LAN91C100-FDTQFP [MICROCHIP]
Micro Peripheral IC;型号: | LAN91C100-FDTQFP |
厂家: | MICROCHIP |
描述: | Micro Peripheral IC |
文件: | 总77页 (文件大小:496K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
LAN91C100FD REV. D
FEAST Fast Ethernet
Controller with Full
Duplex Capability
Datasheet
Product Features
Dual Speed CSMA/CD Engine (10 Mbps and 100
Mbps)
Built-In Transparent Arbitration for Slave
Sequential Access Architecture
Compliant with IEEE 802.3 100BASE-T
Specification
Flat MMU Architecture with Symmetric
Transmit and Receive Structures and
Queues
Supports 100BASE-TX, 100BASE-T4, and
10BASE-T Physical Interfaces
MII (Media Independent Interface) Compliant
MAC-PHY Interface Running at Nibble Rate
32 Bit Wide Data Path (into Packet Buffer
Memory)
MII Management Serial Interface
Seven Wire Interface to 10 Mbps ENDEC
EEPROM-Based Setup
Support for 32 and 16 Bit Buses
Support for 32, 16 and 8 Bit CPU Accesses
Synchronous, Asynchronous and Burst DMA
Interface Mode Options
Full Duplex Capability
128 Kbyte External Memory
ORDER NUMBER(S):
LAN91C100-FD for 208-pin QFP package
LAN91C100-FD-SS for 208-pin QFP lead-free RoHS compliant package
LAN91C100-FD for 208-pin TQFP package
LAN91C100-FD-ST for 208-pin TQFP lead-free RoHS compliant package
SMSC LAN91C100FD Rev. D
Page 1
Revision 1.0 (09-22-08)
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
80 ARKAY DRIVE, HAUPPAUGE, NY 11788 (631) 435-6000, FAX (631) 273-3123
Copyright © 2008 SMSC or its subsidiaries. All rights reserved.
Circuit diagrams and other information relating to SMSC products are included as a means of illustrating typical applications. Consequently, complete
information sufficient for construction purposes is not necessarily given. Although the information has been checked and is believed to be accurate, no
responsibility is assumed for inaccuracies. SMSC reserves the right to make changes to specifications and product descriptions at any time without
notice. Contact your local SMSC sales office to obtain the latest specifications before placing your product order. The provision of this information does
not convey to the purchaser of the described semiconductor devices any licenses under any patent rights or other intellectual property rights of SMSC
or others. All sales are expressly conditional on your agreement to the terms and conditions of the most recently dated version of SMSC's standard
Terms of Sale Agreement dated before the date of your order (the "Terms of Sale Agreement"). The product may contain design defects or errors
known as anomalies which may cause the product's functions to deviate from published specifications. Anomaly sheets are available upon request.
SMSC products are not designed, intended, authorized or warranted for use in any life support or other application where product failure could cause
or contribute to personal injury or severe property damage. Any and all such uses without prior written approval of an Officer of SMSC and further
testing and/or modification will be fully at the risk of the customer. Copies of this document or other SMSC literature, as well as the Terms of Sale
Agreement, may be obtained by visiting SMSC’s website at http://www.smsc.com. SMSC is a registered trademark of Standard Microsystems
Corporation (“SMSC”). Product names and company names are the trademarks of their respective holders.
SMSC DISCLAIMS AND EXCLUDES ANY AND ALL WARRANTIES, INCLUDING WITHOUT LIMITATION ANY AND ALL IMPLIED WARRANTIES
OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, TITLE, AND AGAINST INFRINGEMENT AND THE LIKE, AND ANY AND
ALL WARRANTIES ARISING FROM ANY COURSE OF DEALING OR USAGE OF TRADE. IN NO EVENT SHALL SMSC BE LIABLE FOR ANY
DIRECT, INCIDENTAL, INDIRECT, SPECIAL, PUNITIVE, OR CONSEQUENTIAL DAMAGES; OR FOR LOST DATA, PROFITS, SAVINGS OR
REVENUES OF ANY KIND; REGARDLESS OF THE FORM OF ACTION, WHETHER BASED ON CONTRACT; TORT; NEGLIGENCE OF SMSC
OR OTHERS; STRICT LIABILITY; BREACH OF WARRANTY; OR OTHERWISE; WHETHER OR NOT ANY REMEDY OF BUYER IS HELD TO
HAVE FAILED OF ITS ESSENTIAL PURPOSE, AND WHETHER OR NOT SMSC HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
DAMAGES.
Revision 1.0 (09-22-08)
Page 2
SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Table Of Contents
Chapter 1 General Description .............................................................................................................5
Chapter 2 Pin Configuration.................................................................................................................6
Chapter 3 Description of Pin Functions...............................................................................................7
Chapter 4 Functional Description.......................................................................................................15
4.1 Description of Block...........................................................................................................................15
4.1.1
Clock Generator Block............................................................................................................................15
4.2 CSMA/CD BLOCK.............................................................................................................................15
4.2.1
4.2.2
4.2.3
4.2.4
4.2.5
4.2.6
4.2.7
DMA Block..............................................................................................................................................15
Arbiter Block ...........................................................................................................................................15
MMU Block .............................................................................................................................................16
BIU Block................................................................................................................................................16
MAC-PHY Interface Block ......................................................................................................................16
MII Management Interface Block............................................................................................................17
Serial EEPROM Interface.......................................................................................................................17
Chapter 5 Data Structures and Registers ..........................................................................................19
5.1 Packet Format in Buffer Memory ......................................................................................................19
5.2 Typical Flow of Events for Transmit (Auto Release = 0)...................................................................41
5.3 Typical Flow of Events for Transmit (Auto Release = 1)...................................................................42
5.4 Typical Flow of Events for Receive...................................................................................................43
5.5 Memory Partitioning ..........................................................................................................................48
5.6 Interrupt Generation ..........................................................................................................................49
Chapter 6 Board Setup Information ..................................................................................................52
Chapter 7 Application Considerations...............................................................................................55
7.1 Fast Ethernet Slave Adapter .............................................................................................................55
7.2 VL Local Bus 32 Bit Systems............................................................................................................55
7.3 High End ISA or Non-Burst EISA Machines......................................................................................58
7.4 EISA 32 Bit SLAVEEISA 32 Bit Slave...............................................................................................60
Chapter 8 Operational Description ....................................................................................................63
8.1 Maximum Guaranteed Ratings*........................................................................................................63
8.2 DC Electrical Characteristics.............................................................................................................63
Chapter 9 Timing Diagrams................................................................................................................66
Chapter 10
Package Outlines.............................................................................................................76
List of Figures
Figure 3.1 - LAN91C100FD Block Diagram .................................................................................................................13
Figure 3.2 - LAN91C100FD System Diagram ..............................................................................................................14
Figure 4.1 - LAN91C100FD Internal Bock diagram with Data Path..............................................................................18
Figure 5.1 - Data Packet Format..................................................................................................................................19
Figure 5.2 - Interrupt Structure.....................................................................................................................................37
Figure 5.3 - Interrupt Service Routine ..........................................................................................................................44
Figure 5.4 - RX INTR ...................................................................................................................................................45
Figure 5.5 - TX INTR....................................................................................................................................................46
Figure 5.6 - TXEMPTY INTR (Assumes Auto release Option Selected)......................................................................47
Figure 5.7 - Drive Send and Allocate Routines ............................................................................................................48
Figure 5.8 - Interrupt Generation for Transmit, Receive, MMU ....................................................................................51
Figure 6.1 - 64 X 16 Serial EEPROM Map...................................................................................................................54
SMSC LAN91C100FD Rev. D
Page 3
Revision 1.0 (09-22-08)
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Figure 7.1 - LAN91C100FD on VL BUS.......................................................................................................................57
Figure 7.2 - LAN91C100FD on ISA Bus.......................................................................................................................59
Figure 7.3 - LAN91C100FD on EISA Bus ....................................................................................................................62
Figure 9.1 - Asynchronous Cycle - nADS=0.................................................................................................................66
Figure 9.2 - Asynchronous Cycle - Using nADS...........................................................................................................67
Figure 9.3 - Asynchronous Cycle - nADS=0.................................................................................................................68
Figure 9.4 - Burst Write Cycles - nVLBUS=1 ...............................................................................................................69
Figure 9.5 - Burst Read Cycles - nVLBUS=1 ...............................................................................................................70
Figure 9.6 - Address Latching for all Modes.................................................................................................................71
Figure 9.7 - Synchronous Write Cycles - nVLBUS=0...................................................................................................71
Figure 9.8 - Synchronous Read Cycle - NVLBUS=0....................................................................................................72
Figure 9.9 - SRAM Interface ........................................................................................................................................73
Figure 9.10 - ENDEC Interface - 10 Mbps ...................................................................................................................74
Figure 9.11 - MII Interface............................................................................................................................................75
Figure 10.1 - 208 Pin QFP Package Outline................................................................................................................76
Figure 10.2 - 208 Pin TQFP Package Outlines............................................................................................................77
List of Tables
Table 3.1 - LAN91C100FD Pin Requirements
Table 5.1 - Internal I/O Space Mapping
Table 7.1 - VL Local Bus Signal Connections
Table 7.2 - High-End ISA or Non-Burst EISA Machines Signal Connectors
Table 7.3 - EISA 32 Bit Slave Signal Connections
Table 10.1 - 208 Pin QFP Package Parameters
Table 10.2 - 208 Pin TQFP Package Outlines
12
22
55
58
60
76
77
Revision 1.0 (09-22-08)
Page 4
SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 1 General Description
The LAN91C100FD is designed to facilitate the implementation of first generation Fast Ethernet adapters
and connectivity products. For this first generation of products, flexibility dominates over integration. The
LAN91C100FD is a digital device that implements the MAC portion of the CSMA/CD protocol at 10 and
100 Mbps, and couples it with a lean and fast data and control path system architecture to ensure the CPU
to packet RAM data movement does not cause a bottleneck at 100 Mbps.
Total memory size is 128 Kbytes, equivalent to a total chip storage (transmit plus receive) of 64 outstanding
packets. The LAN91C100FD is software compatible with the LAN9000 family of products and can use existing
LAN9000 drivers (ODI, IPX, and NDIS) in 16 and 32 bit Intel X86 based environments.
Memory management is handled using a unique MMU (Memory Management Unit) architecture and a 32-
bit wide data path. This I/O mapped architecture can sustain back-to-back frame transmission and
reception for superior data throughput and optimal performance. It also dynamically allocates buffer
memory in an efficient buffer utilization scheme, reducing software tasks and relieving the host CPU from
performing these housekeeping functions. The total memory size is 128 Kbytes (external), equivalent to a
total chip storage (transmit and receive) of 64 outstanding packets.
FEAST provides a flexible slave interface for easy connectivity with industry-standard buses. The Bus
Interface Unit (BIU) can handle synchronous as well as asynchronous buses, with different signals being
used for each one. FEAST's bus interface supports synchronous buses like the VESA local bus, as well
as burst mode DMA for EISA environments. Asynchronous bus support for ISA is supported even though
ISA cannot sustain 100 Mbps traffic. Fast Ethernet could be adopted for ISA-based nodes on the basis of
the aggregate traffic benefits.
Two different interfaces are supported on the network side. The first is a conventional seven wire ENDEC
interface that connects to the LAN83C694 for 10BASE-T and coax 10 Mbps Ethernet networks. The second
interface follows the MII (Media Independent Interface) specification draft standard, consisting of 4 bit wide
data transfers at the nibble rate. This interface is applicable to 10 Mbps or 100 Mbps networks. Three of the
LAN91C100FD’s pins are used to interface to the two-line MII serial management protocol. Four I/O ports
(one input and three output pins) are provided for LAN83C694 configuration.
The LAN91C100FD is based on the LAN91C100 FEAST, functional revision G modified to add full duplex
capability. Also added is a software-controlled option to allow collisions to discard receive packets.
Previously, the LAN91C100 supported a “Diagnostic Full Duplex” mode. Under this mode the transmit
packet is looped internally and received by the MAC. This mode was enabled using the FDUPLX bit in the
TCR. In order to avoid confusion, the new, broader full duplex function of the LAN91C100FD is
designated as Switched Full Duplex, and the TCR bit enabling it is designated as SWFDUP. When the
LAN91C100FD is configured for SWFDUP, it’s transmit and receive paths will operate independently and
some CSMA/CD functions will be disabled. When the controller is not configured for SWFDUP it will follow
the CSMA/CD protocol.
SMSC LAN91C100FD Rev. D
Page 5
Revision 1.0 (09-22-08)
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 2 Pin Configuration
A12
156
LNK
TXEN
XTAL1
XTAL2
VDD
1
2
3
4
A11
155
A10
154
A9
153
A8
5
152
A7
A6
A5
A4
MIISEL
nCSOUT
nRXDISC
TX25
6
7
8
9
151
150
149
148
A3
A2
A1
D8
VDD
D9
D10
VDD
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
147
146
145
144
143
142
141
RX_ER
RX_DV
IOS0
GND
IOS1
IOS2
D11
140
RX25
COL100
CRS100
RXD0
RXD1
RXD2
VDD
RXD3
TXD0
TXD1
VDD
TXD2
TXD3
TXEN100
nRWE0
GND
D12
139
GND
138
D13
D14
D15
137
LAN91C100FD
136
135
134
133
132
131
130
129
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
GND
D16
VDD
D17
D18
D19
GND
D20
D21
VDD
D22
D23
208 Pin QFP
and TQFP
RD7
RD6
RD5
RD4
RDMAH
RD3
RD2
RD1
VDD
GND
D24
GND
VDD
D25
D26
GND
D27
D28
D29
D30
GND
D31
nRDYRTN
nLDEV
VDD
nSRDY
LCLK
RD0
RD15
RD14
RD13
GND
RD12
RD11
RD10
GND
ENEEP
EEDO
Revision 1.0 (09-22-08)
Page 6
SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 3 Description of Pin Functions
PQFP/TQFP
PIN NO.
BUFFER
TYPE
NAME
SYMBOL
DESCRIPTION
148-159
Address
A4-A15
I
I
I
I
Input. Decoded by LAN91C100FD to determine
access to its registers.
145-147
193
Address
A1-A3
AEN
Input. Used by LAN91C100FD for internal
register selection.
Address
Enable
Input. Used as an address qualifier. Address
decoding is only enabled when AEN is low.
160-163
nByte
Enable
nBE0-
nBE3
Input. Used during LAN91C100FD register
accesses to determine the width of the access
and the register(s) being accessed. nBE0-nBE3
are ignored when nDATACS is low (burst
accesses) because 32 bit transfers are
assumed.
173-170,
168-166,
164, 144,
142-139,
137-135,
133,
Data Bus
D0-D31
I/O24
Bidirectional. 32 bit data bus used to access the
LAN91C100FD’s internal registers. Data bus
has weak internal pullups. Supports direct
connection to the system bus without external
buffering. For 16 bit systems, only D0-D15 are
used.
131-129,
127, 126,
124, 123,
121, 118,
117,
115-112,
110
182
Reset
RESET
nADS
IS
IS
Input. This input is not considered active unless
it is active for at least 100ns to filter narrow
glitches.
95
nAddress
Strobe
Input. For systems that require address latching,
the rising edge of nADS indicates the latching
moment for A1-A15 and AEN. All
LAN91C100FD internal functions of A1-A15,
AEN are latched except for nLDEV decoding.
183
184
181
nCycle
nCYCLE
W/nR
I
Input. This active low signal is used to control
LAN91C100FD EISA burst mode synchronous
bus cycles.
Write/
IS
Input. Defines the direction of synchronous
cycles. Write cycles when high, read cycles
when low.
nRead
nVL Bus
Access
nVLBUS
I with
pullup
Input. When low, the LAN91C100FD
synchronous bus interface is configured for VL
Bus accesses. Otherwise, the LAN91C100FD is
configured for EISA DMA burst accesses. Does
not affect the asynchronous bus interface.
105
Local Bus
Clock
LCLK
I
Input. Used to interface synchronous buses.
Maximum frequency is 50 MHz. Limited to 8.33
MHz for EISA DMA burst mode.
SMSC LAN91C100FD Rev. D
Page 7
Revision 1.0 (09-22-08)
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
PQFP/TQFP
PIN NO.
175
BUFFER
TYPE
NAME
SYMBOL
DESCRIPTION
Asynchron-
ous Ready
ARDY
OD16
O16
I
Open drain output. ARDY may be used when
interfacing asynchronous buses to extend
accesses. Its rising (access completion) edge is
controlled by the XTAL1 clock and, therefore,
asynchronous to the host CPU or bus clock.
