Intel LXT970AQC Dual-speed fast ethernet transceiver Datasheet

LXT970A
Dual-Speed Fast Ethernet Transceiver
Datasheet
The LXT970A is an enhanced derivative of the LXT970 10/100 Mbps Fast Ethernet PHY
Transceiver that supports selectable driver strength capabilities and link-loss criteria. The
LXT970A supports 100BASE-TX, 10BASE-T, and 100BASE-FX applications. It provides a
Media Independent Interface (MII) for easy attachment to 10/100 Media Access Controllers
(MAC)s and a pseudo-ECL interface for use with 100BASE-FX fiber networks.
The LXT970A supports full-duplex operation at 10 and 100 Mbps. Its operating condition is set
using auto-negotiation, parallel detection or manual control. The encoder may be bypassed for
symbol mode applications.
The LXT970A is fabricated with an advanced CMOS process and requires only a single 5V
power supply. The MII may be operated independently with either a 5V or a 3.3V supply.
Applications
■
■
Combination 10BASE-T/100BASE-TX
Network Interface Cards (NICs)
10/100 Switches, 10/100 Printservers
■
100BASE-FX Network Interface Cards
(NICs)
■
Configurable for DTE or switch
applications.
CMOS process with single 5Vsupply
operation
with provision for interface to 3.3V MII
bus.
Integrated LED drivers.
Integrated supply monitor and line
disconnect during low supply fault.
Available in:
— 64-pin TQFP (LXT970ATC)
— 64-pin PQFP (LXT970AQC)
Commercial temperature range (0 - 70oC
ambient).
Product Features
■
■
■
■
■
IEEE 802.3 Compliant:
— 10BASE-T and 100BASE-TX using a
single RJ-45 connection.
— Supports auto-negotiation and parallel
detection for legacy systems.
— MII interface with extended register
capability.
Robust baseline wander correction
performance.
100BASE-FX fiber optic capable.
Standard CSMA/CD or full-duplex
operation.
Configurable via MII serial port or external
control pins.
■
■
■
■
■
As of January 15, 2001, this document replaces the Level One document
LXT970A — Dual-Speed Fast Ethernet Transceiver.
Order Number: 249099-001
January 2001
Information in this document is provided in connection with Intel® products. No license, express or implied, by estoppel or otherwise, to any intellectual
property rights is granted by this document. Except as provided in Intel’s Terms and Conditions of Sale for such products, Intel assumes no liability
whatsoever, and Intel disclaims any express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to
fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. Intel products are not
intended for use in medical, life saving, or life sustaining applications.
Intel may make changes to specifications and product descriptions at any time, without notice.
Designers must not rely on the absence or characteristics of any features or instructions marked "reserved" or "undefined." Intel reserves these for
future definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them.
The LXT970A may contain design defects or errors known as errata which may cause the product to deviate from published specifications. Current
characterized errata are available on request.
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by calling 1-800548-4725 or by visiting Intel’s website at http://www.intel.com.
Copyright © Intel Corporation, 2001
*Third-party brands and names are the property of their respective owners.
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Contents
1.0
Pin Assignments and Signal Descriptions ....................................................10
2.0
Functional Description...........................................................................................18
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
Datasheet
Introduction..........................................................................................................18
Interfaces (Network Media/Protocol Support) .....................................................19
2.2.1 Twisted-Pair Interface ............................................................................19
2.2.2 Fiber Interface ........................................................................................19
2.2.3 MII Interface ...........................................................................................20
2.2.3.1 Selectable Driver Levels............................................................20
2.2.3.2 MII Data Interface......................................................................21
2.2.3.3 Repeater Mode..........................................................................24
2.2.3.4 MII Management Interface ........................................................24
2.2.4 Hardware Control Interface ....................................................................26
Operating Requirements .....................................................................................27
2.3.1 Power Supply Requirements..................................................................27
2.3.1.1 Optional MII Power Supply ........................................................27
2.3.2 Reference Clock Requirements .............................................................27
2.3.2.1 Master Clock Mode ...................................................................28
2.3.2.2 Slave Clock Mode .....................................................................28
2.3.3 Bias Circuit Requirements......................................................................29
Initialization..........................................................................................................29
2.4.1 Control Mode Selection ..........................................................................29
2.4.1.1 MDIO Control Mode ..................................................................29
2.4.1.2 Manual Control Mode ................................................................29
2.4.2 Link Configuration ..................................................................................29
2.4.2.1 Manual Configuration ................................................................30
2.4.2.2 Auto-Negotiation/Parallel Detection ..........................................30
Monitoring Operational Status.............................................................................31
2.5.1 Monitoring Status via MII Registers........................................................31
2.5.2 Monitoring Status via Indicator Pins .......................................................32
100BASE-X Operation ........................................................................................32
2.6.1 100BASE-X MII Operations....................................................................32
2.6.2 100BASE-X Network Operations ...........................................................33
10BASE-T Operation...........................................................................................35
2.7.1 10BASE-T MII Operations......................................................................35
2.7.2 10BASE-T Network Operations..............................................................35
Protocol Sublayer Operations .............................................................................35
2.8.1 PCS Sublayer .........................................................................................35
2.8.1.1 100X Preamble Handling ..........................................................36
2.8.1.2 10T Preamble Handling.............................................................36
2.8.1.3 Data Errors (100X Only) ............................................................36
2.8.1.4 Collision Indication ....................................................................37
2.8.1.5 SQE (10T Only) .........................................................................38
2.8.1.6 Jabber (10T Only) .....................................................................38
2.8.2 PMA Layer..............................................................................................38
2.8.2.1 100TX Link Options ...................................................................38
2.8.2.2 10T Link Test.............................................................................38
3
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.8.3
2.8.4
2.8.5
2.8.6
2.8.7
2.8.8
2.8.9
3.0
2.8.2.3 Carrier Sense (CRS) ................................................................. 38
Twisted-Pair PMD Layer ........................................................................ 39
2.8.3.1 Scrambler/Descrambler (100TX Only) ...................................... 39
2.8.3.2 Baseline Wander Correction
(100TX Only)39
2.8.3.3 Polarity Correction..................................................................... 39
Fiber PMD Layer .................................................................................... 39
Additional Operating Features ............................................................... 40
Low-Voltage-Fault Detect....................................................................... 40
Power Down Mode................................................................................. 40
Software Reset....................................................................................... 40
Hardware Reset ..................................................................................... 40
Application Information ......................................................................................... 41
3.1
3.2
3.3
Magnetics Information......................................................................................... 41
Crystal Information .............................................................................................. 41
Design Recommendations .................................................................................. 42
3.3.1 General Design Guidelines .................................................................... 42
3.3.2 Power Supply Filtering ........................................................................... 42
3.3.3 Ground Noise ......................................................................................... 43
3.3.4 Power and Ground Plane Layout Considerations .................................. 43
3.3.5 Interfaces for Twisted-Pair /Fiber ........................................................... 43
3.3.5.1 Twisted-Pair .............................................................................. 43
3.3.5.2 Fiber .......................................................................................... 44
3.3.6 Interface for the MII ................................................................................ 44
3.3.6.1 Transmit Hold Time Adjustment ................................................ 44
3.3.6.2 MII Terminations........................................................................ 44
3.3.7 Typical Application ................................................................................. 45
3.3.7.1 Voltage Divider For MF Inputs................................................... 45
4.0
Test Specifications .................................................................................................. 47
5.0
Register Definitions ................................................................................................ 63
6.0
Mechanical Specifications ................................................................................... 73
4
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Figures
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
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22
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24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
Datasheet
LXT970A Block Diagram ....................................................................................... 9
LXT970A Pin Assignments .................................................................................10
Network Interface Card (NIC) Application ..........................................................18
MII Interface .......................................................................................................20
MII Data Interface ...............................................................................................21
Loopback Paths ..................................................................................................23
Repeater Block Diagram ....................................................................................24
MDIO Interrupt Signaling ....................................................................................25
Management Interface - Read Frame Structure .................................................25
Management Interface - Write Frame Structure .................................................25
LXT970A Initialization Sequence .......................................................................30
Auto-Negotiation Operation ................................................................................31
100BASE-TX Frame Structure ...........................................................................33
100BASE-TX Data Flow .....................................................................................33
LXT970A Protocol Sublayers .............................................................................36
100BASE-TX Reception with No Errors .............................................................37
100BASE-TX Reception with Invalid Symbol ....................................................37
100BASE-TX Transmission with No Errors .......................................................37
100BASE-TX Transmission with Collision .........................................................37
Voltage Divider ...................................................................................................45
Typical Interface Circuitry ...................................................................................46
MII - 100BASE-TX Receive Timing / 4B Mode ...................................................51
MII - 100BASE-TX Transmit Timing / 4B Mode .................................................52
MII - 100BASE-TX Receive Timing / 5B Mode ...................................................53
100BASE-TX Transmit Timing / 5B Mode ..........................................................54
MII - 100BASE-FX Receive Timing / 4B Mode ...................................................55
MII - 100BASE-FX Transmit Timing / 4B Mode ..................................................56
MII - 10BASE-T Receiving Timing ......................................................................57
MII - 10BASE-T Transmit Timing .......................................................................58
10BASE-T SQE (Heartbeat) Timing ...................................................................59
10BASE-T Jab and Unjab Timing ......................................................................59
Auto Negotiation and Fast Link Pulse Timing ....................................................60
Fast Link Pulse Timing .......................................................................................60
MDIO Timing when Sourced by STA .................................................................61
MDIO Timing when Sourced by PHY .................................................................61
Power-Down Recovery Timing (Over Recommended Range) ...........................62
PHY Identifier Bit Mapping .................................................................................66
64-Pin QFP Package Diagram ...........................................................................73
64-Pin TQFP Package Diagram .........................................................................74
5
LXT970A — Dual-Speed Fast Ethernet Transceiver
Tables
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
6
LXT970A Power Supply Signal Descriptions ...................................................... 10
LXT970A MII Signal Descriptions ....................................................................... 11
LXT970A Fiber Interface Signal Descriptions ..................................................... 12
LXT970A Twisted-Pair Interface Signal Descriptions ......................................... 13
LXT970A LED Indicator Signal Descriptions....................................................... 13
LXT970A Miscellaneous Signal Descriptions...................................................... 13
LXT970A Hardware Control Interface Signal Descriptions ................................. 14
MF Pin Function Settings1, 3 .............................................................................. 16
LXT970A Auto-Negotiation Operating Speed/Full-Duplex
Advertisement Settings ....................................................................................... 17
Test Loopback Operation.................................................................................... 23
Carrier Sense, Loopback, and Collision Conditions............................................ 23
Configuring the LXT970A via Hardware Control ................................................. 26
LXT970A Operating Configurations / Auto-Negotiation Enabled ........................ 26
LXT970A Operating Configurations / Auto-Negotiation Disabled ....................... 27
Mode Control Settings......................................................................................... 29
LXT970A Status using FDS/LED Pins ................................................................ 32
4B/5B Coding ...................................................................................................... 34
Magnetics Requirements .................................................................................... 41
Crystal Requirements.......................................................................................... 41
Crystal Component Manufacturers ..................................................................... 41
Absolute Maximum Ratings ................................................................................ 47
Operating Conditions .......................................................................................... 47
Digital I/O Characteristics1.................................................................................. 48
Digital I/O Characteristics - MultiFunction Pins MF<4:0>.................................... 48
Required Clock Characteristics........................................................................... 48
Low Voltage Fault Detect Characteristics ........................................................... 49
100BASE-TX Transceiver Characteristics .......................................................... 49
100BASE-FX Transceiver Characteristics .......................................................... 49
10BASE-T Transceiver Characteristics............................................................... 50
10BASE-T Link Integrity Timing Characteristics ................................................. 50
MII - 100BASE-TX Receive Timing Parameters / 4B Mode................................ 51
MII - 100BASE-TX Transmit Timing Parameters / 4B Mode............................... 52
MII - 100BASE-TX Receive Timing Parameters / 5B Mode................................ 53
MII - 100BASE-TX Transmit Timing Parameters / 5B Mode............................... 54
MII - 100BASE-FX Receive Timing Parameters / 4B Mode................................ 55
MII - 100BASE-FX Transmit Timing Parameters / 4B Mode............................... 56
MII - 10BASE-T Receive Timing Parameters...................................................... 57
MII - 10BASE-T Transmit Timing Parameters..................................................... 58
10BASE-T SQE (Heartbeat) Timing Parameters ................................................ 59
10BASE-T Jab and Unjab Timing Parameters.................................................... 59
Auto Negotiation and Fast Link Pulse Timing Parameters.................................. 60
MDIO Timing Parameters ................................................................................... 61
Power-Down Recovery Timing Parameters ........................................................ 62
Register Set ........................................................................................................ 63
Control Register (Address 0)............................................................................... 64
Status Register (Address 1) ................................................................................ 65
PHY Identification Register 1 (Address 2)........................................................... 66
PHY Identification Register 2 (Address 3)........................................................... 66
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
49
50
51
52
53
54
55
56
Datasheet
Auto Negotiation Advertisement Register (Address 4)........................................67
Auto Negotiation Link Partner Ability Register (Address 5).................................68
Auto Negotiation Expansion (Address 6) ............................................................69
Mirror Register (Address 16, Hex 10)..................................................................69
Interrupt Enable Register (Address 17, Hex 11) .................................................70
Interrupt Status Register (Address 18, Hex 12) ..................................................70
Configuration Register (Address 19, Hex 13)......................................................71
Chip Status Register (Address 20, Hex 14) ........................................................72
7
LXT970A — Dual-Speed Fast Ethernet Transceiver
Revision History
Revision
8
Date
Description
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Figure 1. LXT970A Block Diagram
+
TX_EN
MII
TX
Hardware
Interface
MII
MGMT
TX_ER
Parallel
to Serial
Converter
TXD<0:4>
TX_CLK
MF<0:4>
CFG<0:1>
FDE
TRSTE
RESET
FDS/MDINT
MDIO
MDDIS
MDC
XTALI/O
RX_CLK
CRS
COL
RX_DV
RX_ER
PWR_DWN
Datasheet
TPOP
TPON
-
100Mbps
Loopback
LED
Drivers
2
Clock
Generator
Crystal Osc
& PLL
Carrier Sense
Collision Detect
Data Valid
Error Detect
LED_
+
ECL
Rcvr
Serial to
Parallel
Converter
RXD<0:4>
MII
RX
+
TP
Driver
Auto
Negotiation
Management/
Mode Select
Logic
FIBON
-
Pulse
Shaper
Scrambler 100
& Encoder
10Mbps
Loopback
FIBOP
ECL
Driver
Manchester
10
Encoder
10
Manchester
Decoder
100
Decoder &
Descrambler
Slicer
Baseline
Wander
Correction
+
TP
Rcvr
PwrDown/
Line Energy
Monitor
-
FIBIP
FIBIN
TPIP
TPIN
9
LXT970A — Dual-Speed Fast Ethernet Transceiver
1.0
Pin Assignments and Signal Descriptions
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
COL
TXD4
TXD3
TXD2
TXD1
TXD0
TX_EN
TX_CLK
TX_ER
RX_ER
RX_CLK
VCCIO
GNDIO
RX_DV
RXD0
RXD1
Figure 2. LXT970A Pin Assignments
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Part #
LOT #
FPO #
LXT970AQC/ATC XX
XXXXXX
XXXXXXXX
Rev #
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
RXD2
RXD3
RXD4
MDC
MDIO
GNDD
LEDR
LEDT
LEDL
LEDC
LEDS
VCCR
N/C
N/C
PWRDWN
CFG1
FIBOP
FIBON
VCCT
TREF
TPOP
GNDT
TPON
VCCA
RBIAS
GNDA
FIBIP
FIBIN
TPIP
TPIN
GNDR
N/C
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
CRS
FDS/MDINT
TRSTE
MF4
MF3
MF2
MF1
MF0
VCCD
TEST
XO
XI
FDE
CFG0
MDDIS
RESET
Table 1.
