. The 82559ER will work with any PCI clock frequency up to 33 MHz.
2. Rise and fall times are specified in terms of the edge rate measured in V/ns. This slew rate is met across the
minimum peak-to-peak portion of the clock waveform as shown in Figure 26.
10.4.1.2
X1 Specifications
X1 serves as a signal input from an external crystal or oscillator. Table 23 defines the 82559ER
requirements from this signal.
Table 23. X1 Clock Specifications
Symbol
Parameter
Min
Typical
Max
Units
Notes
T8
T9
Tx1_dc
Tx1_pr
X1 Duty Cycle
X1 Period
40%
60%
40
ns
±50PPM
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GD82559ER — Networking Silicon
10.4.2
Timing Parameters
10.4.2.1
Measurement and Test Conditions
Figure 27, Figure 28, and Table 24 define the conditions under which timing measurements are
done. The component test guarantees that all timings are met with minimum clock slew rate
(slowest edge) and voltage swing. The design must guarantee that minimum timings are also met
with maximum clock slew rate (fastest edge) and voltage swing. In addition, the design must
guarantee proper input operation for input voltage swings and slew rates that exceed the specified
test conditions.
V_th
V_test
CLK
V_tl
T_val
OUTPUT
DELAY
V_step
Tri-State
OUTPUT
V_test
T_on
V_test
T_off
Figure 27. Output Timing Measurement Conditions
V_th
V_test
CLK
V_tl
T_su
T_h
V_th
inputs
valid
V_test
V_test
V_max
INPUT
V_tl
Figure 28. Input Timing Measurement Conditions
Table 24. Measure and Test Condition Parameters
Symbol
PCI Level
Units
Notes
V
0.6V
0.2V
0.4V
V
V
V
th
CC
CC
CC
V
tl
V
test
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Networking Silicon — GD82559ER
Table 24. Measure and Test Condition Parameters
0.325V
0.475V
0.475V
0.325V
V
V
V
V
V
Min Delay
Max Delay
Min Delay
Max Delay
CC
CC
CC
CC
V
(rising edge)
(falling edge)
0.285V
0.615V
step
CC
V
step
CC
V
0.4V
1
0.4V
1
max
CC
CC
Input Signal Edge
Rate
V/ns
NOTE: Input test is done with 0.1V overdrive. V
specifies the maximum peak-to-peak waveform allowed
max
CC
for testing input timing.
10.4.2.2
PCI Timings
Table 25. PCI Timing Parameters
Symbol
val
Parameter
Min
Max
Units
Notes
T14
T15
t
t
PCI CLK to Signal Valid Delay
2
11
ns
1, 2, 4
PCI CLK to Signal Valid Delay (point-
to-point)
2
2
12
ns
1, 2, 4
val(ptp)
T16
T17
T18
t
t
t
Float to Active Delay
Active to Float Delay
Input Setup Time to CLK
ns
ns
ns
1
1
on
off
su
28
7
4, 5
PCI Input Setup Time to CLK (point-to-
point)
T19
t
10
ns
4, 5
su(ptp)
T20
T21
t
t
Input Hold Time from CLK
0
1
ns
6
6
h
Reset Active Time After Power Stable
ms
rst
PCI Reset Active Time After CLK
Stable
T22
T23
T
100
µs
6
rst-clk
T
Reset Active to Output Float Delay
40
ns
6, 7
rst-off
NOTES:
1. Timing measurement conditions are illustrated in Figure 27.
2. PCI minimum times are specified with loads as detailed in the PCI Bus Specification, Revision 2.1, Section
4.2.3.2.
3. n a PCI environment, REQ# and GNT# are point-to-point signals and have different output valid delay times
and input setup times than bussed signals. All other signals are bussed.
4. Timing measurement conditions are illustrated in Figure 28.
5. RST# is asserted and de-asserted asynchronously with respect to the CLK signal.
6. All PCI interface output drivers are floated when RST# is active.
10.4.2.3
Flash Interface Timings
The 82559ER is designed to support up to 150 nanoseconds of Flash access time. The VPP signal in
the Flash implementation should be connected permanently to 12 V. Thus, writing to the Flash is
controlled only by the FLWE# pin.