106
109
nSynchron nSRDY
-
ous Ready
Output. This output is used when interfacing
synchronous buses and nVLBUS=0 to extend
accesses. This signal remains normally inactive,
and its falling edge indicates completion. This
signal is synchronous to the bus clock LCLK.
nReady
Return
nRDYRTN
Input. This input is used to complete
synchronous read cycles. In EISA burst mode it
is sampled on falling LCLK edges, and
synchronous cycles are delayed until it is
sampled high.
176,
Interrupt
INTR0-
INTR3
O24
O16
Outputs. Only one of these interrupts is selected
to be used; the other three are tri-stated. The
selection is determined by the value of INT SEL
1-0 bits in the Configuration Register.
187-189
108
nLocal
Device
nLDEV
Output. This active low output is asserted when
AEN is low and A4-A15 decode to the
LAN91C100FD address programmed into the
high byte of the Base Address Register. nLDEV
is a combinatorial decode of unlatched address
and AEN signals.
177
178
190
nRead
Strobe
nRD
IS
IS
Input. Used in asynchronous bus interfaces.
nWrite
Strobe
nWR
Input. Used in asynchronous bus interfaces.
nData
Path Chip
Select
nDATACS
I with
pullup
Input. When nDATACS is low, the Data Path
can be accessed regardless of the values of
AEN, A1-A15 and the content of the BANK
SELECT Register. nDATACS provides an
interface for bursting to and from the
LAN91C100FD 32 bits at a time.
54
55
EEPROM
Clock
EESK
EECS
O4
O4
Output. 4 μsec clock used to shift data in and
out of the serial EEPROM.
EEPROM
Select
Output. Serial EEPROM chip select. Used for
selection and command framing of the serial
EEPROM.
52
53
EEPROM
Data Out
EEDO
EEDI
O4
Output. Connected to the DI input of the serial
EEPROM.
EEPROM
Data In
I with
Input. Connected to the DO output of the serial
pulldown EEPROM.
13, 15, 16
I/O Base
IOS0-
IOS2
I with
pullup
Input. External switches can be connected to
these lines to select between predefined
EEPROM configurations.
51
Enable
EEPROM
ENEEP
I with
pullup
Input. Enables (when high or open)
LAN91C100FD accesses to the serial EEPROM.
Must be grounded if no EEPROM is connected
to the LAN91C100FD.
Revision 1.0 (09-22-08)
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SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
PQFP/TQFP
BUFFER
TYPE
NAME
SYMBOL
DESCRIPTION
PIN NO.
42, 40-38,
36-33
RAM Data RD0-RD7
Bus
I/O4 with Bidirectional. Carries the local buffer memory
pullups
read and write data. Reads are always 32 bits
wide. Writes are controlled individually at the
byte level. Floated if FLTST=1 during RECEIVE
FRAME STATUS WORD writes for packet
forwarding information (RA2-RA16=0,
RCVDMA=1, nRWE0-nRWE3=0).
59, 56,
49-47,
45-43,
RAM Data RD8-
I/O4 with Bidirectional. Carries the local buffer memory
Bus
RD31
pullups
read and write data. Reads are always 32 bits
wide. Writes are controlled individually at the
byte level.
69-67, 65,
64, 62-60,
81-76, 71,
70
84, 87, 88,
90, 91, 96,
99, 101,
100, 98, 89,
92, 103,
RAM
Address
Bus
RA2-RA16
nROE
O4
Outputs. This bus specifies the buffer RAM
doubleword being accessed by the
LAN91C100FD.
102, 104
97
O4
O4
O4
Iclk
Output. Active low signal used to read a
doubleword from buffer RAM.
31, 57, 73,
86
nRWE0-
RWE3
Outputs. Active low signals used to write any
byte, word or dword in RAM.
93
Receive
DMA
RCVDMA
Output. This pin is active during LAN91C100FD
write memory cycles of receive packets.
3
4
Crystal 1
Crystal 2
XTAL1
XTAL2
An external 25 MHz crystal is connected across
these pins. If a TTL clock is supplied instead, it
should be connected to XTAL1 and XTAL2
should be left open.
5, 10, 23,
27, 41, 63,
74, 83, 85,
107, 119,
125, 132,
143, 165,
179, 186,
191
Power
VDD
+5V power supply pins.
205
Analog
Power
AVDD
GND
+5V analog power supply pins.
Ground pins.
14, 32, 46,
50, 66, 75,
82, 94, 111,
116, 120,
122, 128,
134, 138,
169, 174,
180, 185,
200
Ground
203
Analog
Ground
AGND
TXEN
Analog ground pin.
2
Transmit
Enable
O4
Output. Used for 10 Mbps ENDEC. This pin
stays low when MIISEL is high.
SMSC LAN91C100FD Rev. D
Page 9
Revision 1.0 (09-22-08)
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
PQFP/TQFP
PIN NO.
201
BUFFER
TYPE
NAME
SYMBOL
DESCRIPTION
Transmit
Data
TXD
O4
Output. NRZ Transmit Data for 10 Mbps
ENDEC interface.
208
207
206
197
199
Carrier
Sense
CRS
COL
RXD
TXC
RXC
I with
Input. Carrier sense from 10 Mbps ENDEC
pulldown interface. This pin is ignored when MIISEL is
high.
Collision
Detect
I with
Input. Collision detection indication from 10
pulldown Mbps ENDEC interface. This pin is ignored
when MIISEL is high.
Receive
Data
I with
pullup
Input. NRZ Receive Data from 10 Mbps ENDEC
interface. This pin is ignored when MIISEL is
high.
Transmit
Clock
I with
pullup
Input. 10 MHz transmit clock used in 10 Mbps
operation. This pin is ignored when MIISEL is
high.
Receive
Clock
I with
pullup
Input. 10 MHz receive clock recovered by the 10
Mbps ENDEC. This pin is ignored when MIISEL
is high.
202
1
Loopback
LBK
O4
Output. Active when LOOP bit is set (TCR bit 1).
Independent of port selection (MIISEL=X).
nLink
Status
nLNK
I with
pullup
Input. General purpose input port used to
convey LINK status (EPHSR bit 14).
Independent of port selection (MIISEL=X).
195
6
nFullstep
MII Select
nFSTEP
MIISEL
O4
O4
Output. Non volatile output pin. Driven by
inverse of FULLSTEP (CONFIG bit 10).
Independent of port selection (MIISEL=X).
Output. Non volatile output pin. Driven by MII
SELECT (CONFIG bit 15). High indicates the
MII port is selected, low indicates the 10 Mbps
ENDEC is selected.
194
30
AUI Select AUISEL
O4
Output. Non volatile output pin. Driven by AUI
SELECT (CONFIG bit 8). Independent of port
selection (MIISEL= X).
Transmit
Enable
100 Mbps
TXEN100
CRS100
O12
Output to MII PHY. Envelope to 100 Mbps
transmission. This pin stays low if MIISEL is low.
19
Carrier
I with
Input from MII PHY. Envelope of packet
Sense 100
Mbps
pulldown reception used for deferral and backoff
purposes. This pin is ignored when MIISEL is
low.
12
18
Receive
Data Valid
RX_DV
I with
Input from MII PHY. Envelope of data valid
pulldown reception. Used for receive data framing. This
pin is ignored when MIISEL is low.
Collision
Detect
COL100
I with
Input from MII PHY. Collision detection input.
pulldown This pin is ignored when MIISEL is low.
100 Mbps
25, 26, 28,
29
Transmit
Data
TXD0-
TXD3
O12
Outputs. Transmit Data nibble to MII PHY.
9
Transmit
Clock
TX25
I with
pullup
Input. Transmit clock input from MII. Nibble rate
clock (25 MHz). This pin is ignored when
MIISEL is low.
17
Receive
Clock
RX25
I with
pullup
Input. Receive clock input from MII PHY. Nibble
rate clock. This pin is ignored when MIISEL is
low.
Revision 1.0 (09-22-08)
Page 10
SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
PQFP/TQFP
BUFFER
TYPE
NAME
SYMBOL
DESCRIPTION
PIN NO.
20, 21, 22,
24
Receive
Data
RXD0-
RXD3
I
Inputs. Received Data nibble from MII PHY.
These pins are ignored when MIISEL is low.
198
196
192
11
Manage-
ment Data
Input
MDI
I with
pulldown
MII management data input.
Manage-
ment Data
Output
MDO
O4
O4
MII management data output.
MII management clock.
Manage-
ment
Clock
MCLK
RX_ER
Receive
Error
I with
Input. Indicates a code error detected by PHY.
pulldown Used by the LAN91C100FD to discard the
packet being received. The error indication
reported for this event is the same as a bad CRC
(Receive Status Word bit 13). This pin is
ignored when MIISEL is low.
7
8
nChip
Select
Output
nCSOUT
nRXDISC
O4
Output. Chip Select provided for mapping of
PHY functions into LAN91C100FD decoded
space. Active on accesses to LAN91C100FD’s
eight lower addresses when the BANK
SELECTED is 7.
nReceive
Packet
Discard
I with
pullup
Input. Used to discard the receive packet being
stored in memory. Assertion of the pin during a
packet reception results in the interruption of
packet reception into memory. The memory
allocated to the packet and the packet number in
use are freed. The input is driven
asynchronously and is synchronized internally by
the LAN91C100FD. Pin assertion may take
place at any time during the receive DMA
packet. The assertion has no effect if there is no
packet being DMAed to memory or if asserted
during the last DMA write to memory. Works for
both MII and ENDEC. The typical use of
nRXDISC is with the LAN91C100FD in PRMS
mode with an external associative memory use
for address filtering. *Note: The pin must be
asserted for a minimum of 80ns.
37
RDMAH
O4
Output. Active when the first dword of the
address is written (RCVDMA=1, RA10-RA4=0,
RA3-RA2=X).
Buffer Types
O4
Output buffer with 2mA source and 4mA sink
Output buffer with 6mA source and 12mA sink
Output buffer with 8mA source and 16mA sink
Output buffer with 12mA source and 24mA sink
Open drain buffer with 16mA sink
O12
O16
O24
OD16
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FEAST Fast Ethernet Controller with Full Duplex Capability
I/O4
I/O24
I
Bidirectional buffer with 2mA source and 4mA sink
Bidirectional buffer with 12mA source and 24mA sink
Input buffer with TTL levels
IS
Input buffer with Schmitt Trigger Hysteresis
Clock input buffer
Iclk
DC levels and conditions defined in the DC Electrical Characteristics section.
Table 3.1 - LAN91C100FD Pin Requirements
FUNCTION
System Address Bus
System Data Bus
PIN SYMBOLS
A1-A15, AEN, nBE0-nBE3
D0-D31
NUMBER OF PINS
20
32
17
System Control Bus
RESET, nADS, LCLK, ARDY,
nRDYRTN, nSRDY, INTR0-
INTR3, nLDEV, nRD, nWR,
nDATACS, nCYCLE, W/nR,
nVLBUS
Serial EEPROM
EEDI, EEDO, EECS, EESK,
ENEEP, IOS0-IOS2
8
RAM Data Bus
RD0-RD31
RA2-RA16
32
15
7
RAM Address Bus
RAM Control Bus
nROE, nRWE0-nRWE3,
RCVDMA, RDMAH
Crystal Oscillator
Power
XTAL1, XTAL2
VDD, AVDD
GND, AGND
2
19
21
12
Ground
External ENDEC 10 Mbps
TXEN, TXD, CRS, COL, RXD,
TXC, RXC, LBK, nLNK,
nFSTEP, AUISEL, MIISEL
Physical Interface 100 Mbps
TXEN100, CRS100, COL100,
RX_DV, RX_ER, TXD0-TXD3,
RXD0-RXD3, MDI, MDO, MCLK
16
Clocks
TX25, RX25
2
2
Miscellaneous
TOTAL
nCSOUT, nRXDISC
205
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FEAST Fast Ethernet Controller with Full Duplex Capability
SERIAL
EEPROM
Address
10 Mb
Interface
ARBITER
DIRECT
MEMORY
ACCESS
BUS
INTERFACE
UNIT
Data
100
Media
MEDIA
Control
ACCESS
CONTROL
Independent
Interface
MEMORY
MANAGEMENT
UNIT
RD
FIFO
WR
FIFO
RAM
25 MHz
Figure 3.1 - LAN91C100FD Block Diagram
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
SERIAL
EEPROM
SYSTEM BUS
LAN83C69
1O Mbps
10BASE-T
10BASE-T
INTERFACE
ADDRESS
CONTROL
DATA
ADDRESS
CONTROL
LAN91C100FD
DATA
FEAST
100BASE-T4
INTERFACE
MII
CHIP
RA OE,WE RD0-31
100BASE-T4
OR
100BASE-TX
100BASE-TX/
INTERFACE
10BASE-T
LOGIC/
SRAM
32kx8
4
3
2
10BASE-T
1
Figure 3.2 - LAN91C100FD System Diagram
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FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 4 Functional Description
4.1
Description of Block
4.1.1 Clock Generator Block
1. The XTAL1 and XTAL2 pins are to be connected to a 25 MHz crystal.
2. TXCLK and RXCLK are 10 MHz clock inputs. These clocks are generated by the external ENDEC in
10 Mbps mode and are only used by the CSMA/CD block.
3. TX25 is an input clock. It will be the nibble rate of the particular PHY connected to the MII (2.5 MHz for
a 10 Mbps PHY, and 25 MHz for a 100 Mbps PHY).
4. RX25 - This is the MII nibble rate receive clock used for sampling received data nibbles and running
the receive state machine. (2.5 MHz for a 10 Mbps PHY, and 25 MHz for a 100 Mbps PHY).
5. LCLK - Bus clock - Used by the BIU for synchronous accesses. Maximum frequency is 50 MHz for VL
BUS mode, and 8.33 MHz for EISA slave DMA.
4.2
CSMA/CD Block
This is a 16 bit oriented block, with fully- independent Transmit and Receive logic. The data path in and out
of the block consists of two 16-bit wide uni-directional FIFOs interfacing the DMA block. The DMA port of
the FIFO stores 32 bits to exploit the 32 bit data path into memory, but the FIFOs themselves are 16 bit
wide. The Control Path consists of a set of registers interfaced to the CPU via the BIU.
4.2.1 DMA Block
This block accesses packet memory on the CSMA/CD’s behalf, fetching transmit data and storing received
data. It interfaces the CSMA/CD Transmit and Receive FIFOs on one side, and the Arbiter block on the
other. To increase the bandwidth into memory, a 50 MHz clock is used by the DMA block, and the data
path is 32 bits wide.
For example, during active reception at 100 Mbps, the CSMA/CD block will write a word into the Receive
FIFO every 160ns. The DMA will read the FIFO and accumulate two words on the output port to request a
memory cycle from the Arbiter every 320ns.
DMA will discard a packet if nRXDISC is asserted for a minimum of 80ns during a reception. If asserted
late, the DMA will receive the packet normally. The nRXDISC is defined valid for the DMA interface for as
long as the RCVDMA signal is active.
The DMA machine is able to support full duplex operation. Independent receive and transmit counters are
used. Transmit and receive cycles are alternated when simultaneous receive and transmit accesses are
needed.
4.2.2 Arbiter Block
The Arbiter block sequences accesses to packet RAM requested by the BIU and by the DMA blocks. BIU
requests represent pipelined CPU accesses to the Data Register, while DMA requests represent
CSMA/CD data movement. The external memory used is a 25ns SRAM.
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FEAST Fast Ethernet Controller with Full Duplex Capability
The Arbiter is also responsible for controlling the nRWE0-nRWE3 lines as a function of the bytes being
written. Read accesses are always 32 bit wide, and the Arbiter steers the appropriate byte(s) to the
appropriate lanes as a function of the address.
The CPU Data Path consists of two uni-directional FIFOs mapped at the Data Register location. These
FIFOs can be accessed in any combination of bytes, word, or doublewords. The Arbiter will indicate 'Not
Ready' whenever a cycle is initiated that cannot be satisfied by the present state of the FIFO.
4.2.3 MMU Block
The Hardware Memory Management Unit allocates memory and transmit and receive packet queues. It
also determines the value of the transmit and receive interrupts as a function of the queues. The page size
is 2k, with a maximum memory size of 128k. MIR and MCR values are interpreted in 512 byte units.
4.2.4 BIU Block
The Bus Interface Unit can handle synchronous as well as asynchronous buses; different signals are used
for each one. Transparent latches are added on the address path using rising nADS for latching.
When working with an asynchronous bus like ISA, the read and write operations are controlled by the
edges of nRD and nWR. ARDY is used for notifying the system that it should extend the access cycle. The
leading edge of ARDY is generated by the leading edge of nRD or nWR while the trailing edge of ARDY is
controlled by the internal LAN91C100FD clock and, therefore, asynchronous to the bus.