LXT970A Power Supply Signal Descriptions
Pin#1
Pin Name
I/O
19, 22
VCCT, GNDT
-
Transmitter Supply (+5V) and Ground. (Analog plane)
37, 31
VCCR, NDR
-
Receiver Supply (+5V) and Ground. (Analog plane)
24, 26
VCCA, NDA
-
Analog Supply (+5V) and Ground.
9, 43
VCCD, GNDD
-
Digital Supply (+5V) and Ground.
53, 52
VCCIO, GNDIO
-
MII Supply (+3.3V or +5V) and Ground. (Digital plane)
Signal Description
1. Pin numbers apply to all package types.
10
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 2.
Pin#1
LXT970A MII Signal Descriptions
Pin Name
I/O2,3
Signal Description4
MII Data Interface Pins
63
TXD4
62
TXD3
61
TXD2
60
TXD1
59
TXD0
58
TX_EN
57
TX_CLK
I
Transmit Data. The Media Access Controller (MAC) drives data to the
LXT970A using these inputs. TXD4 is monitored only in Symbol (5B) Mode.
These signals must be synchronized to the TX_CLK.
I
Transmit Enable. The MAC asserts this signal when it drives valid data on the
TXD inputs. This signal must be synchronized to the TX_CLK.
I/O
Transmit Clock. Normally the LXT970A drives TX_CLK; in Slave Clock Mode,
TX_CLK is an input. Refer to the Clock Requirements discussion in the
Functional Description section on page 18.
25 MHz for 100 Mbps operation.
2.5 MHz for 10 Mbps operation.
TX_ER
46
RXD4
47
RXD3
48
RXD2
49
RXD1
50
RXD0
51
RX_DV
O
Receive Data Valid. The LXT970A asserts this signal when it drives valid data
on RXD. This output is synchronous to RX_CLK.
55
RX_ER
O
Receive Error. The LXT970A asserts this output when it receives invalid
symbols from the network. This signal is synchronous to RX_CLK.
54
RX_CLK
I
Transmit Coding Error. The MAC asserts this input when an error has
occurred in the transmit data stream. When the LXT970A is operating at 100
Mbps, the LXT970A responds by sending invalid code symbols on the line.
56
O
Receive Data. The LXT970A drives received data on these outputs,
synchronous to RX_CLK.
RXD4 is driven only in Symbol (5B) Mode.
O
Receive Clock. This continuous clock provides reference for RXD, RX_DV, and
RX_ER signals. Refer to the Clock Requirements discussion in the Functional
Description section.
25 MHz for 100 Mbps operation.
2.5 MHz for 10 Mbps operation.
64
COL
O
Collision Detected. The LXT970A asserts this output when detecting a
collision. This output remains High for the duration of the collision.
This signal is asynchronous and inactive during full-duplex operation.
1
CRS
O
Carrier Sense. During half-duplex operation (bit 0.8 = 0), the LXT970A asserts
this output when either transmit or receive medium is non-idle. During fullduplex operation (bit 0.8 = 1) or repeater operation
(bit 19.13 = 1), CRS is asserted only when the receive medium is non-idle.
1. Pin numbers apply to all package types.
2. I/O Column Coding: I = Input, O = Output, OD = Open Drain, A = Analog.
3. If bit 17.3 = 0, 55Ω series termination resistors are recommended on all output signals to avoid undershoot/overshoot, even
on short traces.
If bit 17.3 = 1, termination resistors are not required.
4. The LXT970A supports the 802.3 MDIO register set. Specific bits in the registers are referenced using an “X.Y” notation,
where X is the register number (0-6 or 16-20) and Y is the bit number (0-15).
Datasheet
11
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 2.
LXT970A MII Signal Descriptions (Continued)
Pin#1
Pin Name
I/O2,3
Signal Description4
Tri-state. In DTE Mode (19.13 = 0), when TRSTE input is High, the LXT970A
isolates itself from the MII Data Interface, and controls the MDIO register bit
0.10 (Isolate bit).
3
TRSTE
I
When MDDIS is High, TRSTE provides continuous control over bit 0.10. When
MDDIS is Low, TRSTE sets initial (default) values only and reverts control back
to the MDIO interface.
In Repeater Mode (19.13 = 1), when TRSTE input is High, the LXT970A tristates the receive outputs of the MII (RXD<4:0>, RX_DV, RX_ER, RX_CLK).
MII Control Interface Pins
15
MDDIS
I
Management Disable. When MDDIS is High, the MDIO is restricted to Read
Only and the MF<4:0>, CFG<1:0>, and FDE pins provide continual control of
their respective bits. When MDDIS is Low at power up or Reset, the MF<4:0>,
CFG<1:0>, and FDE pins control only the initial or “default” values of their
respective register bits. After the power-up/reset cycle is complete, bit control
reverts to the MDIO serial channel.
45
MDC
I
Management Data Clock. Clock for the MDIO serial data channel. Maximum
frequency is 2.5 MHz.
44
MDIO
I/O
Management Data Input/Output. Bidirectional serial data channel for PHY/
STA communication.
Full-Duplex Status. When bit 17.1 = 0 (default), this pin indicates full-duplex
status. (High = full-duplex, Low = half-duplex)
2
FDS/MDINT
OD
This pin can drive a high efficiency LED. (See Table 23 for detail specifications).
Management Data Interrupt. When bit 17.1 = 1, an active Low output on this
pin indicates status change.
Interrupt is cleared by sequentially reading Register 1, then Register 18.
1. Pin numbers apply to all package types.
2. I/O Column Coding: I = Input, O = Output, OD = Open Drain, A = Analog.
3. If bit 17.3 = 0, 55Ω series termination resistors are recommended on all output signals to avoid undershoot/overshoot, even
on short traces.
If bit 17.3 = 1, termination resistors are not required.
4. The LXT970A supports the 802.3 MDIO register set. Specific bits in the registers are referenced using an “X.Y” notation,
where X is the register number (0-6 or 16-20) and Y is the bit number (0-15).
Table 3.
Pin#1
LXT970A Fiber Interface Signal Descriptions
Pin Name
17
FIBOP
18
FIBON
27
FIBIP
28
FIBIN
I/O2
Signal Description
O
Fiber Output, Positive and Negative. Differential pseudo-ECL driver pair compatible with
standard fiber transceiver for 100BASE-FX.
I
Fiber Input, Positive and Negative. Differential pseudo-ECL receive pair compatible with
standard fiber transceiver for 100BASE-FX.
1. Pin numbers apply to all package types.
2. I/O Column Coding: I = Input, O = Output, OD = Open Drain, A = Analog.
12
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 4.
Pin#1
LXT970A Twisted-Pair Interface Signal Descriptions
Pin Name
21
TPOP
23
TPON
20
TREF
29
TPIP
30
TPIN
I/O2
Signal Description
AO
Twisted-Pair Output, Positive and Negative. Differential driver pair produces 802.3compliant pulses for either 100BASE-TX or 10BASE-T transmission.
AO
Transmit Reference. Tie to center tap of output transformer.
AI
Twisted-Pair Input, Positive and Negative. Differential input pair for either 100BASE-TX
or 10BASE-T reception.
1. Pin numbers apply to all package types.
2. I/O Column Coding: I = Input, O = Output, OD = Open Drain, A = Analog
Table 5.
LXT970A LED Indicator Signal Descriptions
Pin#1
Pin Name
I/O2
Signal Description3
38
LEDS
O
Speed LED. Active Low output indicates 100 Mbps operation is selected.
42
LEDR
O
Receive LED. Active Low output indicates that receiver is active.
41
LEDT
O
Transmit LED. Active Low output indicates transmitter is active.
Link LED. Active Low output;
40
LEDL
O
During 100 Mbps operation, indicates scrambler lock and receipt of valid Idle codes.
During 10 Mbps operation, indicates Link Valid status.
39
LEDC
O
Collision LED. In default mode, active Low output indicates collision. However, LEDC is
programmable and may be set for other indications. For programming options, see
Configuration Register 19 in Table 55, “Configuration Register (Address 19, Hex 13)” on
page 71.
1. Pin numbers apply to all package types.
2. I/O Column Coding: I = Input, O = Output, OD = Open Drain, A = Analog.
3. LEDs are read at power-up to determine scrambler seed values.
Table 6.
LXT970A Miscellaneous Signal Descriptions
Pin#1
Pin Name
I/O2
10
TEST
I
Test. Must be tied Low.
12
XI
I
11
XO
O
Crystal Input and Output. Use a clock at XI or connect a 25 MHz crystal oscillator across
XI and XO. Refer to the Functional Description section for detailed clock requirements on
page 18.
25
RBIAS
AI
Bias Control. Controls operating circuit bias via an external 22.1 kΩ, 1% resistor to
ground.
16
RESET
I
Reset. This active Low input is OR’ed with the control register Reset bit (0.15). The
LXT970A reset cycle is extended 300 µs (nominal) after Reset is de-asserted.
34
PWRDWN
I
Power Down. When High, forces LXT970A into power down mode. This pin is OR’ed with
the Power Down bit (0.11). Refer to Table 45 for more information.
32, 35,
36
N/C
-
No Connection. Leave open.
Signal Description
1. Pin numbers apply to all package types.
2. I/O Column Coding: I = Input, O = Output, OD = Open Drain, A = Analog.
Datasheet
13
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 7.
Pin#1
LXT970A Hardware Control Interface Signal Descriptions
Pin Name
I/O2
Signal Description3
Multi-Function (MF). Five dual-function configuration inputs. Each pin accepts one of four
input voltage levels (VMF1 = 5V, VMF2 = 3.5V, VMF3 = 1.5V, VMF4 = 0V).
A simple resistor divider network, as shown in Figure 20 on page 45, is required to establish
Mid-level (VMF2 and VMF3) settings. VMF1 and VMF4 (default) settings, can be established
with the LXT970A standard power supply and do not require a voltage divider. One voltage
divider may be used to drive the MF pins in designs using multiple LXT970A’s.
8
MF0
7
MF1
6
MF2
5
MF3
4
MF4
Each MF pin internally drives two different configuration functions. The first function
determines the 5-bit address that the LXT970A responds to on the MDIO line. The second
function determines a particular operational mode of the LXT970A. Each MF pin also
determines the state of a particular bit in the MII registers. The MDDIS input determines if this
effect occurs only at initialization (MDDIS = 0) or continuously (MDDIS = 1). The relationship
between the input levels and the two configuration functions are shown in Table 8 on page 16
and Table 9 on page 17.