Table 26 provides the timing parameters for the Flash interface signals. The timing parameters are
illustrated in Figure 29.
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GD82559ER — Networking Silicon
Table 26. Flash Timing Parameters
Symbol
Parameter
Min
Max
Units
Notes
1, Flash t
AVAV
T35
T36
T37
T38
T39
T40
T41
T42
T43
T44
T45
T46
T47
T48
T49
t
t
t
t
t
t
t
t
t
t
t
t
t
t
t
Flash Read/Write Cycle Time
FLA to Read FLD Setup Time
FLCS# to Read FLD Setup Time
150
ns
flrwc
flacc
flce
= 150 ns
1, Flash t
AVQV
150
150
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
= 150 ns
1, Flash t
ELQV
= 150 ns
1, Flash t
GLQV
FLOE# Active to Read FLD Setup Time 120
floe
= 55 ns
FLOE# Inactive to FLD Driven Delay
1, Flash t
GHQZ
50
fldf
Time
= 35 ns
2, Flash t
AVWL
FLA Setup Time before FLWE#
FLA Hold Time after FLWE#
FLCS# Hold Time before FLWE#
FLCS# Hold Time after FLWE#
FLD Setup Time
5
flas
= 0 ns
2, Flash t
WLAX
200
30
flah
= 60 ns
2, Flash t
ELWL
flcs
= 20 ns
2, Flash t
WHEH
30
flch
= 0 ns
2, Flash t
DVWH
WHDX
WLWH
WHWL
150
10
flds
= 50 ns
2, Flash t
FLD Hold Time
fldh
= 10 ns
2, Flash t
Write Pulse Width
120
25
flwp
flwph
Mioha
Miohi
= 60 ns
2, Flash t
= 20 ns
Write Pulse Width High
IOCHRDY Hold Time after FLWE# or
FLOE# Active
25
IOCHRDY Hold Time after FLWE# or
FLOE# Inactive
0
NOTES:
1. These timing specifications apply to Flash read cycles. The Flash timings referenced are 28F020-150
timings.
2. These timing specifications apply to Flash write cycles. The Flash timings referenced are 28F020-150
timings.
80
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Networking Silicon — GD82559ER
10.4.2.4
EEPROM Interface Timings
FLADDR
FLCS#
Address Stable
T35
T37
FLOE#
T38
T39
T36
FLDATA-R
Data In
Figure 29. Flash Timings for a Read Cycle
The 82559ER is designed to support a standard 64x16, or 256x16 serial EEPROM. Table 27
provides the timing parameters for the EEPROM interface signals. The timing parameters are
illustrated in Figure 30.
Table 27. EEPROM Timing Parameters
Symbol
EFSK
ECSS
ECSH
EDIS
Parameter
Min
Max
Units
Notes
EEPROM fsk =
1 MHz
T50
T51
T52
T53
T54
T55
t
t
t
t
t
t
Serial Clock Frequency
1
Mhz
EEPROM tcss
= 50 ns
Delay from EECS High to EESK High
Delay from EESK Low to EECS Low
Setup Time of EEDI to EESK
Hold Time of EEDI after EESK
EECS Low Time
300
30
ns
ns
ns
ns
ns
EEPROM tcsh
= 0 ns
EEPROM tdis
= 150 ns
300
300
750
EEPROM tdih
= 150 ms
EDIH
EEPROM tcs =
250 ns
ECS
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GD82559ER — Networking Silicon
EECS
T51
T52
FLA15EESK
FLA13EEDI
T53
T54
Figure 30. EEPROM Timings
10.4.2.5
PHY Timings
Table 28. 10BASE-T NLP Timing Parameters
Symbol
Parameter
Condition
Min
Typ
Max
Units
T56
T57
T
T
NLP Width
NLP Period
10 Mbps
10 Mbps
100
ns
nlp_wid
nlp_per
8
24
ms
T57
T56
Normal Link Pulse
Figure 31. 10BASE-T NLP Timings
Table 29. Auto-Negotiation FLP Timing Parameters
Symbol
Parameter
Min
Typ
Max
Units
T58
T59
T60
T61
T62
T63
T
T
T
T
T
T
FLP Width (clock/data)
100
125
62.5
ns
µs
µs
flp_wid
Clock Pulse to Clock Pulse Period
Clock Pulse to Data Pulse Period
Number of Pulses in one burst
FLP Burst Width
111
55.5
17
139
69.5
33
flp_clk_clk
flp_clk_dat
flp_bur_num
flp_bur_wid
flp_bur_per
2
ms
ms
FLP Burst Period
8
24
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Networking Silicon — GD82559ER
T59
T60
T58
Fast Link Pulse
Clock Pulse
T62
Data Pulse
Clock Pulse
T63
FLP Bursts
Figure 32. Auto-Negotiation FLP Timings
Table 30. 100Base-TX Transmitter AC Specification
Symbol
Parameter
Condition
Min
Typ
Max
Units
TDP/TDN Differential
Output Peak Jitter
T64
T
HLS Data
1400
ps
jit
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GD82559ER — Networking Silicon
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Networking Silicon — GD82559ER
12.