In the synchronous VL Bus type mode, nCYCLE and LCLK are used to for read and write operations.
Completion of the cycle may be determined by using nSRDY. nSRDY is controlled by LCLK and
synchronous to the bus.
Direct 32 bit access to the Data Path is supported by using the nDATACS input. By asserting nDATACS,
external DMA type of devices will bypass the BIU address decoders and can sequentially access memory
with no CPU intervention. nDATACS accesses can be used in the EISA DMA burst mode (nVLBUS=1) or
in asynchronous cycles. These cycles MUST be 32 bit cycles. Please refer to the corresponding timing
diagrams for details on these cycles.
The BIU is implemented using the following principles:
4.2.5 MAC-PHY Interface Block
Two separate interfaces are defined, one for the 10 Mbps bit rate interface and one for the MII 100 Mbps
and 10 Mbps nibble rate interface. The 10 Mbps ENDEC interface comprises the signals used for
interfacing Ethernet ENDECs. The 100 Mbps interface follows the MII for 100 Mbps 802.3 networks
proposal, and it is based on transferring nibbles between the MAC and the PHY.
For the MII interface, transmit data is clocked out using the TX25 clock input, while receive data is clocked
in using RX25.
In 100 Mbps mode, the LAN91C100FD provides the following interface signals to the PHY:
For transmission: TXEN100 TXD0-3 TX25
For reception: RX_DV RX_ER RXD0-3 RX25
For CSMA/CD state machines: CRS100 COL100
A transmission begins by TXEN100 going active (high), and TXD0-TXD3 having the first valid preamble
nibble. TXD0 carries the least significant bit of the nibble (that is the one that would go first out of the EPH
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FEAST Fast Ethernet Controller with Full Duplex Capability
at 100 Mbps), while TXD3 carries the most significant bit of the nibble. TXEN100 and TXD0-TXD3 are
clocked by the LAN91C100FD using TX25 rising edges. TXEN100 goes inactive at the end of the packet
on the last nibble of the CRC.
During a transmission, COL100 might become active to indicate a collision. COL100 is asynchronous to
the LAN91C100FD’s clocks and will be synchronized internally to TX25.
Reception begins when RX_DV (receive data valid) is asserted. A preamble pattern or flag octet will be
present at RXD0-RXD3 when RX_DV is activated. The LAN91C100FD requires no training sequence
beyond a full flag octet for reception. RX_DV as well as RXD0-RXD3 are sampled on RX25 rising edges.
RXD0 carries the least significant bit and RXD3 the most significant bit of the nibble. RX_DV goes inactive
when the last valid nibble of the packet (CRC) is presented at RXD0-RXD3.
RX_ER might be asserted during packet reception to signal the LAN91C100FD that the present receive
packet is invalid. The LAN91C100FD will discard the packet by treating it as a CRC error.
When MIISEL=1, RXD0-RXD3 should always be aligned to packet nibbles, therefore, opening flag
detection does not consider misaligned cases. Opening flag detection expects the 5Dh pattern and will not
reject the packet on non-preamble patterns. When MIISEL=0 the opening flag detection expects a
"10101011" pattern and will use it for determining nibble alignment.
CRS100 is used as a frame envelope signal for the CSMA/CD MAC state machines (deferral and backoff
functions), but it is not used for receive framing functions. CRS100 is an asynchronous signal and it will be
active whenever there is activity on the cable, including LAN91C100FD transmissions and collisions.
Switching between the ENDEC and MII interfaces is controlled by the MII SELECT bit in the CONFIG
REGISTER. The MIISEL pin reflects the value of this bit and may be used to control external multiplexing
logic.
Note that given the modular nature of the MII, TX25 and RX25 cannot be assumed to be free running
clocks. The LAN91C100FD will not rely on the presence of TX25 and RX25 during reset and will use its
own internal clock whenever a timeout on TX25 is detected.
4.2.6 MII Management Interface Block
PHY management through the MII management interface is supported by the LAN91C100FD by providing
the means to drive a tri-statable data output, a clock, and reading an input. Timing and framing for each
management command is to be generated by the CPU.
4.2.7 Serial EEPROM Interface
This block is responsible for reading the serial EEPROM upon hardware reset (or equivalent command)
and defining defaults for some key registers. A write operation is also implemented by this block, that
under CPU command will program specific locations in the EEPROM. This block is an autonomous state
machine and controls the internal Data Bus of the LAN91C100FD during active operation.
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FEAST Fast Ethernet Controller with Full Duplex Capability
EEPROM
EEPROM
INTERFACE
DATA BUS
TRANSMIT
RECEIVE
RX
FIFO
ADDRESS
BUS
TX
FIFO
CSMA/CD
DMA
BUS INTERFACE
CONTROL
TX
COMPL
FIFO
ARBITER
READ
WRITE
DATA
REG
DATA
REG
MMU
DATA
ADDRESS
BUFFER RAM
Figure 4.1 - LAN91C100FD Internal Bock Diagram with Data Path
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FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 5 Data Structures and Registers
5.1
Packet Format in Buffer Memory
The packet format in memory is similar for the Transmit and Receive areas. The first word is reserved for
the status word. The next word is used to specify the total number of bytes, and it is followed by the data
area. The data area holds the packet itself.
bit15
bit0
RAM OFFSET
(decimal)
0
2
4
STATUS
reserved
WORD
BYTE
COUNT
DATA AREA
~~
~~
~~
~~
2046 max
CONTROL BYTE
LAST DATA BYTE if odd
Figure 5.1 - Data Packet Format
TRANSMIT PACKET
RECEIVE PACKET
STATUS WORD
Written by CSMA upon transmit
Written by CSMA upon receive
completion (see Status Register) completion (see RX Frame
Status Word)
BYTE COUNT
DATA AREA
Written by CPU
Written by CSMA
Written by CSMA
Written/modified by CPU
CONTROL BYTE
Written by CPU to control
odd/even data bytes
Written by CSMA; also has
odd/even bit
BYTE COUNT - Divided by two, it defines the total number of words including the STATUS WORD, the
BYTE COUNT WORD, the DATA AREA and the CONTROL BYTE.
The receive byte count always appears as even; the ODDFRM bit of the receive status word indicates if the
low byte of the last word is relevant.
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FEAST Fast Ethernet Controller with Full Duplex Capability
The transmit byte count least significant bit will be assumed 0 by the controller regardless of the value
written in memory.
DATA AREA - The data area starts at offset 4 of the packet structure and can extend up to 2043 bytes.
The data area contains six bytes of DESTINATION ADDRESS followed by six bytes of SOURCE
ADDRESS, followed by a variable-length number of bytes. On transmit, all bytes are provided by the
CPU, including the source address. The LAN91C100FD does not insert its own source address. On
receive, all bytes are provided by the CSMA side.
The 802.3 Frame Length word (Frame Type in Ethernet) is not interpreted by the LAN91C100FD. It is
treated transparently as data both for transmit and receive operations.
CONTROL BYTE - For transmit packets the CONTROL BYTE is written by the CPU as:
X
X
ODD
CRC
0
0
0
0
ODD - If set, indicates an odd number of bytes, with the last byte being right before the CONTROL BYTE.
If clear, the number of data bytes is even and the byte before the CONTROL BYTE is not transmitted.
CRC - When set, CRC will be appended to the frame. This bit has only meaning if the NOCRC bit in the
TCR is set.
For receive packets the CONTROL BYTE is written by the controller as:
0
1
ODD
0
0
0
0
0
ODD - If set, indicates an odd number of bytes, with the last byte being right before the CONTROL BYTE.
If clear, the number of data bytes is even and the byte before the CONTROL BYTE should be ignored.
RECEIVE FRAME STATUS WORDRECEIVE FRAME STATUS WORD
This word is written at the beginning of each receive frame in memory. It is not available as a register.
HIGH
BYTE
ALGN
ERR
BROD
CAST
BAD
CRC
ODD
FRM
TOOLNG
TOO
SHORT
LOW
BYTE
HASH VALUE
MULT
CAST
5
4
3
2
1
0
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FEAST Fast Ethernet Controller with Full Duplex Capability
ALGNERR - Frame had alignment error. When MII SEL=1 alignment error is set when BADCRC=1 and an
odd number of nibbles was received between SFD and RX_DV going inactive. When MII SEL=0 alignment
error is set when BADCRC=1 and the number of bits received between SFD and the CRS going inactive is
not an octet multiple.
BRODCAST - Receive frame was broadcast.
BADCRC - Frame had CRC error, or RX_ER was asserted during reception.
ODDFRM - This bit when set indicates that the received frame had an odd number of bytes.
TOOLNG - Frame length was longer than 802.3 maximum size (1518 bytes on the cable).
TOOSHORT - Frame length was shorter than 802.3 minimum size (64 bytes on the cable).
HASH VALUE - Provides the hash value used to index the Multicast Registers. Can be used by receive
routines to speed up the group address search. The hash value consists of the six most significant bits of
the CRC calculated on the Destination Address, and maps into the 64 bit multicast table. Bits 5,4,3 of the
hash value select a byte of the multicast table, while bits 2,1,0 determine the bit within the byte selected.
Examples of the address mapping:
ADDRESS
HASH VALUE 5-0
000 000
MULTICAST TABLE BIT
MT-0 bit 0
ED 00 00 00 00 00
0D 00 00 00 00 00
01 00 00 00 00 00
2F 00 00 00 00 00
010 000
MT-2 bit 0
100 111
MT-4 bit 7
111 111
MT-7 bit 7
MULTCAST - Receive frame was multicast. If hash value corresponds to a multicast table bit that is set,
and the address was a multicast, the packet will pass address filtering regardless of other filtering criteria.
I/O SPACE
The base I/O space is determined by the IOS0-IOS2 inputs and the EEPROM contents. To limit the I/O
space requirements to 16 locations, the registers are assigned to different banks. The last word of the I/O
area is shared by all banks and can be used to change the bank in use. Registers are described using the
following convention:
OFFSET
NAME
TYPE
SYMBOL
HIGH
BYTE
bit 15
bit 14
bit 13
bit 12
bit 11
bit 10
bit 9
bit 8
X
X
X
X
X
X
X
X
LOW
bit 7
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
BYTE
X
X
X
X
X
X
X
X
OFFSET - Defines the address offset within the IOBASE where the register can be accessed at, provided
the bank select has the appropriate value.
The offset specifies the address of the even byte (bits 0-7) or the address of the complete word.
The odd byte can be accessed using address (offset + 1).
Some registers (like the Interrupt Ack., or like Interrupt Mask) are functionally described as two eight bit
registers, in that case the offset of each one is independently specified.
Regardless of the functional description, all registers can be accessed as doublewords, words or bytes.
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
The default bit values upon hard reset are highlighted below each register.
Table 5.1 - Internal I/O Space Mapping
BANK0
TCR
BANK1
CONFIG
BASE
BANK2
MMU COMMAND
PNR
BANK3
MT0-1
MT2-3
0
2
EPH STATUS
ARR
4
6
RCR
COUNTER
MIR
IA0-1
IA2-3
FIFO PORTS
POINTER
DATA
MT4-5
MT6-7
8
IA4-5
MGMT
A
C
E
MCR
GENERAL PURPOSE
CONTROL
DATA
REVISION
RCV
RESERVED (0)
BANK SELECT
INTERRUPT
BANK SELECT
BANK SELECT
BANK SELECT
A special BANK (BANK7) exists to support the addition of external registers.
BANK SELECT REGISTER
OFFSET
E
NAME
TYPE
SYMBOL
BANK SELECT
REGISTER
READ/WRITE
BSR
HIGH
BYTE
0
0
0
1
1
1
0
0
0
1
1
0
1
0
1
1
LOW
BS2
BS1
BS0
BYTE
X
X
X
X
X
0
0
0
BS2, BS1, BS0 Determine the bank presently in use. This register is always accessible and is used to
select the register bank in use.
The upper byte always reads as 33h and can be used to help determine the I/O location of the
LAN91C100FD.
The BANK SELECT REGISTER is always accessible regardless of the value of BS0-2.
Note:
The bank select register can be accessed as a doubleword at offset Ch, as a word at offset Eh, or as at
offset Fh, however a doubleword write to offset Ch will write the BANK SELECT REGISTER but will not
write the registers Ch and Dh.
BANK 7 has no internal registers other than the BANK SELECT REGISTER itself. On valid cycles where
BANK7 is selected (BS0=BS1=BS2=1), and A3=0, nCSOUT is activated to facilitate implementation of
external registers.
Note:
BANK7 does not exist in LAN91C9x devices. For backward S/W compatibility BANK7 accesses should be
done if the Revision Control register indicates the device is the LAN91C100FD.
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FEAST Fast Ethernet Controller with Full Duplex Capability
BANK 0
OFFSET
0
NAME
TYPE
SYMBOL
TCR
TRANSMIT CONTROL
REGISTER
READ/WRITE
This register holds bits programmed by the CPU to control some of the protocol transmit options.
HIGH
BYTE
SWFDU
P
0
EPH
STP
SQET
0
FDUPLX
MON_
CSN
0
NOCRC
LOOP
0
0
0
0
0
0
0
0
0
0
LOW
PAD_EN
0
FORCOL
LOOP
TXENA
BYTE
0
0
0
0
0
0
0
0
SWFDUP - Enables Switched Full Duplex mode. In this mode, transmit state machine is inhibited from
recognizing carrier sense, so deferrals will not occur. Also inhibits collision count, therefore, the collision
related status bits in the EPHSR are not valid (CTR_ROL, LATCOL, SQET, 16COL, MUL COL, and
SNGL COL). Uses COL100 as flow control, limiting backoff and jam to 1 clock each before inter-frame
gap, then retry will occur after IFG. If COL100 is active during preamble, full preamble will be output
before jam. When SWFDUP is high, the values of FDUPLX and MON_CSN have no effect. This bit should
be low for non-MII operation.
EPH_LOOP - Internal loopback at the EPH block. Serial data is internally looped back when set. Defaults
low. When EPH_LOOP is high the following transmit outputs are forced inactive: TXD0-TXD3 = 0h,
TXEN100 = TXEN = 0, TXD = 1. The following and external inputs are blocked: CRS=CRS100=0,
COL=COL100=0, RX_DV= RX_ER=0.
STP_SQET - Stop transmission on SQET error. If set, stops and disables transmitter on SQE test error.
Does not stop on SQET error and transmits next frame if clear. Defaults low.
FDUPLX - When set, the LAN91C100FD will cause frames to be received if they pass the address filter
regardless of the source of the frame. When clear, the node will not receive a frame sourced by itself.
This bit does not control the duplex mode operation, the duplex mode operation is controlled by the
SWFDUP bit.
MON_CSN - When set the LAN91C100FD monitors carrier while transmitting. It must see its own carrier
by the end of the preamble. If it is not seen, or if carrier is lost during transmission, the transmitter aborts
the frame without CRC and turns itself off and sets the LOST CARR bit in the EPHSR. When this bit is
clear the transmitter ignores its own carrier. Defaults low. Should be 0 for MII operation.
NOCRC - Does not append CRC to transmitted frames when set. Allows software to insert the desired
CRC. Defaults to zero, namely CRC inserted.
PAD_EN - When set, the LAN91C100FD will pad transmit frames shorter than 64 bytes with 00. The CPU
should write the actual byte count (1 – 1514/1518) into the BYTE COUNT area in the transmit buffer RAM.
If the CPU provides the 4 byte CRC, the maximum byte count will be 1518. If the CPU elects to have the
LAN91C100FD provide the CRC, the maximum byte count will be 1514. The CPU should then write the
actual packet data in the DATA AREA of the transmit buffer RAM. The LAN91C100FD will then determine
if padding is necessary, (BYTE COUNT AREA less then 64). If padding is required, the LAN91C100FD will
append data bytes of 00 to meet the minimum requirement of 64 bytes. When this bit is cleared, the
LAN91C100FD does not pad frames.
FORCOL - When set, the FORCOL bit will force a collision by not deferring deliberately. This bit is set and
cleared only by the CPU. When TXENA is enabled with no packets in the queue and while the FORCOL
bit is set, the LAN91C100FD will transmit a preamble pattern the next time a carrier is seen on the line. If a
packet is queued, a preamble and SFD will be transmitted. This bit defaults low to normal operation.
NOTE: The LATCOL bit in the EPHSR, setting up as a result of FORCOL, will reset TXENA to 0. In order
to force another collision, TXENA must be set to 1 again.
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FEAST Fast Ethernet Controller with Full Duplex Capability
LOOP - Loopback. General purpose output port used to control the LBK pin. Typically used to put the PHY
chip in loopback mode.