I
The operating functions of MF4, CFGO, and CFG1 change depending on the state of MF0
(Auto-Negotiation enabled or disabled). The functions of MF4, CFG1 and FDE are
interrelated.
The functions of the five MF inputs are as follows:
Pin
MII Address
MII Bit
MF0
0
0.12
Auto-Negotiation
MF1
1
19.13
Repeater Mode (Disabling DTE Mode)
MF2
2
19.4
5B Symbol Mode (Disabling 4B Nibble Mode)
MF3
3
19.3
Scrambler Operation (Disabling Scrambler)
MF4
4
4.7
4.8
19.2
Operating Function
Auto-Negotiation Enabled - Advertise 100 Mbps
Auto-Negotiation Disabled - Selects TX/FX
1. Pin numbers apply to all package types.
2. I/O Column Coding: I = Input, O = Output, OD = Open Drain, A = Analog.
3. FDE, CFG0, and CFG1 are affected by the MDDIS input pin. When MDDIS = 0, these inputs determine only the initial state
of the function they control. When MDDIS = 1, these inputs provide continuous hardware control over their corresponding
functions.
14
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 7.
Pin#1
LXT970A Hardware Control Interface Signal Descriptions (Continued)
Pin Name
I/O2
Signal Description3
Full-Duplex Enable.
When A/N is enabled, FDE determines full-duplex advertisement capability in combination
with MF4 and CFG1.
13
FDE
I
When A/N is disabled, FDE directly affects full-duplex operation and determines the value of
bit 0.8 (Duplex Mode).
When FDE is High, full-duplex is enabled and 0.8 = 1.
When FDE is Low, full-duplex is disabled and 0.8 = 0.
Configuration Control 0.
When A/N is enabled, Low-to-High transition on CFG0 causes auto-negotiate to re-start and
0.9 = 1.
14
CFG0
I
When A/N is disabled, this input selects operating speed and directly affects bit 0.13.
When CFG0 is High, 100 Mbps is selected and 0.13 = 1. If FX Operation is selected, this
input must be tied High.
When CFG0 is Low, 10 Mbps is selected and 0.13 = 0.
Configuration Control 1.
When A/N is enabled, CFG1 determines operating speed advertisement capabilities in
combination with MF4.
33
CFG1
I
When A/N is disabled, CFG1 enables 10 Mbps link test function and directly affects bit 19.8.
When CFG1 is High, 10 Mbps link test is disabled and 19.8 = 1.
When CFG1 is Low, 10 Mbps link test is enabled and 19.8 = 0.
1. Pin numbers apply to all package types.
2. I/O Column Coding: I = Input, O = Output, OD = Open Drain, A = Analog.
3. FDE, CFG0, and CFG1 are affected by the MDDIS input pin. When MDDIS = 0, these inputs determine only the initial state
of the function they control. When MDDIS = 1, these inputs provide continuous hardware control over their corresponding
functions.
Datasheet
15
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 8 summarizes the relationship between input voltage levels (VMF1, VMF2, VMF3, VMF4) and
the configuration function for each of the MF input pins. Each MF pin shows two configuration
inputs; configuration function and MII address. The initial setting of the corresponding bit is also
shown.
Table 8.
MF Pin Function Settings1, 3
Input Voltage Levels2
Pin
Function
MII Address Bit 0
MF0
Auto-Negotiation
Sets the initial value of bit
0.12
MII Address Bit 1
MF1
Repeater / DTE Mode
Sets the initial value of bit
19.13
MII Address Bit 2
MF2
Nibble (4B) / Symbol (5B) Mode
Sets the initial value of bit
19.4
MII Address Bit 3
MF3
Scrambler Operation
Sets the initial value of bit
19.3
MII Address Bit 4
MF4
VMF1 (5V)
VMF2 (3.5V)
VMF3 (1.5V)
VMF4 (0V)
1
1
0
0
Disabled
Enabled
Enabled
Disabled
(0.12 = 0)
(0.12 = 1)
(0.12 = 1)
(0.12 = 0)
1
1
0
0
DTE
Repeater
Repeater
DTE
(19.13 = 0)
(19.13 = 1)
(19.13 = 1)
(19.13 = 0)
1
1
0
0
Nibble (4B)
Symbol (5B)
Symbol (5B)
Nibble (4B)
(19.4 = 0)
(19.4 = 1)
(19.4 = 1)
(19.4 = 0)
1
1
0
0
Enabled
Bypassed
Bypassed
Enabled
(19.3 = 0)
(19.3 = 1)
(19.3 = 1)
(19.3 = 0)
1
1
0
0
If Auto-Negotiate Enabled via
MF0, MF4 works in combination
with CFG1 to control operating
speed and duplex advertisement
capabilities via bits 4.5 - 4.8.
If Auto-Negotiate Disabled via
MF0, MF4 selects either
TX or FX Mode
Sets the initial value of bit
19.2
See Table 9 for details.
100TX
(19.2 = 0)
100FX
(19.2 = 1)
100FX
(19.2 = 1)
100TX
(19.2 = 0)
1. In MDIO Control Mode, the MF pins control only the initial or default value for the respective register bits. In Manual Control
mode, the MF pins provide continuous control of the respective register bits.
2. Input Voltage Levels (VMF1, VMF2, VMF3, VMF4) for MF pins.
3. See Table 12 through Table 14 for operating configuration set-up.
16
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 9.
LXT970A Auto-Negotiation Operating Speed/Full-Duplex
Advertisement Settings
Input Value
Desired Configuration
Advertise all capabilities
Ignore FDE
Advertise 10 Mbps only
Advertise FD
MDIO Registers
MF4
CFG1
FDE
VMF1, VMF4
Low
–
VMF1, VMF4
High
High
Sets 4.5 = 1
Sets 4.5 = 1
Low
Do Not Advertise FD
Advertised FD
Sets 4.7 = 1
VMF2, VMF3
Low
Advertise 10/100 Mbps
Do Not Advertise FD
Datasheet
High
Sets 4.5 and 4.6 = 0
Sets 4.8 = 1
Sets 4.7 = 1
Low
Do Not Advertise FD
Advertise FD
Sets 4.7 and 4.8 = 0
Sets 4.6 = 0
Advertise 100 Mbps only
Advertise 10/100 Mbps
Sets 4.7 and 4.8 = 0
Sets 4.6 = 1
Advertise 10 Mbps only
Advertise 100 Mbps only
Sets 4.5, 4.6, 4.7 and 4.8 = 1
Sets 4.5 and 4.6 = 0
Sets 4.8 = 0
VMF2, VMF3
High
High
Low
Sets 4.5 and 4.7 = 1
Sets 4.6 and 4.8 = 1
Sets 4.5 and 4.7 = 1
Sets 4.6 and 4.8 = 0
17
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.0
Functional Description
2.1
Introduction
The LXT970A, a new-generation version of the LXT970 10/100 PHY Fast Ethernet Transceiver
incorporates several functional enhancements for a more robust Ethernet solution. The LXT970A
supports optional MII driver strength capabilities and link-loss criteria selectable via the MDIO
register set.
The LXT970A can directly drive a twisted-pair cable for up to 100 meters. The LXT970A also
provides a pseudo-ECL interface for driving a 100BASE-FX fiber connection. On power-up, the
LXT970A uses auto-negotiation with parallel detection to automatically determine line operating
conditions. If the PHY device on the other side of the link supports auto-negotiation, the
LXT970A auto-negotiates using Fast Link Pulse (FLP) bursts. If the PHY partner does not support
auto-negotiation, the LXT970A automatically detects the presence of either link pulses (10 Mbps
PHY) or Idle symbols (100 Mbps PHY) and set its operating speed accordingly. When the line
speed selection is made via the parallel detection method, the duplex mode sets to half. The user
may later select full-duplex operation by subsequent writes to the appropriate MDIO register. Line
operation can also be set using the Hardware Control Interface.
The LXT970A interfaces to a 10/100 MAC through the MII interface. The LXT970A performs all
functions of the Physical Coding Sublayer (PCS) and Physical Media Attachment (PMA) sublayer
as defined in the IEEE 802.3 100BASE-X specification. It also performs all Physical Media
Dependent (PMD) sublayer functions for 100BASE-TX connections. The MII speed is
automatically set once line operating conditions have been determined.
See Figure 3 for a typical Network Interface Card (NIC). The LXT970A supports NIC, repeater,
and switch applications. It provides half- and full-duplex operation at 100 Mbps and 10 Mbps. The
LXT970A supports the 802.3 MDIO register set. Specific bits in the registers are referenced using
an “X.Y” notation, where X is the register address (0-6 or 16-20) and Y is the bit number (0:15).
Figure 3. Network Interface Card (NIC) Application
PC Bus (EISA,PCI)
MAC Controller
Magnetic
LXT970A
18
RJ-45
Connection
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
2.2
Interfaces (Network Media/Protocol Support)
The LXT970A provides the following interfaces:
• A Twisted-Pair Interface which directly supports 100BASE-TX and 10BASE-T applications.
• A pseudo-ECL (PECL) Fiber Interface which supports 100BASE-FX applications through an
external fiber transceiver.
• An MII (Media Independent Interface) for interfacing 10/100 Media Access Controllers
(MACs).
• A Hardware Control Interface to configure various operating characteristics.
2.2.1
Twisted-Pair Interface
The Twisted-Pair Interface directly supports both 100BASE-TX and 10BASE-T applications. The
interface is capable of directly driving an RJ-45 interface through magnetics and termination
resistors. The interface uses two signal pairs - one for transmit and one for receive. A third output,
TREF, connects to the center-tap of the transmit transformer. The same signal pairs, magnetics, and
termination resistors are used for both 10 and 100 Mbps operation.
When the LXT970A is operating as a 100 Mbps device, it transmits and receives a 125 Mbps, 5Bencoded, scrambled MLT-3 waveform on this interface. The MLT-3 waveform is continuous.
When there is no data to send, “IDLE” symbols are sent and received.
When the LXT970A is operating as a 10 Mbps device, it transmits and receives 10 Mbps
Manchester-encoded data. The waveform is not continuous. When there is no data to send, the
line is left in an idle state. Link pulses are transmitted periodically to keep the link up.
The LXT970A supports both fixed operation and auto-negotiation with parallel detection on this
interface. Fixed operation allows the designer to specify the line speed and duplex mode. With
auto-negotiation enabled, the LXT970A automatically determines line speed and duplex state by
exchanging capability “pages” with its link partner.
A 4 kΩ passive load is always present across the twisted-pair inputs. When enabled, the twistedpair inputs are actively biased to approximately 2.8V.
In applications where the Twisted-Pair Interface is not used, the inputs and outputs may be left
unconnected.
The Twisted-Pair Interface is disabled in power down mode, when the Fiber Interface is selected,
or when the transmit disconnect (bit 19.0) is set. When the Twisted-Pair Interface is disabled its
outputs are tri-stated and inputs are unbiased.
2.2.2
Fiber Interface
The pseudo-ECL Fiber Interface is suitable for driving 100BASE-FX applications through an
external fiber transceiver. This interface consists of a transmit and receive pair. The LXT970A
sends and receives a continuous 125 Mbps, 5B-encoded NRZI stream on this interface.
Scrambling and MLT-3 are not used in fiber connections.
There is no industry standard for auto-negotiation on 100BASE-FX. The LXT970A only supports
forced operation on the Fiber Interface. The LXT970A does not support 10FL (10 Mbps fiber)
applications.
Datasheet
19
LXT970A — Dual-Speed Fast Ethernet Transceiver
The LXT970A does not support the Signal Detect Function. However, the PMA functions of the
LXT970A guarantee that it will detect invalid link conditions and break down a link, even without
the Signal Detect function.
In applications where the Fiber Interface is not used, the inputs and outputs may be left
unconnected. The Fiber Interface is disabled in power down mode and when the Twisted-Pair
Interface is enabled. When the Fiber Interface is disabled its outputs are pulled to ground.
2.2.3
MII Interface
The LXT970A implements the Media Independent Interface (MII) as defined in the IEEE 802.3.
This interface consists of a data interface and a management interface as shown in Figure 4. The
data interface is used for exchanging data between a 10/100 802.3 compliant Ethernet Media
Access Controller (MAC) and the LXT970A. The management portion of the interface allows
network management functions to control and monitor the LXT970A.
2.2.3.1
Selectable Driver Levels
The LXT970A supports two options for driver-strength capabilities that can be selected via bit
17.3.
High-strength (bit 17.3 = 0, default) MII driver level can effectively source 50 - 60 mA. To avoid
undershoot or overshoot, series termination resistors are recommended on all output signals when
this driver level is selected.
Reduced (bit 17.3 = 1) MII driver level relaxes the pull-down strength of the MII signals by a
factor of ten and the pull-up strength by a factor of eight. Termination resistors are not required on
the MII outputs when this driver level is selected.
Figure 4. MII Interface
Media Access Controller
Mgmt
Media Independent
Interface (MII)
Data
LXT970A
20
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
2.2.3.2
MII Data Interface
Figure 5 shows the data portion of the MII interface. Separate channels are provided for
transmitting data from the MAC to the LXT970A (TXD), and for receiving data (RXD) from the
line.
Each channel has its own clock, data bus and control signals. The LXT970A supplies both clock
signals as well as separate outputs for carrier sense and collision.