Package and Pinout Information
12.1
Package Information
The GD82559ER is a 196-pin Ball Grid Array (BGA) package. Package dimensions are shown in
Figure 24. More information on Intel device packaging is available in the Intel Packaging
Handbook, which is available from the Intel Literature Center or your local Intel sales office.
Figure 24. Dimension Diagram for the GD82559ER 196-Pin BGA
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GD82559ER — Networking Silicon
12.2
Pinout Information
12.2.1
GD82559ER Pin Assignments
Table 15. GD82559ER Pin Assignments
Pin
Name
Pin
Name
Pin
Name
A1
A4
NC
IDSEL
VCC
A2
A5
SERR#
AD25
AD30
VCC
A3
A6
VCC
PME#
A7
A8
A9
ALTRST#
LILED
A10
A13
B1
NC
A11
A14
B2
A12
TEST
AD22
AD24
VSSPP
NC
NC
AD23
AD26
AD31
SPEEDLED
RBIAS10
RST#
NC
B3
B6
VSSPP
AD27
B4
B5
B7
B8
B9
ISOLATE#
TO
B10
B13
C1
B11
B14
C2
B12
RBIAS100
AD21
C/BE3#
AD29
VSSPT
TDP
C3
C6
REQ#
AD28
NC
C4
C5
C7
C8
CLKRUN#
ACTLED
TDN
C9
C10
C13
D1
C11
C14
D2
C12
VREF
AD18
VSS
AD19
VSS
D3
D6
AD20
VSS
NC
D4
D5
D7
VSS
D8
VSS
D9
D10
D13
E1
NC
D11
D14
E2
VSS
D12
TI
TEXEC
VCC
TCK
VSSPP
VSS
E3
E6
AD17
VSS
VSS
VCC
E4
VSS
E5
E7
VSS
E8
VSS
E9
E10
E13
F1
VSS
E11
E14
F2
VSS
E12
RDP
RDN
IRDY#
VSS
FRAME#
VSS
F3
F6
C/BE2#
VSS
F4
F5
F7
VSS
F8
VSS
F9
VSS
F10
F13
G1
VSS
F11
F14
G2
VSS
F12
FLD2
FLD1
CLK
FLD0
VIO
G3
G6
TRDY#
VCC
G4
NC
G5
VCC
G7
VSS
G8
VSS
G9
VSS
G10
G13
VSS
G11
G14
VSS
G12
FLD3
VCC
VSSPL
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Networking Silicon — GD82559ER
Table 15. GD82559ER Pin Assignments
Pin
Name
Pin
Name
Pin
Name
H1
H4
STOP#
NC
H2
H5
INTA#
VCC
VCC
VSS
H3
H6
DEVSEL#
VCC
H7
VCC
H8
H9
VSS
H10
H13
J1
VSS
H11
H14
J2
H12
FLD6
FLD5
PAR
FLD4
PERR#
VCC
VCC
VCC
FLD7
VSSPP
VCC
VCC
VCC
FLA2
AD15
VCC
NC
J3
J6
GNT#
VCC
VCC
FLA1
J4
NC
J5
J7
VCC
J8
J9
J10
J13
K1
VCC
J11
J14
K2
J12
FLA0
AD16
VCC
K3
K6
VCC
VCC
K4
K5
K7
VCC
K8
K9
VCC
K10
K13
L1
VCC
K11
K14
L2
K12
VSSPL
VCC
AD14
VCC
L3
L6
C/BE#1
VSS
L4
L5
L7
NC
L8
L9
VCC
L10
L13
M1
M4
M7
M10
M13
N1
VCC
L11
L14
M2
M5
M8
M11
M14
N2
VSS
L12
FLA5
FLA4
AD11
C/BE0#
AD1
FLA3
AD12
AD5
M3
M6
AD13
VSSPP
FLWE#
FLA11
FLOE#