TXENA - Transmit enabled when set. Transmit is disabled if clear. When the bit is cleared the
LAN91C100FD will complete the current transmission before stopping. When stopping due to an error, this
bit is automatically cleared.
BANK 0
OFFSET
2
NAME
TYPE
SYMBOL
EPHSR
EPH STATUS REGISTER
READ ONLY
This register stores the status of the last transmitted frame. This register value, upon individual transmit
packet completion, is stored as the first word in the memory area allocated to the packet. Packet interrupt
processing should use the copy in memory as the register itself will be updated by subsequent packet
transmissions. The register can be used for real time values (like TXENA and LINK OK). If TXENA is
cleared the register holds the last packet completion status.
HIGH
BYTE
Reserved
0
LINK_
OK
0
CTR
_ROL
0
EXC
_DEF
0
LOST
CARR
0
LATCOL
0
0
-nLNK
pin
0
0
LOW
BYTE
TX
DEFR
0
LTX
BRD
0
SQET
16COL
LTX
MULT
0
MUL
COL
0
SNGL
COL
0
TX_SUC
0
0
0
LINK_OK - General purpose input port driven by nLNK pin inverted. Typically used for Link Test. A
transition on the value of this bit generates an interrupt.
CTR_ROL - Counter Roll Over. When set one or more 4 bit counters have reached maximum count (15).
Cleared by reading the ECR register.
EXC_DEF - Excessive Deferral. When set last/ current transmit was deferred for more than 1518 * 2 byte
times. Cleared at the end of every packet sent.
LOST_CARR - Lost Carrier Sense. When set indicates that Carrier Sense was not present at end of
preamble. Valid only if MON_CSN is enabled. This condition causes TXENA bit in TCR to be reset.
Cleared by setting TXENA bit in TCR.
LATCOL - Late collision detected on last transmit frame. If set a late collision was detected (later than 64
byte times into the frame). When detected the transmitter jams and turns itself off clearing the TXENA bit
in TCR. Cleared by setting TXENA in TCR.
TX_DEFR - Transmit Deferred. When set, carrier was detected during the first 6.4 μs of the inter frame
gap. Cleared at the end of every packet sent.
LTX_BRD - Last transmit frame was a broadcast. Set if frame was broadcast. Cleared at the start of every
transmit frame.
SQET - Signal Quality Error Test. In MII, SQET bit is always set after first transmit, except if SWFDUP=1.
As a consequence, the STP_SQET bit in the TCR register cannot be set as it will always result in transmit
fatal error. In non-MII systems, the transmitter opens a 1.6 μs window 0.8 μs after transmission is
completed and the receiver returns inactive. During this window, the transmitter expects to see the SQET
signal from the transceiver. The absence of this signal is a 'Signal Quality Error' and is reported in this
status bit. Transmission stops and EPH INT is set if STP_SQET is in the TCR is also set when SQET is
set. This bit is cleared by setting TXENA high.
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FEAST Fast Ethernet Controller with Full Duplex Capability
16COL - 16 collisions reached. Set when 16 collisions are detected for a transmit frame. TXENA bit in
TCR is reset. Cleared when TXENA is set high.
LTX_MULT - Last transmit frame was a multicast. Set if frame was a multicast. Cleared at the start of
every transmit frame.
MULCOL - Multiple collision detected for the last transmit frame. Set when more than one collision was
experienced. Cleared when TX_SUC is high at the end of the packet being sent.
SNGLCOL - Single collision detected for the last transmit frame. Set when a collision is detected. Cleared
when TX_SUC is high at the end of the packet being sent.
TX_SUC - Last transmit was successful. Set if transmit completes without a fatal error. This bit is cleared
by the start of a new frame transmission or when TXENA is set high. Fatal errors are:
16 collisions (1/2 duplex mode only)
SQET fail and STP_SQET = 1 (1/2 duplex mode only)
Carrier lost and MON_CSN = 1 (1/2 duplex mode only)
Late collision (1/2 duplex mode only)
BANK 0
OFFSET
4
NAME
TYPE
READ/WRITE
SYMBOL
RCR
RECEIVE CONTROL
REGISTER
HIGH
BYTE
SOFT
RST
FILT
CAR
0
ABORT_E
NB
0
Reserved
Reserved
STRIP
CRC
0
RXEN
0
0
0
0
0
0
RX_
ABORT
0
LOW
BYTE
Reserved
Reserved
Reserved
Reserved
Reserved
ALMUL
PRMS
0
0
0
0
0
0
0
SOFT_RST - Software-Activated Reset. Active high. Initiated by writing this bit high and terminated by
writing the bit low. The LAN91C100FD’s configuration is not preserved except for Configuration, Base, and
IA0-IA5 Registers. EEPROM is not reloaded after software reset.
FILT_CAR - Filter Carrier. When set filters leading edge of carrier sense for 12 bit times (3 nibble times).
Otherwise recognizes a receive frame as soon as carrier sense is active. (Does NOT filter RX DV on MII!)
ABORT_ENB - Enables abort of receive when collision occurs. Defaults low. When set, the
LAN91C100FD will automatically abort a packet being received when the appropriate collision input is
activated (COL100 for MII, COL for non-MII). This bit has no effect if the SWFDUP bit in the TCR is set.
STRIP_CRC - When set it strips the CRC on received frames. When clear the CRC is stored in memory
following the packet. Defaults low.
RXEN - Enables the receiver when set. If cleared, completes receiving current frame and then goes idle.
Defaults low on reset.
ALMUL - When set accepts all multicast frames (frames in which the first bit of DA is '1'). When clear
accepts only the multicast frames that match the multicast table setting. Defaults low.
PRMS - Promiscuous mode. When set receives all frames. Does not receive its own transmission unless
it is in Full Duplex!
RX_ABORT - This bit is set if a receive frame was aborted due to length longer than 2K bytes. The frame
will not be received. The bit is cleared by RESET or by the CPU writing it low.
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
Reserved - Must be 0.
BANK 0
OFFSET
NAME
COUNTER REGISTER
TYPE
READ ONLY
SYMBOL
ECR
6
Counts four parameters for MAC statistics. When any counter reaches 15 an interrupt is issued. All
counters are cleared when reading the register and do not wrap around beyond 15.
HIGH
BYTE
NUMBER OF EXC. DEFFERED TX
NUMBER OF DEFFERED TX
0
0
0
0
0
0
0
0
0
0
LOW
BYTE
MULTIPLE COLLISION COUNT
SINGLE COLLISION COUNT
0
0
0
0
0
0
Each four bit counter is incremented every time the corresponding event, as defined in the EPH STATUS
REGISTER bit description, occurs. Note that the counters can only increment once per enqueued transmit
packet, never faster, limiting the rate of interrupts that can be generated by the counters. For example if a
packet is successfully transmitted after one collision the SINGLE COLLISION COUNT field is incremented
by one. If a packet experiences between 2 to 16 collisions, the MULTIPLE COLLISION COUNT field is
incremented by one. If a packet experiences deferral the NUMBER OF DEFERRED TX field is
incremented by one, even if the packet experienced multiple deferrals during its collision retries.
The COUNTER REGISTER facilitates maintaining statistics in the AUTO RELEASE mode where no
transmit interrupts are generated on successful transmissions.
Reading the register in the transmit service routine will be enough to maintain statistics.
BANK 0
OFFSET
8
NAME
TYPE
SYMBOL
MIR
MEMORY INFORMATION
REGISTER
READ ONLY
HIGH
BYTE
FREE MEMORY AVAILABLE (IN BYTES * 256 * M)
1
1
1
1
1
1
1
1
1
1
1
1
LOW
BYTE
MEMORY SIZE (IN BYTES *256 * M)
1
1
1
1
FREE MEMORY AVAILABLE - This register can be read at any time to determine the amount of free
memory. The register defaults to the MEMORY SIZE upon reset or upon the RESET MMU command.
MEMORY SIZE - This register can be read to determine the total memory size.
All memory related information is represented in 256 * M byte units, where the multiplier M is determined
by the MCR upper byte.
These register default to FFh, which should be interpreted as 256.
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FEAST Fast Ethernet Controller with Full Duplex Capability
BANK 0
OFFSET
A
NAME
TYPE
SYMBOL
MCR
MEMORY
CONFIGURATION
REGISTER
Lower Byte - READ/WRITE
Upper Byte - READ ONLY
HIGH
MEMORY SIZE MULTIPLIER
BYTE
0
0
0
1
1
0
1
0
1
0
LOW
BYTE
MEMORY RESERVED FOR TRANSMIT (IN BYTES * 256 * M)
0
0
0
0
0
0
MEMORY RESERVED FOR TRANSMIT - Programming this value allows the host CPU to reserve
memory to be used later for transmit, limiting the amount of memory that receive packets can use. When
programmed for zero, the memory allocation between transmit and receive is completely dynamic. When
programmed for a non-zero value, the allocation is dynamic if the free memory exceeds the programmed
value, while receive allocation requests are denied if the free memory is less or equal to the programmed
value. This register defaults to zero upon reset. It is not affected by the RESET MMU command.
The value written to the MCR is a reserved memory space IN ADDITION TO ANY MEMORY
CURRENTLY IN USE. If the memory allocated for transmit plus the reserved space for transmit is required
to be constant (rather than grow with transmit allocations) the CPU should update the value of this register
after allocating or releasing memory.
The contents of the MIR as well as the low byte of the MCR are specified in units of 256 * M bytes, where
M is the Memory Size Multiplier. M=2 for the LAN91C100FD. A value of 04h in the lower byte of the MCR
is equal to one 2K page (4 * 256 *2 = 2K); since memory must be reserved in multiples of pages, bits 0
and 1 of the MCR should be written to 1 only when the entire memory is being reserved for transmit (i.e.,
low byte of MCR = FFh).
BANK1
OFFSET
0
NAME
TYPE
SYMBOL
CR
CONFIGURATION REGISTER
READ/WRITE
The Configuration Register holds bits that define the adapter configuration and are not expected to change
during run-time. This register is part of the EEPROM saved setup.
HIGH
BYTE
MII
SELECT
NO
WAIT
FULL
STEP
0
AUI
SELECT
1
1
0
0
1
1
0
0
0
0
0
0
LOW
BYTE
Reserved
INT
SEL1
INT
SEL0
1
0
1
0
0
1
MII SELECT - Used to select the network interface port. When set, the LAN91C100FD will use its MII port
and interface a PHY device at the nibble rate. When clear, the LAN91C100FD will use its 10 Mbps ENDEC
interface. This bit drives the MII SEL pin. Switching between ports should be done with transmitter and
receiver disabled and no transmit/receive packets in progress.
NO WAIT - When set, does not request additional wait states. An exception to this are accesses to the
Data Register if not ready for a transfer. When clear, negates IOCHRDY for two to three clocks on any
cycle to the LAN91C100FD.
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FEAST Fast Ethernet Controller with Full Duplex Capability
FULL STEP - This bit is a general purpose output port. Its inverse value drives pin nFSTEP and it is
typically connected to SEL pin of the LAN83C694. It can be used to select the signaling mode for the AUI
or as a general purpose non-volatile configuration pin. Defaults low.
AUI SELECT - This bit is a general purpose output port. Its value drives pin AUISEL and it is typically
connected to MODE1 pin of the LAN83C694. It can be used to select AUI vs. 10BASE-T, or as a general
purpose non-volatile configuration pin. Defaults low.
Reserved - Must be 0.
INT SEL1-0 - Used to select one out of four interrupt pins. The three unused interrupts are tristated.
INTERRUPT PIN
INT SEL1
INT SEL0
USED
INTR0
INTR1
INTR2
INTR3
0
0
1
1
0
1
0
1
BANK 1
OFFSET
2
NAME
BASE ADDRESS REGISTER
TYPE
READ/WRITE
SYMBOL
BAR
This register holds the I/O address decode option chosen for the LAN91C100FD. It is part of the EEPROM
saved setup and is not usually modified during run-time.
HIGH
BYTE
A15
0
A14
0
A13
0
A9
A8
1
A7
0
A6
0
A5
1
0
1
LOW
Reserved
BYTE
0
0
0
0
0
0
0
1
A15 - A13 and A9 - A5 - These bits are compared against the I/O address on the bus to determine the
IOBASE for the LAN91C100FD‘s registers. The 64k I/O space is fully decoded by the LAN91C100FD
down to a 16 location space, therefore the unspecified address lines A4, A10, A11 and A12 must be all
zeros.
All bits in this register are loaded from the serial EEPROM. The I/O base decode defaults to 300h
(namely, the high byte defaults to 18h).
Reserved - Must be 0.
BANK 1
OFFSET
4 THROUGH 9
NAME
TYPE
SYMBOL
IAR
INDIVIDUAL ADDRESS
REGISTERS
READ/WRITE
These registers are loaded starting at word location 20h of the EEPROM upon hardware reset or
EEPROM reload. The registers can be modified by the software driver, but a STORE operation will not
modify the EEPROM Individual Address contents. Bit 0 of Individual Address 0 register corresponds to the
first bit of the address on the cable.
Revision 1.0 (09-22-08)
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FEAST Fast Ethernet Controller with Full Duplex Capability
LOW
ADDRESS 0
BYTE
0
0
0
0
0
0
0
0
HIGH
BYTE
ADDRESS 1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LOW
BYTE
ADDRESS 2
0
0
HIGH
BYTE
ADDRESS 3
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LOW
BYTE
ADDRESS 4
0
0
HIGH
BYTE
ADDRESS 5
0
0
0
0
0
0
0
0
BANK 1
OFFSET
A
NAME
GENERAL PURPOSE REGISTER
TYPE
READ/WRITE
SYMBOL
GPR
HIGH
BYTE
HIGH DATA BYTE
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LOW
BYTE
LOW DATA BYTE
0
0
This register can be used as a way of storing and retrieving non-volatile information in the EEPROM to be
used by the software driver. The storage is word oriented, and the EEPROM word address to be read or
written is specified using the six lowest bits of the Pointer Register.
This register can also be used to sequentially program the Individual Address area of the EEPROM, that is
normally protected from accidental Store operations.
This register will be used for EEPROM read and write only when the EEPROM SELECT bit in the Control
Register is set. This allows generic EEPROM read and write routines that do not affect the basic setup of
the LAN91C100FD.
BANK 1
OFFSET
C
NAME
CONTROL REGISTER
TYPE
READ/WRITE
SYMBOL
CTR
HIGH
BYTE
0
0
RCV_ BAD
0
0
1
AUTO
RELEASE
0
0
1
0
0
1
1
0
1
0
LOW
BYTE
LE
ENABLE
CR
ENABLE
TE
ENABLE
0
EEPROM
SELECT
RELOAD
STORE
0
0
0
1
0
0
0
0
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FEAST Fast Ethernet Controller with Full Duplex Capability
RCV_BAD - When set, bad CRC packets are received. When clear bad CRC packets do not generate
interrupts and their memory is released.
Note:
nRXDISC, when asserted, overrides RCV_BAD. Also, RCV_ BAD does not modify the function of RCV
DISCARD in the RCV register.
AUTO RELEASE - When set, transmit pages are released by transmit completion if the transmission was
successful (when TX_SUC is set). In that case there is no status word associated with its packet number,
and successful packet numbers are not even written into the TX COMPLETION FIFO. A sequence of
transmit packets will generate an interrupt only when the sequence is completely transmitted (TX EMPTY
INT will be set), or when a packet in the sequence experiences a fatal error (TX INT will be set). Upon a
fatal error TXENA is cleared and the transmission sequence stops. The packet number that failed, is
present in the FIFO PORTS register, and its pages are not released, allowing the CPU to restart the
sequence after corrective action is taken.
LE ENABLE - Link Error Enable. When set it enables the LINK_OK bit transition as one of the interrupts
merged into the EPH INT bit. Clearing the LE ENABLE bit after an EPH INT interrupt, caused by a
LINK_OK transition, will acknowledge the interrupt. LE ENABLE defaults low (disabled).
CR ENABLE - Counter Roll over Enable. When set, it enables the CTR_ROL bit as one of the interrupts
merged into the EPH INT bit. Reading the COUNTER register after an EPH INT interrupt caused by a
counter rollover, will acknowledge the interrupt. CR ENABLE defaults low (disabled).
TE ENABLE - Transmit Error Enable. When set it enables Transmit Error as one of the interrupts merged
into the EPH INT bit. An EPH INT interrupt caused by a transmitter error is acknowledged by setting
TXENA bit in the TCR register to 1 or by clearing the TE ENABLE bit. TE ENABLE defaults low (disabled).
Transmit Error is any condition that clears TXENA with TX_SUC staying low as described in the EPHSR
register.