Normal data transmission across the MII is implemented in 4-bit wide nibbles known as 4B Nibble
Mode. In 5B Symbol Mode, a fifth bit allows 5-bit symbols to be sent across the MII. Refer to the
100 Mbps Operation section on page 32 for additional information.
Figure 5. MII Data Interface
TX_CLK
TX_EN
TXD<3:0>
LXT970A
TX_ER
RX_CLK
RX_DV
Media Access
Controller
MAC
RXD<3:0>
RX_ER
CRS
COL
Transmit Clock
The transmit clock (TX_CLK) is normally generated by the LXT970A from the master 25 MHz
reference source at the XI input. However, when the XI input is grounded, TX_CLK becomes the
master reference clock input.
The transmit data and control signals must always be synchronized to TX_CLK by the MAC. The
LXT970A normally samples these signals on the rising edge of TX_CLK. However, Advanced
TX_CLK Mode is available by setting MII register bit 19.5=1. In this mode, the LXT970A
samples the transmit data and control signals on the falling edge of TX_CLK.
Further details of clock modes can be found in the Operating Requirements section on page 27.
Receive Clock
The source of the receive clock varies depending on operating conditions. For 100BASE-TX and
100BASE-FX links, receive clock is continuously recovered from the line. If the link goes down,
and auto-negotiation is disabled, receive clock operates off the master input clock (XI or
TX_CLK).
For 10T links, receive clock is recovered from the line while carrier is active and operates from the
master input clock when the line is idle.
Datasheet
21
LXT970A — Dual-Speed Fast Ethernet Transceiver
The LXT970A synchronizes the receive data and control signals to RX_CLK. The LXT970A
always changes these signals on the falling edge of RX_CLK in order to stabilize the signals at the
rising edge of the clock with 10 ns setup and hold times.
Transmit Enable
The MAC must assert TX_EN the same time as the first nibble of preamble, and de-assert TX_EN
after the last bit of the packet.
Receive Data Valid
The LXT970A asserts RX_DV when it receives a valid packet. Timing changes depend on line
operating speed and MII mode:
• For 100TX and 100FX links with the MII in 4B mode, RX_DV is asserted from the first nibble
of preamble to the last nibble of the data packet.
• For 100TX and 100FX links with the MII in 5B mode, RX_DV is asserted starting with the /K
symbol and ending with the /T symbol.
• For 10BT links, the entire preamble is truncated. RX_DV is asserted with the first nibble of
the SFD “5D” and remains asserted until the end of the packet.
Error Signals
In 100TX mode, when the LXT970A receives an errored symbol from the network, it asserts
RX_ER and drives “1110” (4B) or “01110” (5B) on the RXD pins.
When the MAC asserts TX_ER, the LXT970A drives “H” symbols out on the line.
There are no error functions in 10T mode.
Carrier Sense
Carrier sense (CRS) is an asynchronous output. It is always generated when a packet is received
from the line and in some modes when a packet is transmitted.
On transmit CRS is asserted on a 10BT, half-duplex link when MII Register 19.11 = 0 (default
state), or on any 100 Mbps half-duplex link. Carrier sense is not generated on transmit when the
link operation is full-duplex, or with 10BT half-duplex links when 19.11=1.
Usage of CRS for Interframe Gap (IFG) timing is not recommended for the following reasons:
• De-assertion time for CRS is slightly longer than assertion time. This causes the IFG interval
to appear somewhat shorter to the MAC than it actually is on the wire.
• CRS de-assertion is not aligned with TX_EN de-assertion on transmit loopbacks in halfduplex mode.
Operational Loopback
Operational loopback is provided for 10 Mbps half-duplex links when bit 19.11 = 0. Data
transmitted by the MAC will be looped back on the receive side of the MII. Operational loopback
is not provided for 100 Mbps links, full-duplex links, or when 19.11 = 1.
22
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Test Loopback
A test loopback function is provided for diagnostic testing of the LXT970A. During test loopback
the twisted-pair interface is disabled. Data transmitted by the MAC is internally looped back by
the LXT970A and returned to the MAC.
Test loopback is available for 100 Mbps and 10 Mbps operation. Loopback paths for the two modes
of operation are shown in Figure 6.
Test loopback is enabled by setting bit 0.14 = 1 (loopback), bit 0.8 = 1 (full-duplex), and bit 0.12 =
0 (disable auto-negotiation). The desired mode of operation for test loopback is set using bits 0.13
and 19.2 as shown in Table 10.
Table 10. Test Loopback Operation
Bit
Mode of Operation
19.2
0.13
10 Mbps Test Loopback
0
0
100 Mbps Test Loopback
1
1
1. Also set bit 0.14 = 1, bit 0.8 = 1, and 0.12 = 0 to enable Test
Loopback.
Figure 6. Loopback Paths
100 Mbps
Loopback
10 Mbps
Loopback
MII
Digital
Block
FX
Driver
Analog
Block
TX
Driver
Collision
The LXT970A asserts its collision signal, asynchronously to any clock, whenever the line state is
half-duplex and the transmitter and receiver are active at the same time. Table 11 summarizes the
conditions for assertion of carrier sense, collision, and data loopback signals.
Table 11. Carrier Sense, Loopback, and Collision Conditions
Carrier Sense
Operational
Loopback
Collision
Receive only
None
None
100 Mbps, Half-Duplex
Transmit or Receive
None
Transmit and Receive
10 Mbps, Half-Duplex, 19.11 = 0
Transmit or Receive
Yes
Transmit and Receive
10 Mbps, Half-Duplex, 19.11 = 1
Receive only
None
Transmit and Receive
Speed & Duplex Condition
Full-Duplex at 10 Mbps or 100 Mbps
Repeater Mode
Datasheet
23
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.2.3.3
Repeater Mode
The LXT970A MII normally operates in DTE Mode (19.13 = 0). An alternative operating mode is
available for repeater applications (19.13 = 1).
In Repeater Mode, the Carrier Sense (CRS) and Tri-state (TRSTE) signals request and grant bus
access. The TRSTE pin controls only the receive channel of the MII (RX_DV, RX_ER, RX_CLK,
and RXD).
As shown in Figure 7, a central Repeater State Machine (RSM) is required to perform arbitration
and determine which LXT970A drives the MII Data Interface. The RSM is responsible for
enforcing collisions, and ensuring packets are not transmitted to the port they were received from.
This is accomplished by supplying each LXT970A with individual TX_EN outputs. Although
repeater operation is half-duplex, the LXT970A operates the MII as a full-duplex interface in
Repeater Mode. CRS is generated only on receive and Collision (COL) is never generated.
Repeater Mode is normally used with Slave Clock Mode (XI = GND and TX_CLK is an input).
Figure 7. Repeater Block Diagram
Receive Channel (RXD)
CRS
TX_EN
TRSTE
CRS
TX_EN
TRSTE
Repeater
State Machine
(RSM)
CRS
TX_EN
TRSTE
CRS
TX_EN
TRSTE
LXT970A
LXT970A
LXT970A
LXT970A
Transmit Channel (TXD)
2.2.3.4
MII Management Interface
The LXT970A supports the IEEE 802.3 MII Management Interface also known as the
Management Data Input/Output (MDIO) Interface. This interface allows upper-layer devices to
monitor and control the state of the LXT970A. MDIO interface consists of a physical connection, a
specific protocol which runs across the connection, and an internal set of addressable registers. The
physical interface consists of a data line (MDIO) and clock line (MDC), a control line (MDDIS)
24
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
and an optional interrupt line (MDINT). The LXT970A can signal an interrupt using the MDIO
signal as shown in Figure 8. The user can also assign a separate pin for this function. If bit 17.1 = 1,
pin 2 (FDS/MDINT) will be used as an MDINT pin.
The protocol allows one controller to communicate with multiple LXT970A devices. The MF pins
control one bit each of the 5-bit address setting. Each LXT970A is assigned an MII address
between 0 and 31. Details of the MF inputs are shown in Table 7 on page 14. Timing for the MDIO
Interface is shown in Table 42 on page 61. Read and write operations are shown in Figure 9 and
Figure 10. Operation of this interface is controlled by the MDDIS input pin. When MDDIS is High,
the MDIO operates as a read-only interface. When MDDIS is Low, read and write are enabled.
The LXT970A supports twelve 16-bit MDIO registers. Registers 0-6 are required and their
functions are specified by the IEEE 802.3 specification. Additional registers are included for
expanded functionality. The MDIO Register set for the LXT970A is described in Table 45 through
Table 56. Specific bits in the registers are referenced using an “X.Y” notation, where X is the
register number (0-6 or 16-20) and Y is the bit number (0-15).
MII Management Interrupt
The MDINT/FDS pin functions as a management data interrupt on the MII when 17.1 = 1. An
active Low on this pin indicates a status change on the LXT970A. The interrupt is activated when
changes are made to the following conditions:
• Link Status
• Duplex Status
This interrupt is cleared by sequentially reading Register 1 and Register 18.
Figure 8. MDIO Interrupt Signaling
MDC
INT
MDIO
Interrupt
MDIO FRAME
0
Z
Turn
Around
Read Data
Sourced by
LXT970A
Idle
Figure 9. Management Interface - Read Frame Structure
MDC
MDIO
(Read)
32 "1"s
Idle
0
1
Preamble
SFD
A4
0
1
Op Code
A3
A0
R4
R3
R0
Z
Register Address
PHY Address
D15 D15D14 D14 D1 D1 D0
0
Turn
Around
Data
Write
Idle
Read
Figure 10. Management Interface - Write Frame Structure
MDC
MDIO
(Write)
32 "1"s
Idle
Preamble
0
1
SFD
0
1
Op Code
A4
A3
A0
R4
PHY Address
R3
Register Address
R0
1
0
Turn
Around
D15
D14
D1
Data
D0
Idle
Write
Datasheet
25
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.2.4
Hardware Control Interface
The Hardware Control Interface consists of MF<4:0>, CFG <1:0> and FDE input pins. This
interface is used to configure operating characteristics of the LXT970A and to determine the
MDIO Address. When MDDIS is Low, the Hardware Control Interface provides initial values for
the MDIO registers, and then passes control to the MDIO Interface.
When MDDIS is High, the Hardware Control Interface provides continuous control over the
LXT970A. Individual chip addressing allows multiple LXT970A devices to share the MII in either
mode. Table 12, Table 13 and Table 14 show how to set up the desired operating configurations
using the Hardware Control Interface.
.
Table 12. Configuring the LXT970A via Hardware Control
Desired Configuration
Pin Name
Voltage Level
MDIO Registers
1
MF0
VMF2, VMF3
0.12 = 1
2
MF0
VMF1, VMF4
0.12 = 0
VMF1, VMF4
19.13 = 0
19.4 = 0
19.3 = 0
Auto-Negotiation Enabled
Auto-Negotiation Disabled
MF1
Normal Operation
MF2
(DTE Mode, Nibble Mode, Scrambler Enabled)
MF3
Repeater Mode
MF1
VMF2, VMF3
19.13 = 1
Symbol Mode
MF2
VMF2, VMF3
19.4 = 1
Scrambler Bypass Mode
MF3
VMF2, VMF3
19.3 = 1
1. Refer to Table 13 for Hardware Control Interface functions available when auto-negotiation is enabled.
2. Refer to Table 14 for Hardware Control Interface functions available when auto-negotiation is disabled.
Table 13. LXT970A Operating Configurations / Auto-Negotiation Enabled
Desired
Configuration1,2
Input Value
MDIO Registers
MF4
CFG1
FDE
4.5
4.6
4.7
4.8
Advertise All
VMF1, VMF4
Low
Ignore
1
1
1
1
Advertise 100 HD
VMF2, VMF3
Low
Low
0
0
1
0
Advertise 100 HD/FD
VMF2, VMF3
Low
High
0
0
1
1
Advertise 10 HD
VMF1, VMF4
High
Low
1
0
0
0
Advertise 10 HD/FD
VMF1, VMF4
High
High
1
1
0
0
Advertise 10/100 HD
VMF2, VMF3
High
Low
1
0
1
0
Advertise 10/100 HD/FD
VMF2, VMF3
High
High
1
1
1
1
1. Refer to Table 12 for basic configurations.
2. Refer to Table 14 for Hardware Control Interface functions available when auto-negotiation is disabled.
26
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 14. LXT970A Operating Configurations / Auto-Negotiation Disabled
Desired Configuration1,2
Force 100FX Operation
Pin Name
Input Value
MDIO Registers
MF4
VMF2, VMF3
19.2 = 1
CFG0
High
0.13 = 1
MF3
VMF1, VMF4
19.3 = 0
MF4
VMF1, VMF4
19.2 = 0
Force 100TX Operation
CFG0
High
0.13 = 1
MF4
VMF1, VMF4
19.2 = 0
CFG0
Low
0.13 = 0
FDE
High
0.8 = 1
Disable 10T Link Test
CFG1
High
19.8 = 1
Enable 10T Link Test
CFG1
Low
19.8 = 0
Force 10T Operation
Force Full-Duplex Operation
1. Refer to Table 12 for basic configurations.
2. Refer to Table 13 for Hardware Control Interface functions available when auto-negotiation is enabled.
2.3
Operating Requirements
2.3.1
Power Supply Requirements
The LXT970A requires a 5V power supply. Power should be supplied from a single source to the
VCC, VCCA, VCCT, and VCCR power pins. A ground return path must be provided to the GND,
GNDA, GNDT, and GNDR pins. As a matter of practice, the power supply should be as clean as
possible. Filtering is recommended for the analog power pins (VCCA, VCCT, VCCR) at least in
the initial design. Consult the Design Recommendations section on page 42 for details. A
decoupling capacitor is recommended between each VCC pin and its respective GND, placed as
close to the device as possible.