FLA12
FLA6
AD10
AD4
M9
FLA15/EESK
FLA7
VSSPP
AD7
M12
N3
N6
AD9
VCC
N4
N5
N7
AD0
N8
VCC
X1
N9
FLCS#
VSSPL
N10
N13
P1
FLA14/EEDO
FLA10
NC
N11
N14
P2
N12
FLA8
VCC
AD3
P3
P6
AD8
AD2
P4
AD6
P5
P7
EECS
FLA13/EEDI
FLA9
P8
VSSPL
X2
P9
FLA16
VCC
P10
P13
P11
P14
P12
NC
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GD82559ER — Networking Silicon
12.2.2
GD82559ER Ball Grid Array Diagram
1
2
3
4
5
6
7
8
9
10
11
12
13
14
ALTRST
#
A
B
C
N C
S E R R #
V C C P P
I D S E L
A D 2 5
A D 2 6
N C
P M E #
A D 2 7
A D 2 8
V S S
V S S
V S S
V C C
V C C
V C C
V C C
V S S
V C C P P
A D 3 0
A D 3 1
N C
N C
V C C P T
LILED
TEST
N C
ISOLAT
E #
S P E E D L
E D
R B I A S 1
0 0
R B I A S 1
0
A D 2 2
A D 2 1
A D 1 8
A D 2 3
V S S P P
R E Q #
A D 2 0
A D 2 4
C B E 3 #
V S S
V S S P P
A D 2 9
V S S
T O
V R E F
TI
C L K R U
N #
R S T #
N C
N C
V S S P T
A C T L E D
V S S
V S S
V S S
V S S
V S S
V C C
V C C
V S S
F L A 1 2
X 1
T D P
T E X E C
R D P
TDN
T C K
D
A D 1 9
V S S
V S S
V S S
V C C
V S S
V S S
V S S
V S S
N C
E
F
V C C P P
IRDY#
C L K
V S S P P
F R A M E #
V I O
A D 1 7
V S S
V S S
V S S
V S S
V S S
V S S
V S S
V S S
V C C
F L D 2
F L D 3
R D N
C B E 2 #
V S S
V S S
F L D 1
F L D 0
V S S P L
F L D 4
F L D 7
F L A 2
F L A 3
F L A 6
F L A 8
N C
G
H
J
TRDY#
N C
V S S
V C C P L
(top view)
BGA196 15mmx15mm
4 May 98
82559ER Ballout
D E V S E L
#
S T O P #
INTA#
P E R R #
V S S P P
A D 1 5
N C
N C
V C C
V C C
V C C
V C C
A D 5
A D 4
A D 3
V C C
V C C
V C C
N C
V C C
V C C
V S S
V C C
V C C
V C C
V S S
F L D 6
F L D 5
P A R
G N T #
V C C P P
C B E 1 #
A D 1 3
A D 9
V C C
V C C
F L A 1
F L A 0
K
L
A D 1 6
A D 1 4
A D 1 1
V S S P P
N C
V C C
V C C
C B E 0 #
A D 7
V C C
V S S P L
V C C P L
N C
V C C
F L A 5
F L A 4
FLA15/
E E S K
M
N
P
A D 1 2
V S S P P
V C C P P
A D 2
A D 1
A D 0
E E C S
F L O E #
V C C P L
V S S P L
F L W E #
F L C S #
F L A 1 6
F L A 1 1
V S S P L
V C C P L
F L A 7
FLA14/
E E D O
A D 1 0
F L A 1 0
FLA13/
E E D I
V C C P P
A D 8
A D 6
X 2
F L A 9
Figure 25. GD82559ER Ball Grid Array Diagram
88
Datasheet
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