EEPROM SELECT - This bit allows the CPU to specify which registers the EEPROM RELOAD or STORE
refers to. When high, the General Purpose Register is the only register read or written. When low,
RELOAD reads Configuration, Base and Individual Address, and STORE writes the Configuration and
Base registers.
RELOAD - When set it will read the EEPROM and update relevant registers with its contents. Clears upon
completing the operation.
STORE - When set, stores the contents of all relevant registers in the serial EEPROM. Clears upon
completing the operation.
Note:
When an EEPROM access is in progress the STORE and RELOAD bits will be read back as high. The
remaining 14 bits of this register will be invalid. During this time attempted read/write operations, other
than polling the EEPROM status, will NOT have any effect on the internal registers. The CPU can resume
accesses to the LAN91C100FD after both bits are low. A worst case RELOAD operation initiated by
RESET or by software takes less than 750 μs.
BANK2
OFFSET
0
NAME
MMU COMMAND
REGISTER
TYPE
WRITE ONLY
BUSY Bit Readable
SYMBOL
MMUCR
This register is used by the CPU to control the memory allocation, de-allocation, TX FIFO and RX FIFO
control.
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FEAST Fast Ethernet Controller with Full Duplex Capability
The three command bits determine the command issued as described below:
HIGH
BYTE
LOW
BYTE
COMMAND
y
0
0
N2
N1
N0/BUSY
0
x
z
COMMAND SET:
xyz
000
001
0)
1)
NOOP - NO OPERATION
ALLOCATE MEMORY FOR TX - N2,N1,N0 defines the amount of memory requested as
(value + 1) * 256 bytes. Namely N2,N1,N0 = 1 will request 2 * 256 = 512 bytes. A shift-based
divide by 256 of the packet length yields the appropriate value to be used as N2,N1,N0.
Immediately generates a completion code at the ALLOCATION RESULT REGISTER. Can
optionally generate an interrupt on successful completion. N2,N1,N0 are ignored by the
LAN91C100FD but should be implemented in LAN91C100FD software drivers for LAN9000
compatibility.
010
011
2)
3)
RESET MMU TO INITIAL STATE - Frees all memory allocations, clears relevant interrupts,
resets packet FIFO pointers.
REMOVE FRAME FROM TOP OF RX FIFO - To be issued after CPU has completed
processing of present receive frame. This command removes the receive packet number from
the RX FIFO and brings the next receive frame (if any) to the RX area (output of RX FIFO).
100
101
4)
5)
REMOVE AND RELEASE TOP OF RX FIFO - Like 3) but also releases all memory used by
the packet presently at the RX FIFO output. The MMU busy time after issuing REMOVE and
RELEASE command depends on the time when the busy bit is cleared. The time from issuing
REMOVE and RELEASE command on the last receive packet to the time when receive FIFO
is empty depends on RX INT bit turning low. An alternate approach can be checking the read
RX FIFO register.
RELEASE SPECIFIC PACKET - Frees all pages allocated to the packet specified in the
PACKET NUMBER REGISTER. Should not be used for frames pending transmission.
Typically used to remove transmitted frames, after reading their completion status. Can be
used following 3) to release receive packet memory in a more flexible way than 4).
110
111
6)
7)
ENQUEUE PACKET NUMBER INTO TX FIFO - This is the normal method of transmitting a
packet just loaded into RAM. The packet number to be enqueued is taken from the PACKET
NUMBER REGISTER.
RESET TX FIFOs - This command will reset both TX FIFOs: The TX FIFO holding the packet
numbers awaiting transmission and the TX Completion FIFO. This command provides a
mechanism for canceling packet transmissions, and reordering or bypassing the transmit
queue. The RESET TX FIFOs command should only be used when the transmitter is
disabled. Unlike the RESET MMU command, the RESET TX FIFOs does not release any
memory.
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
Notes:
Bits N2,N1,N0 bits are ignored by the LAN91C100FD but should be used for command 0 to preserve software
compatibility with the LAN91C92 and future devices. They should be zero for all other commands.
When using the RESET TX FIFOS command, the CPU is responsible for releasing the memory associated with
outstanding packets, or re-enqueuing them. Packet numbers in the completion FIFO can be read via the FIFO ports
register before issuing the command.
MMU commands releasing memory (commands 4 and 5) should only be issued if the corresponding packet number
has memory allocated to it.
COMMAND SEQUENCING
A second allocate command (command 1) should not be issued until the present one has completed.
Completion is determined by reading the FAILED bit of the allocation result register or through the
allocation interrupt.
A second release command (commands 4, 5) should not be issued if the previous one is still being
processed. The BUSY bit indicates that a release command is in progress. After issuing command 5, the
contents of the PNR should not be changed until BUSY goes low. After issuing command 4, command 3
should not be issued until BUSY goes low.
BUSY BIT - Readable at bit 0 of the MMU command register address. When set indicates that MMU is still
processing a release command. When clear, MMU has already completed last release command. BUSY
and FAILED bits are set upon the trailing edge of command.
BANK 2
OFFSET
2
NAME
TYPE
SYMBOL
PNR
PACKET NUMBER REGISTER
READ/WRITE
0
0
0
0
PACKET NUMBER AT TX AREA
0
0
0
0
0
0
PACKET NUMBER AT TX AREA - The value written into this register determines which packet number is
accessible through the TX area. Some MMU commands use the number stored in this register as the
packet number parameter. This register is cleared by a RESET or a RESET MMU Command.
OFFSET
3
NAME
TYPE
SYMBOL
ARR
ALLOCATION RESULT REGISTER
READ ONLY
This register is updated upon an ALLOCATE MEMORY MMU command.
FAILED
1
0
0
ALLOCATED PACKET NUMBER
0
0
0
0
0
0
FAILED - A zero indicates a successful allocation completion. If the allocation fails the bit is set and only
cleared when the pending allocation is satisfied. Defaults high upon reset and reset MMU command. For
polling purposes, the ALLOC_INT in the Interrupt Status Register should be used because it is
synchronized to the read operation. Sequence:
1. Allocate Command
2. Poll ALLOC_INT bit until set
3. Read Allocation Result Register
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FEAST Fast Ethernet Controller with Full Duplex Capability
ALLOCATED PACKET NUMBER - Packet number associated with the last memory allocation request.
The value is only valid if the FAILED bit is clear.
Note:
For software compatibility with future versions, the value read from the ARR after an allocation request is
intended to be written into the PNR as is, without masking higher bits (provided FAILED = 0).
BANK 2
OFFSET
4
NAME
TYPE
SYMBOL
FIFO
FIFO PORTS REGISTER
READ ONLY
This register provides access to the read ports of the Receive FIFO and the Transmit completion FIFO.
The packet numbers to be processed by the interrupt service routines are read from this register.
HIGH
REMPTY
0
RX FIFO PACKET NUMBER
BYTE
1
0
0
0
0
0
0
0
0
0
0
0
0
LOW
BYTE
TEMPTY
TX DONE PACKET NUMBER
1
0
0
0
REMPTY - No receive packets queued in the RX FIFO. For polling purposes, uses the RCV_INT bit in the
Interrupt Status Register.
TOP OF RX FIFO PACKET NUMBER - Packet number presently at the output of the RX FIFO. Only valid
if REMPTY is clear. The packet is removed from the RX FIFO using MMU Commands 3) or 4).
TEMPTY - No transmit packets in completion queue. For polling purposes, uses the TX_INT bit in the
Interrupt Status Register.
TX DONE PACKET NUMBER - Packet number presently at the output of the TX Completion FIFO. Only
valid if TEMPTY is clear. The packet is removed when a TX INT acknowledge is issued.
Note:
For software compatibility with future versions, the value read from each FIFO register is intended to be
written into the PNR as is, without masking higher bits (provided TEMPTY and REMPTY = 0 respectively).
BANK 2
OFFSET
6
NAME
TYPE
SYMBOL
PTR
POINTER REGISTER
READ/WRITE
NOT EMPTY is a read
only bit
HIGH
BYTE
RCV
0
AUTO
INCR.
READ
0
Reserved
0
NOT
EMPTY
POINTER HIGH
0
0
0
0
0
0
0
0
LOW
BYTE
POINTER LOW
0
0
0
0
0
POINTER REGISTER - The value of this register determines the address to be accessed within the
transmit or receive areas. It will auto-increment on accesses to the data register when AUTO INCR. is set.
The increment is by one for every byte access, by two for every word access, and by four for every double
word access. When RCV is set the address refers to the receive area and uses the output of RX FIFO as
the packet number, when RCV is clear the address refers to the transmit area and uses the packet number
at the Packet Number Register.
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READ - Determines the type of access to follow. If the READ bit is high the operation intended is a read. If
the READ bit is low the operation is a write. Loading a new pointer value, with the READ bit high,
generates a pre-fetch into the Data Register for read purposes.
Readback of the pointer will indicate the value of the address last accessed by the CPU (rather than the
last pre-fetched). This allows any interrupt routine that uses the pointer, to save it and restore it without
affecting the process being interrupted. The Pointer Register should not be loaded until the Data Register FIFO is
empty. The NOT EMPTY bit of this register can be read to determine if the FIFO is empty. On reads, if IOCHRDY is
not connected to the host, the Data Register should not be read before 370ns after the pointer was loaded to allow the
Data Register FIFO to fill.
If the pointer is loaded using 8 bit writes, the low byte should be loaded first and the high byte last.
Reserved – Must be 0.
NOT EMPTY - When set indicates that the Write Data FIFO is not empty yet. The CPU can verify that the
FIFO is empty before loading a new pointer value. This is a read only bit.
Note:
If AUTO INCR. is not set, the pointer must be loaded with a dword aligned value.
BANK 2
OFFSET
NAME
TYPE
SYMBOL
DATA
8 THROUGH BH
DATA REGISTER
READ/WRITE
DATA HIGH
X
X
X
X
X
X
X
X
X
X
X
X
X
DATA LOW
X
X
X
DATA REGISTER - Used to read or write the data buffer byte/word presently addressed by the pointer
register.
This register is mapped into two uni-directional FIFOs that allow moving words to and from the
LAN91C100FD regardless of whether the pointer address is even, odd or dword aligned. Data goes
through the write FIFO into memory, and is pre-fetched from memory into the read FIFO. If byte accesses
are used, the appropriate (next) byte can be accessed through the Data Low or Data High registers. The
order to and from the FIFO is preserved. Byte, word and dword accesses can be mixed on the fly in any
order.
This register is mapped into two consecutive word locations to facilitate double word move operations
regardless of the actual bus width (16 or 32 bits). The DATA register is accessible at any address in the 8
through Ah range, while the number of bytes being transferred is determined by A1 and nBE0-nBE3. The
FIFOs are 12 bytes each.
BANK 2
OFFSET
C
NAME
TYPE
SYMBOL
IST
INTERRUPT STATUS REGISTER
READ ONLY
RX_DISC
Reserved
0
EPH INT
0
RX_OVRN
INT
ALLOC
INT
TX EMPTY
INT
TX INT
RCV INT
0
INT
0
0
0
1
0
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FEAST Fast Ethernet Controller with Full Duplex Capability
OFFSET
C
NAME
TYPE
SYMBOL
ACK
INTERRUPT ACKNOWLEDGE
REGISTER
WRITE ONLY
RX_DISC
Reserved
RX_OVRN
INT
TX EMPTY
INT
TX INT
INT
OFFSET
NAME
TYPE
SYMBOL
MSK
D
INTERRUPT MASK REGISTER
READ/WRITE
RX_DISC
INT
Reserved
0
EPH INT
0
RX_OVRN
INT
ALLOC
INT
TX EMPTY
INT
TX INT
RCV INT
0
0
0
0
0
0
This register can be read and written as a word or as two individual bytes.
The Interrupt Mask Register bits enable the appropriate bits when high and disable them when low. A
MASK bit being set will cause a hardware interrupt.
Note:
The Bit 7 mask must never be written high (1).
RX_DISC INT - Set when the nRXDISC PIN COUNTER in the RCV register increments to a value of FF.
The RX_DISC INT bit latches the condition for the purpose of being polled or generating an interrupt, and
will only be cleared by writing the acknowledge register with the RX_DISC INT bit set.
Reserved – Must be 0.
EPH INT - Set when the Ethernet Protocol Handler section indicates one out of various possible special
conditions. This bit merges exception type of interrupt sources, whose service time is not critical to the
execution speed of the low level drivers. The exact nature of the interrupt can be obtained from the EPH
Status Register (EPHSR), and enabling of these sources can be done via the Control Register. The
possible sources are:
1. LINK - Link Test transition
2. CTR_ROL - Statistics counter roll over
3. TXENA cleared - A fatal transmit error occurred forcing TXENA to be cleared. TX_SUC will be low
and the specific reason will be reflected by the bits:
3.1 SQET - SQE Error
3.2 LOST CARR - Lost Carrier
3.3 LATCOL - Late Collision
3.4 16COL - 16 collisions
Any of the above interrupt sources can be masked by the appropriate ENABLE bits in the Control Register.
1) LE ENABLE (Link Error Enable), 2) CR ENABLE (Counter Roll Over), 3) TE ENABLE (Transmit Error
Enable)
EPH INT will only be cleared by the following methods:
1. Clearing the LE ENABLE bit in the Control Register if an EPH interrupt is caused by a LINK_OK
transition.
2. Reading the Counter Register if an EPH interrupt is caused by statistics counter roll over.
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FEAST Fast Ethernet Controller with Full Duplex Capability
3. Setting TXENA bit high if an EPH interrupt is caused by any of the fatal transmit error listed above (3.1
to 3.5).
RX_OVRN INT - Set when 1) the receiver aborts due to an overrun due to a failed memory allocation, 2)
the receiver aborts due to a packet length of greater than 2K bytes, or 3) the receiver aborts due to the
RCV DISCRD bit in the RCV register set. The RX_OVRN INT bit latches the condition for the purpose of
being polled or generating an interrupt, and will only be cleared by writing the acknowledge register with
the RX_OVRN INT bit set.
ALLOC INT - Set when an MMU request for TX RAM page is successful. This bit is the complement of the
FAILED bit in the ALLOCATION RESULT register. The ALLOC INT bit is cleared by the MMU when the
next allocation request is processed or allocation fails.
TX EMPTY INT - Set if the TX FIFO goes empty, can be used to generate a single interrupt at the end of a
sequence of packets enqueued for transmission. This bit latches the empty condition, and the bit will stay
set until it is specifically cleared by writing the acknowledge register with the TX EMPTY INT bit set. If a
real time reading of the FIFO empty is desired, the bit should be first cleared and then read.
The TX EMPTY Mask bit should only be set after the following steps:
a. a packet is enqueued for transmission
b. the previous empty condition is cleared (acknowledged)
TX INT - Set when at least one packet transmission was completed or any of the below transmit fatal
errors occurs:
1. SQET - SQE Error
2. LOST CARR - Lost Carrier
3. LATCOL - Late Collision
4. 16COL - 16 collisions
The first packet number to be serviced can be read from the FIFO PORTS register. The TX INT bit is
always the logic complement of the TEMPTY bit in the FIFO PORTS register. After servicing a packet
number, its TX INT interrupt is removed by writing the Interrupt Acknowledge Register with the TX INT bit
set.
RCV INT - Set when a receive interrupt is generated. The first packet number to be serviced can be read
from the FIFO PORTS register. The RCV INT bit is always the logic complement of the REMPTY bit in the
FIFO PORTS register. The Receive Interrupt is cleared when RX FIFO is empty.
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FEAST Fast Ethernet Controller with Full Duplex Capability
Figure 5.2 - Interrupt Structure
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FEAST Fast Ethernet Controller with Full Duplex Capability
BANK3
OFFSET
NAME
TYPE
SYMBOL
MT
0 THROUGH 7
MULTICAST TABLE
READ/WRITE
LOW
MULTICAST TABLE 0
BYTE
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
HIGH
BYTE
MULTICAST TABLE 1
0
0
LOW
BYTE
MULTICAST TABLE 2
0
0
HIGH
BYTE
MULTICAST TABLE 3
0
0
LOW
BYTE
MULTICAST TABLE 4
0
0
HIGH
BYTE
MULTICAST TABLE 5
0
0
LOW
BYTE
MULTICAST TABLE 6
0
0
HIGH
BYTE
MULTICAST TABLE 7
0
0
The 64 bit multicast table is used for group address filtering. The hash value is defined as the six most
significant bits of the CRC of the destination addresses. The three msb's determine the register to be used
(MT0-MT7), while the other three determine the bit within the register.
If the appropriate bit in the table is set, the packet is received.
If the ALMUL bit in the RCR register is set, all multicast addresses are received regardless of the multicast
table values.