2.3.1.1
Optional MII Power Supply
The MII may be powered by either a 3.3V or 5V source via the VCCIO pin. To avoid power
sequencing issues, the VCCIO pin should be supplied from the same source used to power the
other side of the MII interface. When VCCIO is supplied with 3.3V, the MII inputs are not tolerant
of 5V signal levels. The MDIO and MDC pins must be operated at the same voltage as the rest of
the MII interface.
2.3.2
Reference Clock Requirements
The LXT970A requires a continuous, stable reference clock. There are two clock modes, Master
Clock Mode and Slave Clock Mode. Depending on the mode of operation, the clock may be
supplied at the crystal oscillator pins (XI, XO), or at the Transmit Clock pin (TX_CLK). See Table
25 on page 48 for input clock requirements.
Datasheet
27
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.3.2.1
Master Clock Mode
The Master Clock mode is recommended in most Network Interface Cards (NICs) and switch
applications. In Master Clock mode the LXT970A is the master clock source for data transmission,
and requires a 25 MHz reference signal at XI. The reference clock may be supplied either from a
crystal oscillator or from a digital clock circuit with the following specifications:
• A frequency of 25 MHz +/-100 ppm
• 40/60 duty cycle or better
• CMOS voltage levels (VOH >3.2V).
In Master Clock Mode, TX_CLK is an output and the LXT970A automatically sets the speed of
TX_CLK to match line conditions. If the line is operating at 100 Mbps, TX_CLK will be set to 25
MHz. If the line is operating at 10 Mbps, TX_CLK will be set to 2.5 MHz.
External Crystal
A crystal is typically used in NIC applications. If using a crystal oscillator, it should be
fundamental-mode and parallel-resonant, with a drive capacity of at least 7 pF. Attach between the
XI and XO pins. Add compensating capacitors between each leg and digital ground. The correct
value to use is the nominal drive capacity of the crystal minus 3 pF (input capacitance of the XI and
XO pins). One crystal can be used to drive two LXT970As. Connect the XO pin of only one 970
to one side of the crystal, and connect the other side to both XI pins. Calculate compensation
accordingly.
External Clock
An external 25 MHz clock source, rather than a crystal, is frequently used in switch applications.
When a clock is supplied to XI, XO is left open.
TX Clock Advance Mode
When operating in Master Clock mode under MDIO Control, the user can advance the transmit
clock relative to TXD<4:0> and TX_ER. When TX_CLK Advance is selected, the LXT970A
clocks TXD data in on the falling edge of TX_CLK, instead of the rising edge.
This mode provides an increase in timing margins of TXD, relative to TX_CLK. TX_CLK
Advance is enabled when bit 19.5 = 1.
2.3.2.2
Slave Clock Mode
The Slave Clock mode is typically used for repeater applications, where the LXT970A is not the
master clock source for data transmissions. In Slave Clock Mode, a digital clock circuit with TTL
levels (VOH >2.4V) must supply the TX_CLK input. The frequency may be either 25 MHz or 2.5
MHz. Either frequency can be used during auto-negotiation. However, once link is established,
the supplied frequency must match the link state. A 25 MHz clock must be supplied for correct
operation of a 100TX or 100FX link, and a 2.5 MHz clock must be supplied for correct operation
of a 10BT link. In Slave Clock mode, XI is connected to ground and XO is left open.
28
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
2.3.3
Bias Circuit Requirements
A 22.1 kΩ 1% resistor must be tied between the RBIAS input and ground. High-speed signals
should be kept away from this resistor. Follow the layout recommendations given in the Design
Recommendations section on page 42.
2.4
Initialization
At power-up or reset, the LXT970A performs the initialization sequence shown in Figure 11.
2.4.1
Control Mode Selection
Mode control selection is provided via the MDDIS pin as shown in Table 15. When pin 15
(MDDIS) is High, the LXT970A enters Manual Control Mode. When MDDIS is Low, MDIO
Control Mode is enabled.
2.4.1.1
MDIO Control Mode
In the MDIO Control mode, the LXT970A reads the Hardware Control Interface pins to set the
initial (default) values of the MDIO registers. Once the initial values are set, bit control reverts to
the MDIO interface.
2.4.1.2
Manual Control Mode
In the Manual Control Mode, LXT970A disables direct write operations to the MDIO registers via
the MDIO Interface. The LXT970A continuously monitors the Hardware Control Interface pins
and updates the MDIO registers accordingly.
Table 15. Mode Control Settings
Mode
2.4.2
MDDIS
RESET
PWRDWN
MDIO Control
Low
High
Low
Manual Control
High
High
Low
Reset
-
Low
Low
Power Down
-
-
High
Link Configuration
When the LXT970A is first powered on, reset, or encounters a link failure state, it must determine
the line speed and operating conditions to use for the network link. The LXT970A first checks the
MDIO registers (initialized via the Hardware Control Interface or MDIO Interface) for operating
instructions. Both control modes allow the user to either force the LXT970A to a specific
configuration or allow it to auto-negotiate the optimum configuration with its link partner.
Datasheet
29
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.4.2.1
Manual Configuration
The LXT970A can be manually configured to force operation in the following modes:
•
•
•
•
•
•
100FX, full-duplex
100FX, half-duplex
100TX, full-duplex
100TX, half-duplex
10T, full-duplex
10T, half-duplex
Refer to Table 12 through Table 14 in the Hardware Control Interface discussion for specific
manual configuration settings.
Figure 11. LXT970A Initialization Sequence
Power-up or Reset
MDIO Control
Mode
Low
Check Value
MDDIS
High
Manual Control
Mode
Read H/W Control
Interface
Disable MDIO Writes
Initialize MDIO Registers
Read H/W Control
Interface
Pass Control to MDIO
Interface
Update MDIO Registers
Exit
2.4.2.2
Auto-Negotiation/Parallel Detection
With auto-negotiation enabled at power-up or reset, the LXT970A attempts to establish link
operating conditions with its partner by sending Fast Link Pulse (FLP) bursts.
If the link partner is also capable of auto-negotiation, the two devices exchange FLP bursts to
communicate their capabilities to each other. Each side finds the highest common capabilities that
both sides can support and then begins operating in that mode.
If the link partner is not capable of auto-negotiation, it transmits either 10 Mbps Normal Link
Pulses (NLP) or 100 Mbps Idle symbols. When the LXT970A detects either NLPs or Idle symbols,
it automatically configures to match the detected operating speed in half-duplex mode. This ability
allows the LXT970A to communicate with devices that do not support auto-negotiation.
30
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Controlling Auto-Negotiation
When auto-negotiation is controlled by software, the following steps are recommended:
• After a reset or power-up (initial or from power down mode), the power down recovery time
(refer to Table 43 on page 62) must be exhausted before proceeding.
• Set MDIO Register 4 advertisement capabilities before setting MDIO bit 0.12 = 1 to enable
auto-negotiation.
Figure 12. Auto-Negotiation Operation
Power-Up, Reset,
Link Failure
Start
Disable
Auto-Negotiation
Go To Forced
Settings
Done
Enable
Auto-Neg/Parallel Detection
Auto
Negotiation
Attempt AutoNegotiation
YES
2.5
Monitoring Operational Status
2.5.1
Monitoring Status via MII Registers
Listen for 100TX
Idle Symbols
Link Set?
Listen for 10T
Link Pulses
NO
The Chip Status Register (Table 56 on page 72) provides a convenient indication of several status
conditions:
• Bit 20.13 is set to 1 once the link is established.
• Bits 20.11 and 20.12 indicate the link speed and duplex condition respectively.
• Bits 20.9 and 20.8 indicate the progress and status of auto-negotiation.
Refer to the Register Definition section on page 63 for additional details on specific registers.
Datasheet
31
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.5.2
Monitoring Status via Indicator Pins
The LEDS, LEDR, LEDT, LEDL, and LEDC pins are CMOS digital outputs that drive LEDs.
These pins along with the FDS/MDINT output, can also be used to externally monitor the status of
the LXT970A. The following notes apply to the FDS/MDINT and LED pins:
• LEDR, LEDT and LEDC pulse Low to indicate receive, transmit, and collision activity
respectively. When the LXT970A asserts these signals, it automatically extends them for 100
ms.
• LEDL indicates link status and LEDS indicates link speed. LEDL and LEDS are active Low.
• In its default state (17.1 = 0), the MDINT/FDS output indicates duplex condition. FDS is
active High.
Table 16 shows the state of the LXT970A according to the status of LEDL, LEDS, and FDS pins.
Table 16. LXT970A Status using FDS/LED Pins
LXT970A State
Pin Status
LEDL
LEDS
FDS
During Power-up
High
High
Low
During Auto-Negotiation or
Link Failure
High
High
Low
Link-up; 100 Mbps; full-duplex
Low
Low
High
Link-up; 100 Mbps; half-duplex
Low
Low
Low
Link-up; 10 Mbps; full-duplex
Low
High
High
Link-up; 10 Mbps; half-duplex
Low
High
Low
2.6
100BASE-X Operation
2.6.1
100BASE-X MII Operations
The MAC exchanges data with the LXT970A over the MII interface. The LXT970A converts the
digital data from the MAC into an analog waveform that is transmitted to the network via the
copper (TX) or fiber (FX) interface. The LXT970A converts analog signals received from the
network into a digital format and sends them to the MAC via the MII. Refer to the MII interface
discussion on page 20 for details on MII control and data signals.
The 100BASE-X protocol specifies the use of a 5-bit symbol code on the network media. However,
data is normally transmitted across the MII interface in 4-bit nibbles. The LXT970A incorporates a
4B/5B encoder/decoder circuit that translates 4-bit nibbles from the MII into 5-bit symbols for the
100BASE-X connection, and translates 5-bit symbols from the 100BASE-X connection into 4-bit
nibbles for the MII. Figure 14 shows the data conversion flow from nibbles to symbols. Table 17
shows 4B/5B symbol coding (not all symbols are valid).
In some applications it may be desirable to bypass the 4B/5B encoder/decoder circuit, and operate
the MII as a 5-bit symbol mode interface. The LXT970A provides additional lines in both the
receive and transmit channels (RXD4 & TXD4) to accommodate MACs that accept 5-bit symbols.
32
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
2.6.2
100BASE-X Network Operations
During 100BASE-X operation, the LXT970A transmits and receives 5-bit symbols across the
network link. Figure 13 shows the structure of a standard frame packet. When the MAC is not
actively transmitting data, the LXT970A sends out Idle symbols on the line.
In 100TX mode, the LXT970A scrambles the data using a polynomial key, and transmits it to the
network using MLT-3 line code. The MLT-3 signals received from the network are descrambled
and decoded by the LXT970A, and sent across the MII to the MAC.
In 100FX mode, the LXT970A transmits and receives NRZI signals across the pseudo-ECL
interface. An external 100FX transceiver module is required to complete the fiber connection. To
enable 100FX operation, auto-negotiation must be disabled and FX selected.
Figure 13. 100BASE-TX Frame Structure
64-Bit Preamble
(8 Octets)
P0
P1
Replaced by
/J/K/ code-groups
Start of Stream
Delimiter (SSD)
P6
Destination and Source
Address (6 Octets each)
SFD
DA
DA
SA
Packet Length
(2 Octets)
SA
L1
Data Field
Frame Check Field InterFrame Gap / Idle Code
(Pad to minimum packet size)
(4 Octets)
(> 12 Octets)
L2
D0
D1
Dn
CRC
IFG
I0
Replaced by
/T/R/ code-groups
End of Stream Delimiter (ESD)
Start of Frame
Delimiter (SFD)
Figure 14. 100BASE-TX Data Flow
Standard Data Flow
D0
D1
+1
Parallel
to
Serial
D0
D2
D3
0
Scramble
D1
D2
D3
4B/5B
S0
S1
S2
S3
S4
Serial
to
Parallel
DeScramble
0
0
-1
MLT3
Transition = 1.
No Transition = 0.
All transitions must follow
pattern: 0, +1, 0, -1, 0, +1...
Symbol (5B) Mode Data Flow
S0
S1
Parallel
to
Serial
S2
S3
+1
S0
Serial
to
Parallel
0
Scramble
S1
S2
S3
S4
DeScramble
0
0
-1
MLT3
Transition = 1.
No Transition = 0.
All transitions must follow
pattern: 0, +1, 0, -1, 0, +1...
S4
Scrambler Bypass Data Flow
S0
S1
S2
S3
S4
Datasheet
+1
Parallel
to
Serial
0
MLT3
Serial
to
Parallel
0
0
-1
Transition = 1.
No Transition = 0.
All transitions must follow
pattern: 0, +1, 0, -1, 0, +1...
33
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 17. 4B/5B Coding
Code Type
DATA
IDLE
CONTROL
4B Code
3210
Name
5B Symbol
43210
0000
0
11110
Data 0
0001
1
01001
Data 1
0010
2
10100
Data 2
0011
3
10101
Data 3
0100
4
01010
Data 4
0101
5
01011
Data 5
0110
6
01110
Data 6
0111
7
01111
Data 7
1000
8
10010
Data 8
1001
9
10011
Data 9
1010
A
10110
Data A
1011
B
10111
Data B
1100
C
11010
Data C
1101
D
11011
Data D
1110
E
11100
Data E
1111
F
11101
Data F
I
1
11111
Idle. Used as inter-stream fill code
0101
J
2
11000
Start-of-Stream Delimiter (SSD), part 1 of 2
0101
K2
10001
Start-of-Stream Delimiter (SSD), part 2 of 2
T
3
01101
End-of-Stream Delimiter (ESD), part 1 of 2
R
3
00111
End-of-Stream Delimiter (ESD), part 2 of 2
H
4
undefined
undefined
undefined
00100
Transmit Error. Used to force signaling errors
undefined
Invalid
00000
Invalid
undefined
Invalid
00001
Invalid
undefined
Invalid
00010
Invalid
undefined
Invalid
00011
Invalid
undefined
Invalid
00101
Invalid
undefined
Invalid
00110
Invalid
undefined
Invalid
01000
Invalid
undefined
Invalid
01100
Invalid
undefined
Invalid
10000
Invalid
undefined
Invalid
11001
Invalid
undefined
INVALID
1.
2.
3.
4.
34
Interpretation
The /I/ (Idle) code-group is sent continuously between frames.
The /J/ and /K/ (SSD) code-groups are always sent in pairs; /K/ follows /J/.
The /T/ and /R/ (ESD) code-groups are always sent in pairs; /R/ follows /T/.
An /H/ (Error) code-group is used to signal an error condition.
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
2.7
10BASE-T Operation
2.7.1
10BASE-T MII Operations
The MAC transmits data to the LXT970A over the MII interface. The LXT970A converts the
digital data from the MAC into an analog waveform that is transmitted to the network via the
copper interface. The LXT970A converts analog signals received from the network into a digital
format suitable for the MAC. The LXT970A sends the received data to the MAC via the MII. The
5-bit symbol code is not used for 10BASE-T operation. The MII operates only as a 4-bit interface
and the RXD4 & TXD4 lines are not used.
2.7.2
10BASE-T Network Operations
During 10BASE-T operation, the LXT970A transmits and receives Manchester-encoded data
across the network link. When the MAC is not actively transmitting data, the LXT970A sends out
link pulses on the line.
In 10BASE-T mode, the polynomial scrambler/descrambler is inactive. Manchester-encoded
signals received from the network are decoded by the LXT970A and sent across the MII to the
MAC.
The LXT970A does not support fiber connections at 10 Mbps.
2.8
Protocol Sublayer Operations
With respect to the 7-layer communications model, the LXT970A is a Physical Layer 1 (PHY)
device. The LXT970A implements the Physical Coding Sublayer (PCS), Physical Medium
Attachment (PMA), and Physical Medium Dependent (PMD) sublayers of the reference model
defined by the IEEE 802.3u specification. The following paragraphs discuss LXT970A operation
from the reference model point of view.
2.8.1
PCS Sublayer
The Physical Coding Sublayer (PCS) provides the MII interface, as well as the 4B/5B encoding/
decoding function when the MII is operating as a 4B interface.
For 100TX and 100FX operation, the PCS layer provides IDLE symbols to the PMD-layer line
driver as long as TX_EN is de-asserted.
When the MII is operating in 5B mode, the encoder/decoder function is disabled, and symbol data
presented at the MII is transparently passed downstream, and vice versa.
For 10T operation, the PCS layer merely provides a bus interface and serialization/de-serialization
function. 10T operation does not use the 4B/5B encoder, and is not supported when the MII is in
5B mode.
Datasheet
35
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.8.1.1
100X Preamble Handling
When the MAC asserts TX_EN, the PCS substitutes a /J/K symbol pair, also known as the Start of
Stream Delimiter or SSD, for the first two nibbles received across the MII. The PCS layer
continues to encode the remaining MII data, following Table 17, until TX_EN is de-asserted. It
then returns to supplying IDLE symbols to the line driver.
In the receive direction, the PCS layer performs the opposite function, substituting two preamble
nibbles for the SSD.
2.8.1.2
10T Preamble Handling
In 10BASE-T Mode, the LXT970A strips the entire preamble off of received packets. CRS is
asserted a few bit times after carrier is detected. RX_DV is held for the duration of the preamble.
When RX_DV is asserted, the very first two nibbles driven by the LXT970A are the SFD “5D” hex
followed by the body of the packet. In 10T loopback
the LXT970A loops back whatever the MAC transmits to it, including the preamble.
Figure 15. LXT970A Protocol Sublayers
MII Interface
PCS
Layer
LXT970A
Encoder/Decoder
Serializer/De-serializer
PMA
Layer
Link/Carrier Detect
PECL Interface
PMD
Layer
Scrambler/Descrambler
100BASETX
2.8.1.3
Fiber Transceiver
100BASE-FX
Data Errors (100X Only)
Figure 16 shows normal reception. When the LXT970A receives invalid symbols from the line, it
asserts RX_ER, as shown in Figure 17.
36
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
2.8.1.4
Collision Indication
Figure 18 shows normal transmission. The LXT970A detects a collision if transmit and receive are
active at the same time. As shown in Figure 19 upon detection of a collision, the COL output is
asserted and remains asserted for the duration of the collision.
Figure 16. 100BASE-TX Reception with No Errors
RX_CLK
RX_DV
RXD<3:0>
preamble SFD SFD
DA
DA
DA
CRC
DA
CRC
CRC
CRC
RX_ER
Figure 17. 00BASE-TX Reception with Invalid Symbol
RX_CLK
RX_DV
preamble
RXD<3:0>
SFD
SFD
DA
DA
DA
XX
DA
DA
DA
DA
DA
DA
DA
DA
RX_ER
Figure 18. 00BASE-TX Transmission with No Errors
TX_CLK
TX_EN
P
TXD<3:0>
R
E
A
M
B
L
DA
E
DA DA
DA
DA
DA
DA
DA
DA
CRS
COL
1. In half-duplex mode, CRS asserts when receive or transmit are active. In full-duplex mode, CRS asserts during receive only.
Figure 19. 00BASE-TX Transmission with Collision
TX_CLK
TX_EN
TXD<3:0>
P
R
E
A
M
B
L
E
JAM
JAM
JAM
JAM
CRS
COL
1. In half-duplex mode, CRS asserts when receive or transmit is active. In full-duplex mode, CRS asserts during receive only.
Datasheet
37
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.8.1.5
SQE (10T Only)
When the SQE (heartbeat) function is enabled, the LXT970A asserts its COL output for 5-15 BT
after each packet. By default, the SQE function is disabled on the LXT970A. To enable SQE, set
bit 19.10 = 1. See Figure 30 on page 59 for SQE timing parameters.
2.8.1.6
Jabber (10T Only)
If the MAC transmission exceeds the jabber timer, the LXT970A disables the transmit and
loopback functions and asserts the COL pin. The LXT970A automatically exits jabber mode after
250-750 ms. This function can be disabled by setting bit 19.9 = 1. See Figure 31 on page 59 for
Jabber timing parameters.
2.8.2
PMA Layer
The Physical Medium Attachment (PMA) layer provides link and carrier status functions.
2.8.2.1
100TX Link Options
The LXT970A uses standard symbol error rate criteria to establish a link and has two options for
100TX and 100FX applications to break down a link:
• Standard (symbol error rate).
• Enhanced (scrambler lock).
Standard link criteria (17.2 = 0 default), takes down the link when the Bit Error Rate (BER)
exceeds the allowable standards. If the link goes down and auto-negotiation is enabled, the device
automatically restarts the auto-negotiation process. Otherwise the device continues to monitor the
line for a valid link. With this option both link up and link loss are based on symbol error rate.
Enhanced link-loss criteria (17.2 = 1) works independent of symbol error rate. The loss of
scrambler lock for more than 1 - 2 msec brings the link down. Enhanced link-loss criteria is not
available in 5B mode.
2.8.2.2
10T Link Test
For 10T operation, link is detected via Normal Link Pulses (NLPs). In 10T mode, the LXT970A
always transmits link pulses. If the Link Test Function is enabled, it monitors the connection for
link pulses. Once it detects 2 to 7 link pulses, data transmission will be enabled and remains
enabled as long as the link pulses or data transmission continues. Link failure occurs if Link Test is
enabled and link pulses are no longer received. When this condition occurs, the LXT970A returns
to the auto-negotiation phase if auto-negotiation is enabled. If the Link Test function is disabled,
the LXT970A transmits to the connection regardless of detected link pulses. The Link Test
function can be disabled by setting bit 19.8 = 1 or by setting MF0 to disable auto-negotiation and
setting CFG1 input High.
2.8.2.3
Carrier Sense (CRS)
For 100TX and 100FX links, a start-of-stream delimiter or /J/K symbol pair causes assertion of
carrier sense (CRS). An end-of-stream delimiter, or /T/R symbol pair causes deassertion of CRS.
The PMA layer also de-asserts CRS if IDLE symbols are received without /T/R, however, in this
case RX_ER asserts for one clock cycle when CRS is de-asserted.
38
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
For 10T links, CRS assertion is based on reception of valid preamble, and de-assertion on reception
of an end-of-frame (EOF) marker.
The PMA layer in the LXT970A does not support the optional Far-End-Fault function.
2.8.3
Twisted-Pair PMD Layer
The twisted-pair Physical Medium Dependent (PMD) layer provides the signal scrambling and
descrambling, line coding and decoding (MLT-3 for 100TX, Manchester for 10T), as well as
receiving, polarity correction, and baseline wander correction functions.
2.8.3.1
Scrambler/Descrambler (100TX Only)
The scrambler spreads the signal power spectrum and reduces EMI and baseline wander.
Scrambling is done with an 11-bit, non-data-dependent polynomial. The receiver automatically
decodes the polynomial whenever IDLE symbols are received.
The LXT970A provides a scrambler-bypass mode for testing purposes. Bypassing the scrambler
causes the PCS-layer encoder to be bypassed as well, and the MII to operate in 5B mode.
2.8.3.2
Baseline Wander Correction
(100TX Only)
The LXT970A provides a baseline wander correction function that makes the device robust under
all network operating conditions. The MLT3 coding scheme used in 100BASE-TX is by definition
“unbalanced”, which means the average DC value of the signal voltage can “wander” significantly
over short time intervals (tenths of seconds). In less robust PHY devices, this wander can cause
receiver errors, particularly at long line lengths (100 meters). The exact characteristics of the
wander are completely data dependent. The LXT970A baseline wander correction circuitry allows
error-free data recovery, even at long line lengths.
2.8.3.3
Polarity Correction
The LXT970A automatically detects and corrects for the condition where the receive signal (TPIP/
N) is inverted. Reversed polarity is detected if eight inverted link pulses, or four inverted end-offrame markers, are received consecutively. If link pulses or data are not received for 96-128 ms,
the polarity state is reset to a non-inverted state.
2.8.4
Fiber PMD Layer
The LXT970A provides a pseudo-ECL interface for connection to an external fiber optic
transceiver. (The external transceiver provides the PMD function for fiber media.) The LXT970A
uses an NRZI format for the fiber interface. The fiber interface operates at 100 Mbps and is
intended for 100FX applications. It does not support 10FL applications. The fiber interface does
not support the signal detect function supplied by most fiber optic transceivers. However, the link
detection function in the PMA layer quickly detects faults in the fiber link.
Datasheet
39
LXT970A — Dual-Speed Fast Ethernet Transceiver
2.8.5
Additional Operating Features
2.8.6
Low-Voltage-Fault Detect
The LXT970A low-voltage fault detection function prevents transmission of invalid symbols when
VCC goes below normal operating levels. If this condition occurs, the LXT970A disables the
transmit outputs and sets 20.2 = 1. Operation is automatically restored when VCC returns to
normal. Table 26 on page 49 indicates voltage levels that detect and clear the low-voltage fault
condition.
2.8.7
Power Down Mode
The LXT970A goes into power down mode when PWRDWN is asserted. In this mode, all
functions are disabled except the MDIO. The power supply current is significantly reduced. This
mode can be used for energy-efficient applications or for redundant applications where there are
two devices and one is left as a stand-by. When the LXT970A is returned to normal operation,
configuration settings of the MDIO registers are maintained. Refer to Table 22 on page 47 for
power down specifications.
2.8.8
Software Reset
Software reset causes all state machines to be reset and the LXT970A to re-configure itself to the
settings of the hardware configuration pins (MF<4:0>, FDE, CFG0, CFG1).
The LXT970A is reset via software(0.15 = 1). This bit setting is maintained while the reset
operation is running. When the reset operation is complete, the LXT70 resets bit 0.15 = 0.
2.8.9
Hardware Reset
Hardware reset causes the LXT970A to reset all of its functions and re-configure itself based on the
hardware configuration pin settings.