Hashing is only a partial group addressing filtering scheme, but being the hash value available as part of
the receive status word, the receive routine can reduce the search time significantly. With the proper
memory structure, the search is limited to comparing only the multicast addresses that have the actual
hash value in question.
BANK 3
OFFSET
8
NAME
TYPE
SYMBOL
MGMT
MANAGEMENT INTERFACE
READ/WRITE
HIGH
BYTE
FLTST
0
MSK_
CRS100
0
1
1
1
1
0
0
1
1
LOW
BYTE
MDOE
MCLK
MDI
MDO
0
0
0
0
MDI Pin
0
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FEAST Fast Ethernet Controller with Full Duplex Capability
FLTST - Facilitates the inclusion of packet forwarding information on the receive packet memory structure.
When 0, RD0-RD7 is always driven. When 1, RD0-RD7 is floated during RECEIVE FRAME STATUS
WORD writes (RA2-RA16=0, RCVDMA=1, nRWE0-nRWE3=0).
MSK_CRS100 - Disables CRS100 detection during transmit in half duplex mode (SWFDUP=0).
MDO - MII Management output. The value of this bit drives the MDO pin.
MDI - MII Management input. The value of the MDI pin is readable using this bit.
MDCLK - MII Management clock. The value of this bit drives the MDCLK pin.
MDOE - MII Management output enable. When high pin MDO is driven, when low pin MDO is tri-stated.
The purpose of this interface, along with the corresponding pins is to implement MII PHY management in
software.
BANK 3
OFFSET
A
NAME
TYPE
SYMBOL
REV
REVISION REGISTER
READ ONLY
HIGH
BYTE
0
1
0
0
1
0
1
0
0
0
0
0
1
0
1
0
LOW
BYTE
CHIP
REV
CHIP - Chip ID. Can be used by software drivers to identify the device used.
REV - Revision ID. Incremented for each revision of a given device.
OFFSET
C
NAME
RCV REGISTER
TYPE
READ/WRITE
SYMBOL
RCV
HIGH
BYTE
nRXDISC PIN COUNTER
0
0
0
0
0
0
0
0
0
LOW
BYTE
RCV
DISCR
D
0
MBO
MBO
MBO
MBO
MBO
0
0
0
1
1
1
1
1
nRXDISC PIN COUNTER - 8-bit counter increments when a packet is discarded due to the nRXDISC pin
being active. This counter will be reset to 00 when read. A count of FF will set the RX_DISC INT. The
count will wrap around to 00 after FF.
RCV DISCRD - Set to discard a packet being received. Will discard packets only in the process of being
received. When set prior to the end of receive packet, bit 4 (RXOVRN) of the interrupt status register will
be set to indicate that the packet was discarded. Otherwise, the packet will be received normally and bit 0
set (RCVINT) in the interrupt status register. RCV DISCRD is self clearing.
MBO – Must be 1.
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FEAST Fast Ethernet Controller with Full Duplex Capability
BANK7
OFFSET
0 THROUGH 7
NAME
TYPE
SYMBOL
EXTERNAL REGISTERS
nCSOUT is driven low by the LAN91C100FD when a valid access to the EXTERNAL REGISTER range
occurs.
HIGH
BYTE
EXTERNAL R/W REGISTER
LOW
EXTERNAL R/W REGISTER
BYTE
CYCLE
NCSOUT
LAN91C100FD DATA BUS
Ignored on writes.
AEN=0
A3=0
Driven low. Transparently
latched on nADS rising edge.
Tri-stated on reads.
A4-15 matches I/O BASE
BANK SELECT = 7
BANK SELECT = 4,5,6
Otherwise
High
High
Ignore cycle.
Normal LAN91C100FD cycle.
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FEAST Fast Ethernet Controller with Full Duplex Capability
5.2
Typical Flow of Events for Transmit (Auto Release = 0)
S/W DRIVER
MAC SIDE
1
2
ISSUE ALLOCATE MEMORY FOR TX - N
BYTES - the MMU attempts to allocate N bytes
of RAM.
WAIT FOR SUCCESSFUL COMPLETION
CODE - Poll until the ALLOC INT bit is set or
enable its mask bit and wait for the interrupt.
The TX packet number is now at the Allocation
Result Register.
3
4
LOAD TRANSMIT DATA - Copy the TX packet
number into the Packet Number Register. Write
the Pointer Register, then use a block move
operation from the upper layer transmit queue
into the Data Register.
ISSUE "ENQUEUE PACKET NUMBER TO TX
FIFO" - This command writes the number
present in the Packet Number Register into the
TX FIFO. The transmission is now enqueued.
No further CPU intervention is needed until a
transmit interrupt is generated.
5
6
The enqueued packet will be transferred to the
MAC block as a function of TXENA (nTCR) bit
and of the deferral process (1/2 duplex mode
only) state.
a) Upon transmit completion the first word in
memory is written with the status word. The
packet number is moved from the TX FIFO
into the TX completion FIFO. Interrupt is
generated by the TX completion FIFO being
not empty.
b) If a TX failure occurs on any packets, TX
INT is generated and TXENA is cleared,
transmission sequence stops. The packet
number of the failure packet is presented at
the TX FIFO PORTS Register.
7
a) SERVICE INTERRUPT - Read Interrupt
Status Register. If it is a transmit interrupt,
read the TX FIFO Packet Number from the
FIFO Ports Register. Write the packet
number into the Packet Number Register.
The corresponding status word is now
readable from memory. If status word
shows successful transmission, issue
RELEASE packet number command to free
up the memory used by this packet.
Remove packet number from completion
FIFO by writing TX INT Acknowledge
Register.
b) Option 1) Release the packet.
Option 2) Check the transmit status in the
EPH STATUS Register, write the packet
number of the current packet to the Packet
Number Register, re-enable TXENA, then
go to step 4 to start the TX sequence again.
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FEAST Fast Ethernet Controller with Full Duplex Capability
5.3
Typical Flow of Events for Transmit (Auto Release = 1)
S/W DRIVER
MAC SIDE
1
2
ISSUE ALLOCATE MEMORY FOR TX - N
BYTES - the MMU attempts to allocate N bytes
of RAM.
WAIT FOR SUCCESSFUL COMPLETION
CODE - Poll until the ALLOC INT bit is set or
enable its mask bit and wait for the interrupt.
The TX packet number is now at the Allocation
Result Register.
3
4
LOAD TRANSMIT DATA - Copy the TX packet
number into the Packet Number Register. Write
the Pointer Register, then use a block move
operation from the upper layer transmit queue
into the Data Register.
ISSUE "ENQUEUE PACKET NUMBER TO TX
FIFO" - This command writes the number
present in the Packet Number Register into the
TX FIFO. The transmission is now enqueued.
No further CPU intervention is needed until a
transmit interrupt is generated.
5
The enqueued packet will be transferred to the
MAC block as a function of TXENA (nTCR) bit
and of the deferral process (1/2 duplex mode
only) state.
6
7
Transmit pages are released by transmit
completion.
a) The MAC generates a TXEMPTY interrupt
upon a completion of a sequence of
enqueued packets.
b) If a TX failure occurs on any packets, TX
INT is generated and TXENA is cleared,
transmission sequence stops. The packet
number of the failure packet is presented at
the TX FIFO PORTS Register.
8
a) SERVICE INTERRUPT – Read Interrupt
Status Register, exit the interrupt service
routine.
b) Option 1) Release the packet.
Option 2) Check the transmit status in the
EPH STATUS Register, write the packet
number of the current packet to the Packet
Number Register, re-enable TXENA, then
go to step 4 to start the TX sequence again.
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FEAST Fast Ethernet Controller with Full Duplex Capability
5.4
Typical Flow of Events for Receive
S/W DRIVER
MAC SIDE
1
2
ENABLE RECEPTION - By setting the RXEN
bit.
A packet is received with matching address.
Memory is requested from MMU. A packet
number is assigned to it. Additional memory is
requested if more pages are needed.
3
4
The internal DMA logic generates sequential
addresses and writes the receive words into
memory. The MMU does the sequential to
physical address translation. If overrun, packet
is dropped and memory is released.
When the end of packet is detected, the status
word is placed at the beginning of the receive
packet in memory. Byte count is placed at the
second word. If the CRC checks correctly the
packet number is written into the RX FIFO. The
RX FIFO, being not empty, causes RCV INT
(interrupt) to be set. If CRC is incorrect the
packet memory is released and no interrupt will
occur.
5
SERVICE INTERRUPT - Read the Interrupt
Status Register and determine if RCV INT is set.
The next receive packet is at receive area. (Its
packet number can be read from the FIFO Ports
Register). The software driver can process the
packet by accessing the RX area, and can move
it out to system memory if desired. When
processing is complete the CPU issues the
REMOVE AND RELEASE FROM TOP OF RX
command to have the MMU free up the used
memory and packet number.
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FEAST Fast Ethernet Controller with Full Duplex Capability
ISR
Save Bank Select & Address
Ptr Registers
Mask SMC91C100FD
Interrupts
Read Interrupt Register
No
Yes
RX INTR?
Yes
TX INTR?
Call TX INTR or TXEMPTY
INTR
No
Call RXINTR
Get Next TX
ALLOC INTR?
Packet
No
Yes
Available for
Transmission?
Write Allocated Pkt # into
Packet Number Reg.
Yes
No
Call ALLOCATE
Write Ad Ptr Reg. & Copy Data
& Source Address
Enqueue Packet
EPH INTR?
Yes
No
Set "Ready for Packet" Flag
Restore Address Pointer &
Bank Select Registers
Call EPH INTR
Return Buffers to Upper Layer
Unmask SMC91C100FD
Interrupts
Disable Allocation Interrupt
Mask
Exit ISR
Figure 5.3 - Interrupt Service Routine
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FEAST Fast Ethernet Controller with Full Duplex Capability
RX INTR
Write Ad. Ptr. Reg. & Read
Word 0 from RAM
No
Yes
Destination
Multicast?
Read Words 2, 3, 4 from RAM
for Address Filtering
Address
Filtering Pass?
No
Yes
Yes
No
Status Word
OK?
Do Receive Lookahead
Get Copy Specs from Upper
Layer
Okay to
Copy?
No
Yes
Copy Data Per Upper Layer
Specs
Issue "Remove and Release"
Command
Return to ISR
Figure 5.4 - RX INTR
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FEAST Fast Ethernet Controller with Full Duplex Capability
TX INTR
Save Pkt Number Register
Read TXDONE Pkt # from
FIFO Ports Reg.
Write Into Packet Number
Register
Write Address Pointer Register
Read Status Word from RAM
Yes
No
TX Status
OK?
Update Statistics
Re-Enable TXENA
Immediately Issue "Release"
Command
Update Variables
Acknowledge TXINTR
Read TX INT Again
No
TX INT = 0?
Yes
Restore Packet Number
Return to ISR
Figure 5.5 - TX INTR
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FEAST Fast Ethernet Controller with Full Duplex Capability
TXEMPTY INTR
Write Acknowledge Reg. with
TXEMPTY Bit Set
Read TXEMPTY & TX INTR
TXEMPTY = 1
&
TXINT = 0
TXEMPTY = 0
&
TXINT = 0
TXEMPTY = X
&
TXINT = 1
(Everything went through
successfully)
(Waiting for Completion)
(Transmission Failed)
Read Pkt. # Register & Save
Write Address Pointer
Register
Read Status Word from RAM
Update Statistics
Update Variables
Issue "Release" Command
Acknowledge TXINTR
Re-Enable TXENA
Restore Packet Number
Return to ISR
Figure 5.6 - TXEMPTY INTR (Assumes Auto release Option Selected)
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
DRIVER SEND
ALLOCATE
Choose Bank Select
Register 2
Issue "Allocate Memory"
Command to MMU
Call ALLOCATE
Exit Driver Send
Read Interrupt Status Register
Yes
No
Allocation
Passed?
Read Allocation Result
Register
Write Allocated Packet into
Packet # Register
Store Data Buffer Pointer
Clear "Ready for Packet" Flag
Enable Allocation Interrupt
Write Address Pointer Register
Copy Part of TX Data Packet
into RAM
Write Source Address into
Proper Location
Copy Remaining TX Data
Packet into RAM
Enqueue Packet
Set "Ready for Packet" Flag
Return Buffers to Upper Layer
Return
Figure 5.7 - Drive Send and Allocate Routines
5.5
Memory Partitioning
Unlike other controllers, the LAN91C100FD does not require a fixed memory partitioning between transmit
and receive resources. The MMU allocates and de-allocates memory upon different events. An additional
mechanism allows the CPU to prevent the receive process from starving the transmit memory allocation.
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FEAST Fast Ethernet Controller with Full Duplex Capability
Memory is always requested by the side that needs to write into it, that is: the CPU for transmit or the MAC
for receive. The CPU can control the number of bytes it requests for transmit but it cannot determine the
number of bytes the receive process is going to demand. Furthermore, the receive process requests will
be dependent on network traffic, in particular on the arrival of broadcast and multicast packets that might
not be for the node, and that are not subject to upper layer software flow control.
In order to prevent unwanted traffic from using too much memory, the CPU can program a "memory
reserved for transmit" parameter. If the free memory falls below the "memory reserved for transmit" value,
MMU requests from the MAC block will fail and the packets will overrun and be ignored. Whenever
enough memory is released, packets can be received again. If the reserved value is too large, the node
might lose data which is an abnormal condition. If the value is kept at zero, memory allocation is handled
on first-come first-served basis for the entire memory capacity.
Note that with the memory management built into the LAN91C100FD, the CPU can dynamically program
this parameter. For instance, when the driver does not need to enqueue transmissions, it can allow more
memory to be allocated for receive (by reducing the value of the reserved memory). Whenever the driver
needs to burst transmissions it can reduce the receive memory allocation. The driver program the
parameter as a function of the following variables:
1. Free memory (read only register)
2. Memory size (read only register)
The reserved memory value can be changed on the fly. If the MEMORY RESERVED FOR TX value is
increased above the FREE MEMORY, receive packets in progress are still received, but no new packets
are accepted until the FREE MEMORY increases above the MEMORY RESERVED value.
5.6
Interrupt Generation
The interrupt strategy for the transmit and receive processes is such that it does not represent the
bottleneck in the transmit and receive queue management between the software driver and the controller.
For that purpose there is no register reading necessary before the next element in the queue (namely
transmit or receive packet) can be handled by the controller. The transmit and receive results are placed
in memory.
The receive interrupt will be generated when the receive queue (FIFO of packets) is not empty and receive
interrupts are enabled. This allows the interrupt service routine to process many receive packets without
exiting, or one at a time if the ISR just returns after processing and removing one.
There are two types of transmit interrupt strategies:
1. One interrupt per packet.
2. One interrupt per sequence of packets.
The strategy is determined by how the transmit interrupt bits and the AUTO RELEASE bit are used.
TX INT bit - Set whenever the TX completion FIFO is not empty.
TX EMPTY INT bit - Set whenever the TX FIFO is empty.
AUTO RELEASE - When set, successful transmit packets are not written into completion FIFO, and their
memory is released automatically.
1. One interrupt per packet: enable TX INT, set AUTO RELEASE=0. The software driver can find the
completion result in memory and process the interrupt one packet at a time. Depending on the
completion code the driver will take different actions. Note that the transmit process is working in
parallel and other transmissions might be taking place. The LAN91C100FD is virtually queuing the
packet numbers and their status words.
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FEAST Fast Ethernet Controller with Full Duplex Capability
In this case, the transmit interrupt service routine can find the next packet number to be serviced by
reading the TX DONE PACKET NUMBER at the FIFO PORTS register. This eliminates the need for the
driver to keep a list of packet numbers being transmitted. The numbers are queued by the LAN91C100FD
and provided back to the CPU as their transmission completes.
2. One interrupt per sequence of packets: Enable TX EMPTY INT and TX INT, set AUTO RELEASE=1.
TX EMPTY INT is generated only after transmitting the last packet in the FIFO.
TX INT will be set on a fatal transmit error allowing the CPU to know that the transmit process has
stopped and therefore the FIFO will not be emptied.
This mode has the advantage of a smaller CPU overhead, and faster memory de-allocation. Note that
when AUTO RELEASE=1 the CPU is not provided with the packet numbers that completed
successfully.
Note:
The pointer register is shared by any process accessing the LAN91C100FD memory. In order to allow
processes to be interruptable, the interrupting process is responsible for reading the pointer value before
modifying it, saving it, and restoring it before returning from the interrupt.
Typically there would be three processes using the pointer:
1. Transmit loading (sometimes interrupt driven)
2. Receive unloading (interrupt driven)
3. Transmit Status reading (interrupt driven).
1) and 3) also share the usage of the Packet Number Register. Therefore saving and restoring the PNR is
also required from interrupt service routines.