The LXT970A performs a hardware reset when a Low signal is detected at the RESET pin. All
operational conditions must be met for this function to operate. VCC must be above 4.75V and
stable, and the RESET signal must be asserted for two cycles of the master input clock. The
LXT970A continues to drive an internal reset for a period of 300 µs after the RESET signal is deasserted to ensure that all functions start up smoothly. MII registers are not available and the MDIO
output is tri-stated during the internal reset period. Refer to Table 43 on page 62 for hardware reset
specifications.
40
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
3.0
Application Information
3.1
Magnetics Information
The LXT970A requires a 1:1 ratio for both the receive and the transmit transformers. Refer to
Table 18 for magnetics requirements.
A cross-reference list of magnetic manufacturers and part numbers is available in Application Note
73, Magnetic Manufacturers, which can be found on the Intel web site (developer.intel.com/design/
network/). Designers must test and evaluate all components for suitability in their applications.
Table 18. Magnetics Requirements
Parameter
Rx and Tx Turns Ratio
Min
Nom
Max
Units
–
1:1
–
–
Test Condition
Insertion Loss
0.0
–
1.1
dB
Primary Inductance
350
–
–
µH
–
2
–
kV
–
–
-40
dB
.1 to 60 MHz
Transformer Isolation
Differential to common mode rejection
–
–
-35
dB
60 to 100 MHz
–
–
-17
dB
.1 to 60 MHz
–
–
-15
dB
60 to 100 MHz
2.0
–
3.5
ns
10% to 90%
Return Loss
Rise Time
3.2
Crystal Information
The LXT970A requires a parallel-resonant fundamental-mode crystal that meet specifications as
shown in Table 19. XI and XO input capacitance and voltage requirements are provided in Table 25
on page 48.
Crystals are available from various manufacturers. Designers should test and validate all crystals
before committing to a specific component. Based on limited evaluation, Table 20 provides
suitable crystal component manufacturers.
Table 19. Crystal Requirements
Parameter
Min
Nom
Max
Units
Frequency
–
Frequency Stability
–
25.0
–
MHz
–
±100
ppm
Test Condition
-40 - 85oC
1. See Table 25 (Clock Characteristics) for additional device specifications.
Table 20. Crystal Component Manufacturers
Component
Manufacturer
Part Number
Epson America
MA-505-25.000M
Caliber Electronics
AA18C1-25.000MHz
Crystal
Datasheet
41
LXT970A — Dual-Speed Fast Ethernet Transceiver
3.3
Design Recommendations
The LXT970A is designed in accordance with IEEE requirements and provides outstanding
receive Bit Error Ratio (BER) and long-line-length performance. Lab tests show that the
LXT970A performs well beyond the required distance of 100 meters. Ensuring maximum
performance from the LXT970A requires attention to detail and good design practices. Refer to
the LXT970 Design and Layout Guide for detailed design and layout information.
3.3.1
General Design Guidelines
Adherence to generally accepted design practices is essential to minimize noise levels on power
and ground planes. Up to 50 mV of noise is considered acceptable. 50 to 80 mV of noise is
considered marginal. High-frequency switching noise can be reduced, and its effects can be
eliminated, by following these simple guidelines throughout the design:
• Fill in unused areas of the signal planes with solid copper and attach them with vias to a VCC
or ground plane that is not located adjacent to the signal layer.
• Use ample bulk and decoupling capacitors throughout the design (a value of .01 µF is
recommended for decoupling caps).
•
•
•
•
•
•
Provide ample power and ground planes.
Provide termination on all high-speed switching signals and clock lines.
Provide impedance matching on long traces to prevent reflections.
Route high-speed signals next to a continuous, unbroken ground plane.
Filter and shield DC-DC converters, oscillators, etc.
Do not route any digital signals between the LXT970A and the RJ-45 connectors at the edge of
the board.
• Do not extend any circuit power and ground plane past the center of the magnetics or to the
edge of the board. Use this area for chassis ground, or leave it void.
3.3.2
Power Supply Filtering
Power supply ripple and digital switching noise on the VCC plane can cause EMI problems and
degrade line performance. It is generally difficult to predict in advance the performance of any
design, although certain factors greatly increase the risk of having these problems:
• Poorly-regulated or over-burdened power supplies.
• Wide data busses (>32-bits) running at a high clock rate.
• DC-to-DC converters.
Many of these issues can be improved by following good general design guidelines. Intel also
recommends filtering between the power supply and the analog VCC pins of the LXT970A.
Filtering has two benefits. First, it keeps digital switching noise out of the analog circuitry inside
the LXT970A, which helps line performance. Second, if the VCC planes are laid out correctly, it
keeps digital switching noise away from external connectors, reducing EMI problems.
42
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
The recommended implementation is to divide the VCC plane into two sections. The digital
section supplies power to the digital VCC pin, VCCIO pin, and to the external components. The
analog section supplies power to VCCA, VCCT, and VCCR pins of the LXT970A. The break
between the two planes should run under the device. In designs with more than one LXT970A, a
single continuous analog VCC plane can be used to supply them all.
The digital and analog VCC planes should be joined at one or more points by ferrite beads. The
beads should produce at least a 100Ω impedance at 100 MHz. The beads should be placed so that
current flow is evenly distributed. The maximum current rating of the beads should be at least
150% of the current that is actually expected to flow through them. A bulk cap (2.2 -10 µF) should
be placed on each side of each ferrite bead to stop switching noise from traveling through the
ferrite.
In addition, a high-frequency bypass cap (.01µf) should be placed near each analog VCC pin.
3.3.3
Ground Noise
The best approach to minimize ground noise is strict use of good general design guidelines and by
filtering the VCC plane.
3.3.4
Power and Ground Plane Layout Considerations
Great care needs to be taken when laying out the power and ground planes. The following
guidelines are recommended:
• Follow the guidelines in the LXT970 Layout Guide for locating the split between the digital
and analog VCC planes.
• Keep the digital VCC plane away from the TPOP/N and TPIP/N signals, away from the
magnetics, and away from the RJ-45 connectors.
• The ground plane should be one continuous, unbroken plane.
• Place the layers so that the TPOP/N and TPIP/N signals can be routed near or next to the
ground plane. It is more important to shield TPOP/N than TPIP/N for EMI reasons.
3.3.5
Interfaces for Twisted-Pair /Fiber
3.3.5.1
Twisted-Pair
Figure 21 on page 46 shows the recommended termination circuits for the fiber and twisted-pair
interfaces. The twisted-pair interface consists of magnetics and a 100Ω termination resistance in
parallel on the device-side of the winding. On the transmit pair, a common-mode bypass capacitor
to ground is strongly recommended. A similar technique on the receive side can improve
performance in some cases, however the results are highly application specific and must be
verified. Route TREF nearby, but not in-between TPOP and TPON. A “Bob Smith” termination is
often provided for the unused signal pairs.
Datasheet
43
LXT970A — Dual-Speed Fast Ethernet Transceiver
3.3.5.2
Fiber
The fiber interface consists of a pseudo-ECL transmit and receive pair to an external fiber optic
transceiver. The transmit pair should be AC-coupled to the transceiver, and biased to 3.7V with a
50Ω equivalent impedance. The receive pair can be DC-coupled, and should be biased to 3.0V with
a 50Ω equivalent impedance. Figure 21 on page 46 shows the correct bias networks to achieve
these requirements.
The following guidelines apply to when laying out any differential pair:
•
•
•
•
•
Space both members close together allowing nothing to come between them.
Keep distances as short as possible, both traces should have the same length.
Avoid layer changes as much as possible.
Keep termination circuits close together and on the same side of the board.
Always put termination circuits close to the source end of any circuit.
3.3.6
Interface for the MII
3.3.6.1
Transmit Hold Time Adjustment
Transmit hold time for TXD, TX_EN, and TX_ER from TX_CLK High is currently specified in
Table 32, Table 34, Table 36, and Table 38 as 5 ns minimum. 0 ns minimum is the IEEE
specification. Depending on the specification of the MAC or ASIC used in your design, you may or
may not need to account for this in your PC board design.
If you determine that a timing adjustment is required, there are a couple of recommended ways to
do this.
• If using series resistors in the TXD lines, increase the value of the resistors to achieve the
necessary delay.
• An alternative method is to add the appropriate delay in the TX_CLK line. Depending on the
amount of delay required, this may be accomplished with a series resistor or by adding a buffer
to the TX_CLK line.
Note that some delay is introduced by the actual PC board traces themselves.
3.3.6.2
MII Terminations
When the LXT970A is configured with high-strength MII driver levels (bit 17.3 = 0), 55Ω series
termination resistors are recommended on all MII output signals to avoid undershoot and
overshoot.
When 17.3 = 1, the MI driver levels are reduced by a factor of ten and termination resistors are not
required on the MII outputs.
44
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
3.3.7
Typical Application
Figure 21 on page 46 is typical interface circuitry of the LXT970A. The diagram groups similar
pins; it does not portray the actual chip pinout. The Media Independent Interface (MII) pins are at
the upper left. Hardware Control Interface pins are center left. The line interface pins for twistedpair and fiber are shown on the top and bottom right respectively.
The VCCD and VCCIO pins are at the bottom of the diagram. VCCT, VCCR, and VCCA are at the
center right. All VCC pins (except VCCIO) use a single power supply. VCCIO may be powered by
a 3.3V supply, and may be separately connected.
3.3.7.1
Voltage Divider For MF Inputs
The LXT970A requires an external voltage divider to provide optional (VMF2 and VMF3) multilevel inputs to the Multi-Function (MF) pins. These voltage levels are designated as VMF1 - VMF4.
A single voltage divider may be used to drive the MF pins in designs using multiple PHYs. Figure
20 shows a voltage divider with three 1 kΩ resistors configured in series between VCC and
Ground.
Figure 20. Voltage Divider
1kW
1kW
1kW
+5V
VMF1
Datasheet
VMF2
VMF3
VMF4
45
LXT970A — Dual-Speed Fast Ethernet Transceiver
Figure 21. Typical Interface Circuitry
1
GNDD
C1
XI
XO
TXD<4:0>
MII
Data
I/F
55Ω
55Ω
55Ω
7
55Ω
55Ω
MII
Control
I/F
6
50 Ω
5
50 Ω
4
RX_ER
RX_CLK
3
50 Ω
1%
RX_DV
75 Ω
1
50 Ω
1%
RXD<4:0>
TRSTE
TPOP
CRS
TREF
0.001µF/2kV
4
.01µF
.01µF
VCCD
VCCA
VCCT
10µF
.01µF
GNDT
VCCA
22.1k Ω 1%
GNDD
.01µF
GNDR
VCCT +5 V
RESET
PWRDWN
.01 mF
.01µF
LEDS
69 W
69 W
GNDA
FIBON
LEDR
TD
TD
FIBOP
LEDT
.01µF
LEDL
191 W
LEDC
GNDA
191 W
VCCR Fiber Txcvr
+5 V
+
10µF
+5 V
80 W
80 W
GNDA
FIBIP
VCCD
GNDIO TEST
3
.01 mF
FIBIN
GNDD
.01 mF
5
VCCIO
.01 m F
+5 V
10µF
.01µF
CFG<1:0>
+3.3V
or
+5V
+
VCCR
MF<4:0>
330 W
Ferrite Bead
GNDA
FDE
330 W
+
GNDA
RBIAS
+5 V
2
LXT970A
MDDIS
330 W
50 Ω
TPON
COL
MDC
330 W
50 Ω
7
TPIP
FDS/MDINT
330 W
50 Ω
TPIN
MDIO
H/W
Control
I/F
8
75 Ω
50 Ω
1%
TX_CLK
RJ45
50 Ω
2
50 Ω
1%
TX_ER
55Ω
55Ω
GNDR
.01µF
To Fiber Network
TX_EN
6
C2
25.0 MHz
To Twisted-Pair Network
GNDD
RD
RD
130 W
130 W
GNDA
1. Refer to Table 19 and Table 20 for crystals.
2. Refer to Table 18 for magnetics.
3. Refer to fiber transceiver manufacturers recommendations for termination circuitry. Suitable fiber transceivers include:
HFBR-5103 and HFBR-5105.
4. Bypassing to chassis ground (if available) provides additional EMI shielding.
5. If the fiber interface is not used, FIBIN, FIBIP, FIBON, and FIBOP may be left unconnected.
6. Placement of this cap should be verified for each application. This cap typically reduces error rates at long line lengths but
is implementation specific.
7. If bit 17.3 = 0, series terminations resistors are recommended for all MII outputs. The proper value is application specific.
If bit 17.3 = 1, termination resistors are not required.
46
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
4.0
Test Specifications
Note:
Table 21 through Table 43 and Figure 22 through Figure 36 represent the performance
specifications of the LXT970A. These specifications are guaranteed by test except where noted “by
design.” Minimum and maximum values listed in Table 23 through Table 43 apply over the
recommended operating conditions specified in Table 22.
Table 21. Absolute Maximum Ratings
Parameter
Sym
Min
Max
Units
Supply Voltage
VCC
-0.3
6
V
Ambient
TOPA
-15
+85
ºC
Case
TOPC
–
+120
ºC
TST
-65
+150
ºC
Operating Temperature
Storage Temperature
Caution:
Exceeding these values may cause permanent damage. Functional operation under these
conditions is not implied. Exposure to maximum rating conditions for extended periods may
affect device reliability.