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FEAST Fast Ethernet Controller with Full Duplex Capability
INTERRUPT
'NOT EMPTY'
STATUS REGISTER
RCV
INT
PACKET NUMBER
REGISTER
RX FIFO
PACKET NUMBER
TX EMPTY
INT
TWO
OPTIONS
TX
INT
ALLOC
INT
'EMPTY'
RX PACKET
NUMBER
'NOT EMPTY'
TX DONE
PACKET NUMBER
CSMA ADDRESS
CPU ADDRESS
CS
MA
/CD
MM
U
M.S. BIT ONLY
PACK # OUT
RA
M
Figure 5.8 - Interrupt Generation for Transmit, Receive, MMU
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FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 6 Board Setup Information
The following parameters are obtained from the EEPROM as board setup information:
ETHERNET INDIVIDUAL ADDRESS
I/O BASE ADDRESS
10BASET or AUI INTERFACE
MII or ENDEC INTERFACE
INTERRUPT LINE SELECTION
All the above mentioned values are read from the EEPROM upon hardware reset. Except for the
INDIVIDUAL ADDRESS, the value of the IOS switches determines the offset within the EEPROM for these
parameters, in such a way that many identical boards can be plugged into the same system by just
changing the IOS jumpers.
In order to support a software utility based installation, even if the EEPROM was never programmed, the
EEPROM can be written using the LAN91C100FD. One of the IOS combination is associated with a fixed
default value for the key parameters (I/O BASE, INTERRUPT) that can always be used regardless of the
EEPROM based value being programmed. This value will be used if all IOS pins are left open or pulled
high.
The EEPROM is arranged as a 64 x 16 array. The specific target device is the 9346 1024-bit Serial
EEPROM. All EEPROM accesses are done in words. All EEPROM addresses in the spec are specified as
word addresses.
REGISTER
EEPROM WORD ADDRESS
Configuration Register
IOS Value * 4
Base Register
(IOS Value * 4) + 1
INDIVIDUAL ADDRESS 20-22 hex
If IOS2-IOS0 = 7, only the INDIVIDUAL ADDRESS is read from the EEPROM. Currently assigned values
are assumed for the other registers. These values are default if the EEPROM read operation follows
hardware reset.
The EEPROM SELECT bit is used to determine the type of EEPROM operation: a) normal or b) general
purpose register.
a) NORMAL EEPROM OPERATION - EEPROM SELECT bit = 0
On EEPROM read operations (after reset or after setting RELOAD high) the CONFIGURATION
REGISTER and BASE REGISTER are updated with the EEPROM values at locations defined by the
IOS2-0 pins. The INDIVIDUAL ADDRESS registers are updated with the values stored in the
INDIVIDUAL ADDRESS area of the EEPROM.
On EEPROM write operations (after setting the STORE bit) the values of the CONFIGURATION
REGISTER and BASE REGISTER are written in the EEPROM locations defined by the IOS2-IOS0
pins.
The three least significant bits of the CONTROL REGISTER (EEPROM SELECT, RELOAD and
STORE) are used to control the EEPROM. Their values are not stored nor loaded from the EEPROM.
b) GENERAL PURPOSE REGISTER - EEPROM SELECT bit = 1
On EEPROM read operations (after setting RELOAD high) the EEPROM word address defined by the
POINTER REGISTER 6 least significant bits is read into the GENERAL PURPOSE REGISTER.
Revision 1.0 (09-22-08)
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DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
On EEPROM write operations (after setting the STORE bit) the value of the GENERAL PURPOSE
REGISTER is written at the EEPROM word address defined by the POINTER REGISTER 6 least
significant bits.
RELOAD and STORE are set by the user to initiate read and write operations respectively. Polling the
value until read low is used to determine completion. When an EEPROM access is in progress the
STORE and RELOAD bits of CTR will readback as both bits high. No other bits of the LAN91C100FD
can be read or written until the EEPROM operation completes and both bits are clear. This
mechanism is also valid for reset initiated reloads.
Note:
If no EEPROM is connected to the LAN91C100FD, for example for some embedded applications, the
ENEEP pin should be grounded and no accesses to the EEPROM will be attempted. Configuration, Base,
and Individual Address assume their default values upon hardware reset and the CPU is responsible for
programming them for their final value.
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
16 BITS
IOS2-0
WORD ADDRESS
000
0h
CONFIGURATION REG.
BASE REG.
1h
001
010
011
4h
5h
CONFIGURATION REG.
BASE REG.
8h
9h
CONFIGURATION REG.
BASE REG.
Ch
Dh
CONFIGURATION REG.
BASE REG.
100
101
110
10h
11h
CONFIGURATION REG.
BASE REG.
14h
15h
CONFIGURATION REG.
BASE REG.
18h
19h
CONFIGURATION REG.
BASE REG.
XXX
20h
21h
22h
IA0-1
IA2-3
IA4-5
Figure 6.1 - 64 X 16 Serial EEPROM Map
Revision 1.0 (09-22-08)
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SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 7 Application Considerations
The LAN91C100FD is envisioned to fit a few different bus types. This section describes the basic
guidelines, system level implications and sample configurations for the most relevant bus types. All
applications are based on buffered architectures with a private SRAM bus.
7.1
Fast Ethernet Slave Adapter
Slave non-intelligent board implementing 100 Mbps and 10 Mbps speeds.
Adapter requires:
a) LAN91C100FD chip
b) Four SRAMs (32k x 8 - 25ns)
c) Serial EEPROM (93C46)
d) Mbps ENDEC and transceiver chip
e) Mbps MII compliant PHY
f) Some bus specific glue logic
Target systems:
a) VL Local Bus 32 bit systems
b) High-end ISA or non-burst EISA machines
c) EISA 32 bit slave
7.2
VL Local Bus 32 Bit Systems
On VL Local Bus and other 32 bit embedded systems the LAN91C100FD is accessed as a 32 bit
peripheral in terms of the bus interface. All registers except the DATA REGISTER will be accessed using
byte or word instructions. Accesses to the DATA REGISTER could use byte, word, or dword instructions.
Table 7.1 - VL Local Bus Signal Connections
VL BUS
SIGNAL
LAN91C100
SIGNAL
NOTES
A2-A15
A2-A15
Address bus used for I/O space and register decoding, latched
by nADS rising edge, and transparent on nADS low time.
M/nIO
AEN
Qualifies valid I/O decoding - enabled access when low. This
signal is latched by nADS rising edge and transparent on nADS
low time.
W/nR
W/nR
Direction of access. Sampled by the LAN91C100FD on first
rising clock that has nCYCLE active. High on writes, low on
reads.
nRDYRTN
nLRDY
nRDYRTN
Ready return. Direct connection to VL bus.
nSRDY and
some logic
nSRDY has the appropriate functionality and timing to create the
VL nLRDY except that nLRDY behaves like an open drain output
most of the time.
LCLK
LCLK
Local Bus Clock. Rising edges used for synchronous bus
interface transactions.
nRESET
RESET
Connected via inverter to the LAN91C100FD.
nBE0 nBE1
nBE2 nBE3
nBE0 nBE1
nBE2 nBE3
Byte enables. Latched transparently by nADS rising edge.
SMSC LAN91C100FD Rev. D
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VL BUS
SIGNAL
LAN91C100
SIGNAL
NOTES
nADS
nADS, nCYCLE
INTR0-INTR3
D0-D31
Address Strobe is connected directly to the VL bus. nCYCLE is
created typically by using nADS delayed by one LCLK.
IRQn
Typically uses the interrupt lines on the ISA edge connector of
VL bus
D0-D31
32 bit data bus. The bus byte(s) used to access the device are a
function of nBE0-nBE3:
nBE0
nBE1
nBE2
nBE3
0
0
1
0
1
1
1
0
0
1
1
0
1
1
0
1
0
1
1
0
1
0
1
0
1
1
1
0
Double word access
Low word access
High word access
Byte 0 access
Byte 1 access
Byte 2 access
Byte 3 access
Not used = tri-state on reads, ignored on writes. Note that nBE2
and nBE3 override the value of A1, which is tied low in this
application.
nLDEV
nLDEV
nLDEV is a totem pole output. nLDEV is active on valid decodes
of A15-A4 and AEN=0.
UNUSED PINS
VCC
GND
nRD nWR
A1 nVLBUS
nDATACS
OPEN
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FEAST Fast Ethernet Controller with Full Duplex Capability
VL BUS
W/nR
W/nR
A2-A15
LCLK
A2-A15
LCLK
M/nIO
AEN
nRESET
RESET
INTR0-INTR3
D0-D31
nRDYRTN
nBE0-nBE3
nADS
LAN91C100FD
IRQn
D0-D31
nRDYRTN
nBE0-nBE3
nADS
delay 1 LCLK
nCYCLE
nSRDY
nLDEV
O.C.
nLRDY
simulated
O.C.
nLDEV
Figure 7.1 - LAN91C100FD on VL BUS
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
7.3
High End ISA or Non-Burst EISA Machines
On ISA machines, the LAN91C100FD is accessed as a 16 bit peripheral. No support for XT (8 bit
peripheral) is provided. The signal connections are listed in the following table:
Table 7.2 - High-End ISA or Non-Burst EISA Machines Signal Connectors
ISA BUS
SIGNAL
LAN91C100FD
SIGNAL
NOTES
A1-A15
AEN
A1-A15
AEN
Address bus used for I/O space and register decoding.
Qualifies valid I/O decoding - enabled access when low.
nIORD
nRD
I/O Read strobe - asynchronous read accesses. Address is valid
before leading edge.
nIOWR
nWR
I/O Write strobe - asynchronous write access. Address is valid
before leading edge. Data is latched on trailing edge.
IOCHRDY
ARDY
This signal is negated on leading nRD, nWR if necessary. It is
then asserted on CLK rising edge after the access condition is
satisfied.
RESET
A0
RESET
nBE0
nSBHE
IRQn
nBE1
INTR0-INTR3
D0-D15
D0-D15
16 bit data bus. The bus byte(s) used to access the device are a
function of nBE0 and nBE1:
nBE0
nBE1
D0-D7
Lower
D8-D15
Upper
0
0
1
0
1
0
Lower
Not used
Upper
Not used
Not used = tri-state on reads, ignored on writes
nIOCS16
nLDEV buffered
LCLK nADS
nLDEV is a totem pole output. Must be buffered using an open
collector driver. nLDEV is active on valid decodes of A15-A4 and
AEN=0.
UNUSED PINS
GND
VCC
nBE2 nBE3
nCYCLE W/nR
nRDYRTN
No upper word access.
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FEAST Fast Ethernet Controller with Full Duplex Capability
ISA BUS
A1-A15, AEN
RESET
A1-A15, AEN
RESET
nBE2, nBE3
D0-D15
INTR0-INTR3
nRD
VCC
D0-D15
nIRQ
LAN91C100FD
nIORD
nIOWR
A0
nWR
nBE0
nBE1
nSBHE
nLDEV
O.C.
nIOCS16
Figure 7.2 - LAN91C100FD on ISA Bus
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
7.4
EISA 32 Bit SLAVEEISA 32 Bit Slave
On EISA the LAN91C100FD is accessed as a 32 bit I/O slave, along with a Slave DMA type "C" data path
option. As an I/O slave, the LAN91C100FD uses asynchronous accesses. In creating nRD and nWR
inputs, the timing information is externally derived from nCMD edges. Given that the access will be at least
1.5 to 2 clocks (more than 180ns at least) there is no need to negate EXRDY, simplifying the EISA
interface implementation. As a DMA Slave, the LAN91C100FD accepts burst transfers and is able to
sustain the peak rate of one doubleword every BCLK. Doubleword alignment is assumed for DMA
transfers. Up to three extra bytes in the beginning and at the end of the transfer should be moved by the
CPU using I/O accesses to the Data Register. The LAN91C100FD will sample EXRDY and postpone DMA
cycles if the memory cycle solicits wait states.
Table 7.3 - EISA 32 Bit Slave Signal Connections
EISA BUS
SIGNAL
LAN91C100FD
SIGNAL
NOTES
LA2-LA15
A2-A15
Address bus used for I/O space and register decoding,
latched by nADS (nSTART) trailing edge.
M/nIO
AEN
AEN
Qualifies valid I/O decoding - enabled access when low.
These signals are externally ORed. Internally the AEN pin is
latched by nADS rising edge and transparent while nADS is
low.
Latched W-R
combined with
nCMD
nRD
I/O Read strobe - asynchronous read accesses. Address is
valid before its leading edge. Must not be active during DMA
bursts if DMA is supported.
Latched W-R
combined with
nCMD
nWR
I/O Write strobe - asynchronous write access. Address is
valid before leading edge . Data latched on trailing edge.
Must not be active during DMA bursts if DMA is supported.
nSTART
nADS
Address strobe is connected to EISA nSTART.
RESDRV
RESET
nBE0 nBE1
nBE2 nBE3
nBE0 n BE1
nBE2 nBE3
Byte enables. Latched on nADS rising edge.
Interrupts used as active high edge triggered
IRQn
INTR0-INTR3
D0-D31
D0-D31
32 bit data bus. The bus byte(s) used to access the device
are a function of nBE0-nBE3:
nBE0
nBE1 nBE2
nBE3
0
0
1
0
1
1
1
0
0
1
1
0
1
1
0
1
0
1
1
0
1
0
1
0
1
1
1
0
Double word access
Low word access
High word access
Byte 0 access
Byte 1 access
Byte 2 access
Byte 3 access
Not used = tri-state on reads, ignored on writes. Note that
nBE2 and nBE3 override the value of A1, which is tied low in
this application. Other combinations of nBE are not
supported by the LAN91C100FD. Software drivers are not
anticipated to generate them.
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FEAST Fast Ethernet Controller with Full Duplex Capability
EISA BUS
SIGNAL
LAN91C100FD
SIGNAL
NOTES
nEX32
nLDEV
nLDEV is a totem pole output. nLDEV is active on valid
decodes of LAN91C100FD pins A15-A4, and AEN=0.
nNOWS is similar to nLDEV except that it should go inactive
on nSTART rising. nNOWS can be used to request
compressed cycles (1.5 BCLK long, nRD/nWR will be 1/2
BCLK wide).
nNOWS
(optional
additional logic)
THE FOLLOWING SIGNALS SUPPORT SLAVE DMA TYPE "C" BURST CYCLES
BCLK
LCLK
EISA Bus Clock. Data transfer clock for DMA bursts.
nDAK<n>
nDATACS
DMA Acknowledge. Active during Slave DMA cycles. Used
by the LAN91C100FD as nDATACS direct access to data
path.
nIORC
W/nR
Indicates the direction and timing of the DMA cycles. High
during LAN91C100FD writes, low during LAN91C100FD
reads.
nIOWC
nCYCLE
Indicates slave DMA writes.
nEXRDY
nRDYRTN
EISA bus signal indicating whether a slave DMA cycle will
take place on the next BCLK rising edge, or should be
postponed. nRDYRTN is used as an input in the slave DMA
mode to bring in EXRDY.
UNUSED PINS
VCC
GND
nVLBUS
A1
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FEAST Fast Ethernet Controller with Full Duplex Capability
EISA BUS
LA2-LA15
A2-A15
RESET
AEN
RESDRV
AEN
M/nIO
D0-D31
INTR0-INTR3
D0-D31
IRQn
LAN91C100FD
nBE0-nBE3
nBE0-nBE3
nRD
nCMD
nWR
LATCH +
gates
nWR
LCLK
nADS
BCLK
nSTART
nLDEV
nEX32
O.C.
Figure 7.3 - LAN91C100FD on EISA Bus
Revision 1.0 (09-22-08)
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DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 8 Operational Description
8.1
Maximum Guaranteed Ratings*
Operating Temperature Range ............................................................................................... 0 EC to +70EC
Storage Temperature Range ............................................................................................-55EC°to + 150EC
Lead Temperature Range (soldering, 10 seconds) ........................................................................... +325EC
Positive Voltage on any pin, with respect to Ground .....................................................................VCC + 0.3V
Negative Voltage on any pin, with respect to Ground ........................................................................... -0.3V
Maximum VCC .......................................................................................................................................... +7V
* Stresses above those listed above could cause permanent damage to the device. This is a stress rating only and
functional operation of the device at any other condition above those indicated in the operation sections of this
specification is not implied.
Note:
When powering this device from laboratory or system power supplies, it is important that the Absolute
Maximum Ratings not be exceeded or device failure can result. Some power supplies exhibit voltage
spikes on their outputs when the AC power is switched on or off. In addition, voltage transients on the AC
power line may appear on the DC output. If this possibility exists, it is suggested that a clamp circuit be
used.
8.2
DC Electrical Characteristics
(TA = 0EC - 70EC, VCC = +5.0 V ± 10%)
PARAMETER
SYMBOL
MIN
TYP
MAX UNITS
COMMENTS
I Type Input Buffer
Low Input Level
VILI
VIHI
0.8
V
V
TTL Levels
High Input Level
2.0
IS Type Input Buffer
Low Input Level
High Input Level
VILIS
VIHIS
VHYS
0.8
V
V
Schmitt Trigger
Schmitt Trigger
2.2
3.0
Schmitt Trigger Hysteresis
250
mV
ICLK Input Buffer
VILCK
VIHCK
0.4
V
V
Low Input Level
High Input Level
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
PARAMETER
Input Leakage
SYMBOL
MIN
TYP
MAX UNITS
COMMENTS
(All I and IS buffers except
pins with pullups/pulldowns)
Low Input Leakage
IIL
-10
-10
+10
+10
µA
µA
VIN = 0
VIN = VCC
High Input Leakage
IIH
IP Type Buffers
Input Current
IIL
-150
-75
mA
mA
VIN = 0
ID Type Buffers
Input Current
IIH
+75
+150
0.4
VIN = VCC
O4 Type Buffer
Low Output Level
High Output Level
VOL
VOH
IOL
V
V
IOL = 4 mA
IOH = -2 mA
VIN = 0 to VCC
2.4
-10
Output Leakage
+10
0.4
µA
I/O4 Type Buffer
VOL
VOH
IOL = 4 mA
Low Output Level
High Output Level
V
V
IOH = -2 mA
2.4
-10
IOL
VIN = 0 to VCC
Output Leakage
+10
0.5
µA
O12 Type Buffer
Low Output Level
High Output Level
VOL
VOH
IOL
V
V
IOL = 12 mA
IOH = -6 mA
VIN = 0 to VCC
2.4
-10
Output Leakage
+10
0.5
µA
O16 Type Buffer
Low Output Level
High Output Level
VOL
VOH
IOL
V
V
IOL = 16 mA
IOH = -8 mA
2.4
-10
VIN = 0 to VCC
Output Leakage
+10
µA
OD16 Type Buffer
Low Output Level
Output Leakage
VOL
IOL
0.5
V
IOL = 16 mA
VIN = 0 to VCC
-10
+10
µA
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FEAST Fast Ethernet Controller with Full Duplex Capability
PARAMETER
O24 Type Buffer
SYMBOL
MIN
TYP
MAX UNITS
COMMENTS
Low Output Level
High Output Level
VOL
0.5
V
V
IOL = 24 mA
IOH = -12 mA
VIN = 0 to VCC
2.4
-10
VOH
IOL
Output Leakage
+10
0.5
µA
I/O24 Type Buffer
Low Output Level
High Output Level
VOL
VOH
V
V
IOL = 24 mA
IOH = -12 mA
2.4
-10
IOL
ICC
VIN = 0 to VCC
Output Leakage
+10
40
µA
Supply Current Active
25
mA
All Outputs Open
CAPACITANCE TA = 25EC; fc = 1MHz; VCC = 5V
LIMITS
TYP
PARAMETER
SYMBOL
MIN
MAX
UNIT
TEST CONDITION
All pins except pin
under test tied to
AC ground
Clock Input Capacitance
CIN
20
pF
Input Capacitance
Output Capacitance
CIN
10
20
pF
pF
COUT
CAPACITIVE LOAD ON OUTPUTS
nARDY, D0-D31 (non VLBUS)
D0-D31 in VLBUS
240 pF
45 pF
45 pF
All other outputs
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 9 Timing Diagrams
t2
A1-15, AEN, nBE0-nBE3 valid
ADDRESS
nADS
t3
t4
READ DATA
nRD,nWR
t1
t5
t5A
WRITE DATA
D0-D31 valid
Figure 9.1 - Asynchronous Cycle - nADS=0
PARAMETER
MIN
TYP
MAX
UNITS
t1
t2
A1-A15, AEN, nBE0-nBE3 Valid and nADS Low Setup to
nRD, nWR Active
25
ns
A1-A15, AEN, nBE0-nBE3 Hold After nRD, nWR Inactive
(Assuming nADS Tied Low)
20
ns
t3
t4
nRD Low to Valid Data
40
30
ns
ns
ns
ns
nRD High to Data Floating
Data Setup to nWR Inactive
Data Hold After nWR Inactive
t5
30
5
t5A
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FEAST Fast Ethernet Controller with Full Duplex Capability
ADDRESS
nADS
A1-A15, AEN, nBE0-nBE3
valid
t8
t9
t3
t4
READ DATA
nRD, nWR
t1
t5
t5A
WRITE DATA
valid
D0-D31
Figure 9.2 - Asynchronous Cycle - Using nADS
PARAMETER
MIN TYP MAX UNITS
t1
A1-A15, AEN, nBE0-nBE3 Valid and nADS Low Setup to nRD,
nWR Active
25
ns
t3
t4
nRD Low to Valid Data
40
30
ns
ns
ns
ns
ns
ns
nRD High to Data Floating
t5
Data Setup to nWR Inactive
30
5
t5A
t8
Data Hold After nWR Inactive
A1-A15, AEN, nBE0-nBE3 Setup to nADS Rising
A1-A15, AEN, nBE0-nBE3 Hold after nADS Rising
10
15
t9
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
t2
nDATACS
nADS
t3
t4
READ DATA
nRD, nWR
t1
t5
t5A
WRITE DATA
D0-D31 valid
Figure 9.3 - Asynchronous Cycle - nADS=0
(nDATACS Used to Select Data Register; Must Be 32 Bit Access)
PARAMETER
MIN
TYP
MAX
UNITS
t1
t2
A1-A15, AEN, nBE0-nBE3 Valid and nADS Low Setup to
nRD, nWR Active
25
ns
A1-A15, AEN, nBE0-nBE3 Hold After nRD, nWR Inactive
(Assuming nADS Tied Low)
20
ns
t3
t4
nRD Low to Valid Data
40
30
ns
ns
ns
ns
nRD High to Data Floating
Data Setup to nWR Inactive
Data Hold After nWR Inactive
t5
30
5
t5A
Revision 1.0 (09-22-08)
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FEAST Fast Ethernet Controller with Full Duplex Capability
LCLK
t13
t17
t12
nDATACS
W/nR
t17
nCYCLE
t20
t18
b
a
c
WRITE DATA
nRDYRTN
t15
t14
Figure 9.4 - Burst Write Cycles - nVLBUS=1
PARAMETER
t12 nDATACS Setup to Either nCYCLE or W/nR Falling
t13 nDATACS Hold after Either nCYCLE or W/nR Rising
t14 nRDYRTN Setup to LCLK Falling
MIN
60
30
15
2
TYP
MAX
UNITS
ns
ns
ns
t15 nRDYRTN Hold after LCLK Falling
ns
t17 nCYCLE High and W/nR High Overlap
t18 Data Setup to LCLK Rising (Write)
50
13
5
ns
ns
t20 Data Hold from LCLK Rising (Write)
ns
SMSC LAN91C100FD Rev. D
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FEAST Fast Ethernet Controller with Full Duplex Capability
LCLK
nDATACS
W/nR
t12
t13
t17
t19
READ DATA
a
b
c
t15
t14
nRDYRTN
nCYCLE
t17
Figure 9.5 - Burst Read Cycles - nVLBUS=1
PARAMETER
MIN
60
30
15
2
TYP
MAX
UNITS
ns
t12 nDATACS Setup to Either nCYCLE or W/nR Falling
t13 nDATACS Hold after Either nCYCLE or W/nR Rising
t14 nRDYRTN Setup to LCLK Falling
ns
ns
t15 nRDYRTN Hold after LCLK Falling
ns
t17 nCYCLE High and W/nR High Overlap
t19 Data Delay from LCLK Rising (Read)
50
ns
5
38
ns
(Note
9.1)
(Note
9.2)
Note 9.1
Note 9.2
(holdt.)
(Setupt.)
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FEAST Fast Ethernet Controller with Full Duplex Capability
nADS
t9
t8
ADDRESS
nLDEV
A1-A15, AEN, nBE0-nBE3
t25
Figure 9.6 - Address Latching for all Modes
PARAMETER
MIN
10
TYP
MAX
UNITS
ns
t8
t9
A1-A15, AEN, nBE0-nBE3 Setup to nADS Rising
A1-A15, AEN, nBE0-nBE3 Hold After nADS Rising
15
ns
t25 A4-A15, AEN to nLDEV Delay
20
ns
t18
t20
LCLK
W/nR
t17A
t9
ADDRESS
nADS
A1-A15, AEN, nBE0-nBE3
t8
t11
t16
t10
nCYCLE
D0-D31 valid
t21
WRITE DATA
t21
nSRDY
nDATACS
Figure 9.7 - Synchronous Write Cycles - nVLBUS=0
PARAMETER
MIN
10
15
7
TYP
MAX
UNITS
ns
t8
t9
A1-A15, AEN, nBE0-nBE3 Setup to nADS Rising
A1-A15, AEN, nBE0-nBE3 Hold After nADS Rising
ns
t10 nCYCLE Setup to LCLK Rising
ns
t11 nCYCLE Hold after LCLK Rising (Non-Burst Mode)
t16 W/nR Setup to nCYCLE Active
3
ns
30
5
ns
t17A W/nR Hold after LCLK Rising with nLRDY Active
t18 Data Setup to LCLK Rising (Write)
t20 Data Hold from LCLK Rising (Write)
t21 nLRDY Delay from LCLK Rising
ns
13
5
ns
ns
10
ns
SMSC LAN91C100FD Rev. D
Page 71
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DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
t23
t24
LCLK
W/nR
t9
ADDRES
nADS
A1-A15, AEN, nBE0-nBE3
t8
t10
t16
t11
nCYCL
READ
D0-D31
t21
t21
nSRD
RDYRT
nDATAC
Figure 9.8 - Synchronous Read Cycle - NVLBUS=0
PARAMETER
MIN
10
15
7
TYP
MAX
UNITS
t8
A1-A15, AEN, nBE0-nBE3 Setup to nADS Rising
A1-A15, AEN, nBE0-nBE3 Hold After nADS Rising
nCYCLE Setup to LCLK Rising
ns
ns
ns
ns
ns
ns
ns
ns
ns
t9
t10
t11
t16
t20
t21
t23
t24
nCYCLE Hold after LCLK Rising (Non-Burst Mode)
W/nR Setup to nCYCLE Active
3
30
5
Data Hold from LCLK Rising (Read)
nLRDY Delay from LCLK Rising
10
nRDYRTN Setup to LCLK Rising
7
3
nRDYRTN Hold after LCLK Rising
Revision 1.0 (09-22-08)
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SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
t50
t54
t50
t34
t35
t38
t51
RA2-RA16
t39
t36
t37
nRWE0-nRWE3
t52
t53
nROE
RD0-RD31
WRITE CYCLE
READ CYCLE
t50
t39
t50
t54
t38
t51
t34
t35
RA2-RA16
t36
t37
nRWE0-nRWE3
t52
t53
nROE
RD0-RD31
READ CYCLE
WRITE CYCLE
t50
t51
t38
t51
t38
t51
t38
t38
RA2-RA16
nRWE0-nRWE3
t52
nROE
RD0-RD31
MULTIPLE READ CYCLES
Figure 9.9 - SRAM Interface
PARAMETER
MIN
0
TYP
MAX
UNITS
ns
t34
t35
t36
t37
t39
t54
t38
t51
Write – RA2-RA16 Setup to nRWE0-nRWE3 Falling
Write – RA2-RA16 Hold after nRWE0-nRWE3 Rising
Write – RD0-RD31 Setup to nRWE0-nRWE3 Rising
Write – RD0-RD31 Hold after nRWE0-nRWE3 Rising
Write – nRWE0-nRWE3 Pulse Width
0
ns
12
0
ns
ns
15
12
ns
Write – RA2-RA16 Valid to End of Write
ns
Read – RA2-RA16 Valid to RD0-RD31 Valid
Read – RD0-RD31 Hold after RA2-RA16 Change
15
ns
3
ns
SMSC LAN91C100FD Rev. D
Page 73
Revision 1.0 (09-22-08)
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
PARAMETER
Read – nROE enable to RD0-RD31 Valid
Read – nROE disable to RD0-RD31 Invalid
Read/Write – Cycle Time
MIN
TYP
MAX
12
UNITS
ns
t52
t53
t50
0
8
ns
25
ns
TXC
t30
t30
TXEN
TXD
t30
t31
t32
RXD
RXC
CRS
Figure 9.10 - ENDEC Interface - 10 Mbps
PARAMETER
MIN
0
TYP
MAX
UNITS
ns
t30 TXD, TXEN Delay from TXC Rising
t31 RXD Setup to RXC Rising
40
10
30
ns
t32 RXD Hold After RXC Rising
ns
Notes:
1. CRS input might be asynchronous to RXC.
2. RXC starts after CRS goes active. RXC stops after CRS goes inactive.
3. COL is an asynchronous input.
Revision 1.0 (09-22-08)
Page 74
SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
t27
TXD0-TXD3
t27
TXEN100
t28
t28
RXD0-RXD3
t28
RX25
RX_DV
RX_ER
t29
t29
Figure 9.11 - MII Interface
PARAMETER
MIN
0
TYP
MAX
15
UNITS
ns
t27 TXD0-TXD3, TXEN100 Delay from TX25 Rising
t28 RXD0-RXD3, RX_DV, RX_ER Setup to RX25 Rising
t29 RXD0-RXD3, RX_DV, RX_ER Hold After RX25 Rising
10
10
ns
ns
SMSC LAN91C100FD Rev. D
Page 75
Revision 1.0 (09-22-08)
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Chapter 10 Package Outlines
Figure 10.1 - 208 Pin QFP Package Outline
Table 10.1 - 208 Pin QFP Package Parameters
MIN
~
NOMINAL
MAX
4.07
0.5
REMARK
Overall Package Height
Standoff
A
A1
A2
D
D1
E
E1
H
L
~
~
~
~
~
~
~
~
0.05
3.17
30.35
27.90
30.35
27.90
0.09
0.45
~
3.67
30.85
28.10
30.85
28.10
0.20
0.75
~
Body Thickness
X Span
X Body Size
Y Span
Y body Size
Lead Frame Thickness
Lead Foot Length
Lead Length
0.60
1.30
0.50 Basic
L1
e
Lead Pitch
Lead Foot Angle
Lead Width
0o
0.10
0.08
0.08
~
~
~
~
~
~
7o
0.30
~
0.25
0.08
θ
W
R1
R2
ccc
Lead Shoulder Radius
Lead Foot Radius
Coplanarity
Notes:
1. Controlling Unit: millimeter.
2. Tolerance on the true position of the leads is ± 0.04 mm maximum.
3. Package body dimensions D1 and E1 do not include the mold protrusion.
Maximum mold protrusion is 0.25 mm.
4. Dimension for foot length L measured at the gauge plane 0.25 mm above the seating plane.
5. Details of pin 1 identifier are optional but must be located within the zone indicated.
Revision 1.0 (09-22-08)
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SMSC LAN91C100FD Rev. D
DATASHEET
FEAST Fast Ethernet Controller with Full Duplex Capability
Figure 10.2 - 208 Pin TQFP Package Outlines
Table 10.2 - 208 Pin TQFP Package Outlines
MIN
~
NOMINAL
MAX
1.60
0.15
1.45
30.20
28.10
30.20
28.10
0.23
0.75
~
REMARK
Overall Package Height
Standoff
A
A1
A2
D
D1
E
E1
H
L
~
~
~
~
~
~
~
~
0.05
1.35
29.80
27.90
29.80
27.90
0.09
0.45
~
Body Thickness
X Span
X Body Size
Y Span
Y body Size
Lead Frame Thickness
Lead Foot Length
Lead Length
0.60
1.00
0.50 Basic
L1
e
Lead Pitch
Lead Foot Angle
Lead Width
0o
0.17
0.08
0.08
~
~
0.22
~
~
~
7o
0.27
~
0.20
0.08
θ
W
R1
R2
ccc
Lead Shoulder Radius
Lead Foot Radius
Coplanarity
Notes:
1. Controlling Unit: millimeter.
2. Tolerance on the true position of the leads is ± 0.04 mm maximum.
3. Package body dimensions D1 and E1 do not include the mold protrusion.
Maximum mold protrusion is 0.25 mm.
4. Dimension for foot length L measured at the gauge plane 0.25 mm above the seating plane.
5. Details of pin 1 identifier are optional but must be located within the zone indicated.
SMSC LAN91C100FD Rev. D
Page 77
Revision 1.0 (09-22-08)
DATASHEET
相关型号:
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