Table 22. Operating Conditions
Sym
Min
Typ1
Max
Units
VCC
4.75
5.0
5.25
V
MII Supply
VCCIO
3.125
–
5.25
V
Ambient
TOPA
0
–
70
ºC
Case
Parameter
Recommended Supply Voltage2
Except MII Supply
Recommended Operating Temperature
Power Consumption
(+5V Only)
TOPC
0
–
110
ºC
100BASE-TX
ICC
–
170
–
mA
100BASE-FX
ICC
–
80
–
mA
10BASE-T
ICC
–
185
–
mA
Power-Down Mode
ICC
–
9
–
mA
Auto-Negotiation
ICC
–
240
270
mA
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. Voltages with respect to ground unless otherwise specified.
Datasheet
47
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 23. Digital I/O Characteristics1
Parameter
Symbol
Min
Typ
Max
Units
Test Conditions
Input Low Voltage3
VIL
–
–
.8
V
Input High Voltage3
VIH
2.0
–
–
V
II
-10
–
10
µA
0.0 < VI < VCC
Output Low Voltage
VOL
–
–
0.4
V
IOL = 4 mA
Output High Voltage (MII only)
VOH
2.2
–
–
V
IOH = -4 mA, VCCIO =3.3V
Output High Voltage
VOH
2.4
–
–
V
IOH = -4 mA, VCCIO =5.0V
RO
2,4
6.0
–
25.0
Ω
VCCIO = 3.3V
RO
2,4
6.0
–
25.0
Ω
VCCIO = 5.0V
Input Current
MII Driver Output Resistance
(Line Driver Output Enabled)
1.
2.
3.
4.
Applies to all pins except MF<4:0> pins. Refer to Table 24 for MF pin I/O Characteristics.
Parameter is guaranteed by design and not subject to production testing.
Does not apply to XI or TX_CLK pins. Refer to Table 25 for clock input levels.
Applies to default MII driver level (bit 17.3= 0).
Table 24. Digital I/O Characteristics - MultiFunction Pins MF<4:0>
Symbol
Min
Typ1
Max
Units
Input Voltage Level 1
VMF1
VCC - 0.5
–
–
V
Input Voltage Level 2
VMF2
(VCC/2) + 0.5
–
VCC - 1.2
V
Input Voltage Level 3
VMF3
1.2
–
VCC/2 - 0.5
V
Input Voltage Level 4
VMF4
–
–
0.5
V
Parameter
Test Conditions
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
Table 25. Required Clock Characteristics
Parameter
Sym
Min
Typ1
Max
Units
Test Conditions
Master Clock Mode - External XI Clock Input
Input Low Voltage
2
VIL
–
–
1.0
V
VIH
3.2
–
–
V
∆f
–
–
± 100
ppm
Input Clock Duty Cycle2
Tdc
40
–
60
%
Input Capacitance (XI and XO)
CIN
–
3.0
–
pF
Input High Voltage
2
Input Clock Frequency Tolerance2
Clock frequency is 25
MHz or 2.5 MHz
Slave Clock Mode - External TX_CLK Input
Input Low Voltage
VIL
–
–
.8
V
Input High Voltage
VIH
2.0
–
–
V
Input Clock Frequency Tolerance2
∆f
–
–
± 100
ppm
Tdc
35
–
65
%
Input Clock Duty Cycle2
Clock frequency is 25
MHz or 2.5 MHz
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. Parameter is guaranteed by design; not subject to production testing.
48
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 26. Low Voltage Fault Detect Characteristics
Sym
Min
Typ1
Max
Units
Test Conditions
Detect Fault Threshold
VLT
3.4
–
4.0
V
–
Clear Fault Threshold
VLH
4.1
–
4.7
V
–
Parameter
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
Table 27. 100BASE-TX Transceiver Characteristics
Sym
Min
Typ1
Max
Units
Test Conditions
Peak Differential Output Voltage
VOP
0.95
–
1.05
V
Note 2
Signal Amplitude Symmetry
Vss
98
–
102
%
Note 2
Signal Rise/Fall Time
TRF
3.0
–
5.0
ns
Note 2
Rise/Fall Time Symmetry
TRFS
–
–
0.5
ns
Note 2
Duty Cycle Distortion
DCD
–
–
± 0.5
ns
Offset from 16ns
pulse width at 50% of
pulse peak
Overshoot/Undershoot
VOS
–
–
5
%
–
Parameter
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. Measured at the line side of the transformer, line replaced by 100Ω (±1%) resistor.
Table 28. 100BASE-FX Transceiver Characteristics
Parameter
Sym
Min
Typ1
Max
Units
Test Conditions
Transmitter
Peak Differential Output Voltage
(Single Ended)
VOP
0.6
–
1.0
V
–
Signal Rise/Fall Time
TRF
–
–
1.6
ns
10 <–> 90%
2.0 pF load
–
–
–
1.3
ns
–
Jitter (Measured Differentially)
Receiver
Peak Differential Input Voltage
Common-Mode Input Range
VIP
0.55
–
1.5
V
–
VCMIR
2.25
–
VCC - 0.5
V
–
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
Datasheet
49
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 29. 10BASE-T Transceiver Characteristics
Parameter
Sym
Min
Typ1
Max
Units
Test Conditions
Transmitter
Peak Differential
Output Voltage
VOP
2.2
2.5
2.8
V
With transformer, line
replaced by 100Ω (±1%)
resistor
–
0
2
11
ns
After line model specified by
IEEE 802.3 for 10BASE-T
MAU
Transmit Timing Jitter added by the
MAU and PLS Sections2,3
Receiver
Receive Input Impedance2
ZIN
–
3.6
–
kΩ
Between TPIP/TPIN
Differential Squelch Threshold
VDS
300
420
585
mV
5 MHz square wave input
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. Parameter is guaranteed by design; not subject to production testing.
3. IEEE 802.3 specifies maximum jitter additions at 1.5 ns for the AUI cable, 0.5ns from the encoder, and 3.5ns from the MAU.
Table 30. 10BASE-T Link Integrity Timing Characteristics
Sym
Min
Typ1
Max
Time Link Loss Receive
TLL
50
64
150
ms
–
Link Pulse
TLP
2
4
7
Link Pulses
–
Link Min Receive Timer
TLR MIN
2
4
7
ms
–
Link Max Receive Timer
TLR MAX
50
64
150
ms
–
Tlt
8
10
24
ms
–
Tlpw
–
100
–
ns
–
Parameter
Link Transmit Period
Link Pulse Width
Units
Test Conditions
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
50
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Figure 22. MII - 100BASE-TX Receive Timing / 4B Mode
0ns
250ns
TPIP
t1D
t1E
CRS
TRSTE1
t1H
t1C
RX_DV
t1A
t1B
RXD<3:0>
RX_CLK
t1F
t1G
COL
Table 31. MII - 100BASE-TX Receive Timing Parameters / 4B Mode
Sym
Min
Typ1
Max
Units3
RXD, RX_DV, RX_ER Setup to RX_CLK High
t1A
10
–
–
ns
RXD, RX_DV, RX_ER Hold from RX_CLK High
t1B
10
–
–
ns
CRS asserted to RXD<3:0>, RX_DV asserted
t1C
–
8
–
BT
Receive start of “J” to CRS asserted
t1D
0
15 - 19
20
BT
Receive start of “T” to CRS de-asserted
t1E
13
23 - 27
28
BT
Receive start of “J” to COL asserted
t1F
0
15 - 19
20
BT
Receive start of “T” to COL de-asserted
t1G
13
23 - 27
28
BT
TRSTE asserted to RX_DV, RXD<3:0> driven2
t1H
–
20
–
ns
Parameter
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. These parameters apply only when the device is operated in Repeater Mode.
3. BT is the duration of one bit as transferred to and from the MAC and is the reciprocal of the bit rate. 100BASE-T bit time = 108
s or 10 ns.
Datasheet
51
LXT970A — Dual-Speed Fast Ethernet Transceiver
Figure 23. MII - 100BASE-TX Transmit Timing / 4B Mode
0ns
250ns
t2A
TXCLK
TX_EN
t2B
TXD<3:0>
t2E
TPOP
t2D
t2C
CRS
Table 32. MII - 100BASE-TX Transmit Timing Parameters / 4B Mode
Sym
Min
Typ1
Max
Units2
TXD<3:0>, TX_EN, TX_ER Setup to TX_CLK High
t2A
10
–
–
ns
TXD<3:0>, TX_EN, TX_ER Hold from TX_CLK High
t2B
5
–
–
ns
TX_EN sampled to CRS asserted
t2C
–
3
4
BT
TX_EN sampled to CRS de-asserted
t2D
–
4
16
BT
TX_EN sampled to TPO out (Tx latency)
t2E
6
10
14
BT
Parameter
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. BT is the duration of one bit as transferred to and from the MAC and is the reciprocal of the bit rate. 100BASE-T bit time = 108
s or 10 ns.
52
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Figure 24. MII - 100BASE-TX Receive Timing / 5B Mode
0ns
250ns
TPIP
t3E
t3F
Note
2
CRS
TRSTE1
t3I1
t3C
RX_DV
t3D
t3A
t3B
RXD<4:0>
RX_CLK
t3G
t3H
COL
1. This parameter applies only when the device is operated in Repeater Mode.
2. In Repeater Mode, application circuit must assert TRSTE within time period specified by t4 - t10.
Table 33. MII - 100BASE-TX Receive Timing Parameters / 5B Mode
Sym
Min
Typ1
Max
Units3
RXD, RX_DV, RX_ER Setup to RX_CLK High
t3A
10
–
–
ns
RXD, RX_DV, RX_ER Hold from RX_CLK High
t3B
10
–
–
ns
CRS asserted to RX_DV asserted
t3C
–
8
–
BT
CRS asserted to RXD<4:0> asserted
t3D
–
4
–
BT
Receive start of “J” to CRS asserted
t3E
0
15 - 19
20
BT
Receive start of “T” to CRS de-asserted
t3F
13
23 - 27
28
BT
Receive start of “J” to COL asserted
t3G
0
15 - 19
20
BT
Receive start of “T” to COL de-asserted
t3H
13
23 - 27
28
BT
t3I
–
20
–
ns
Parameter
TRSTE asserted to RX_DV, RXD<4:0> driven
2
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. These parameters apply only when the device is operated in Repeater Mode.
3. BT is the duration of one bit as transferred to and from the MAC and is the reciprocal of the bit rate. 100BASE-T bit time = 108
s or 10 ns.
Datasheet
53
LXT970A — Dual-Speed Fast Ethernet Transceiver
Figure 25. 100BASE-TX Transmit Timing / 5B Mode
0ns
250ns
t4A
TXCLK
TX_EN
t4B
TXD<3:0>
t4E
TPOP
t4D
t4C
CRS
Table 34. MII - 100BASE-TX Transmit Timing Parameters / 5B Mode
Parameter
Sym
Min
Typ1
Max
Units2
TXD, TX_EN, TX_ER Setup to TX_CLK High
t4A
10
–
–
ns
TXD, TX_EN, TX_ER Hold from TX_CLK High
t4B
5
–
–
ns
TX_EN sampled to CRS asserted
t4C
–
3
4
BT
TX_EN sampled to CRS de-asserted
t4D
–
4
16
BT
TX_EN sampled to TPO out (Tx latency)
t4E
4
6
9
BT
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. BT is the duration of one bit as transferred to and from the MAC and is the reciprocal of the bit rate. 100BASE-T bit time = 108
s or 10 ns.
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Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Figure 26. MII - 100BASE-FX Receive Timing / 4B Mode
0ns
250ns
FIBIP
t5D
Note
2
t5E
CRS
TRSTE1
t5H1
t5C
RX_DV
t5A
t5B
RXD<3:0>
RX_CLK
t5F
t5G
COL
1. These parameters apply only when the device is operated in Repeater Mode.
2. In Repeater Mode, application circuit must assert TRSTE within time period specified by t4 - t10.
Table 35. MII - 100BASE-FX Receive Timing Parameters / 4B Mode
Sym
Min
Typ1
Max
Units3
t5A
10
–
–
ns
RXD, RX_DV, RX_ER Hold from RX_CLK High
t5B
10
–
–
ns
CRS asserted to RXD<3:0>, RX_DV asserted
t5C
–
8
–
BT
Receive start of “J” to CRS asserted
t5D
0
13 - 17
20
BT
Receive start of “T” to CRS de-asserted
t5E
13
21 - 25
26
BT
Parameter
RXD, RX_DV, RX_ER Setup to RX_CLK High
Receive start of “J” to COL asserted
t5F
0
13 - 17
20
BT
Receive start of “T” to COL de-asserted
t5G
13
21 - 25
26
BT
t5H
–
20
–
ns
TRSTE asserted to RX_DV, RXD<3:0> driven
2
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. These parameters apply only when the device is operated in Repeater Mode.
3. BT is the duration of one bit as transferred to and from the MAC and is the reciprocal of the bit rate. 100BASE-T bit time = 108
s or 10 ns.
Datasheet
55
LXT970A — Dual-Speed Fast Ethernet Transceiver
Figure 27. MII - 100BASE-FX Transmit Timing / 4B Mode
0ns
250ns
t6A
TXCLK
TX_EN
t6B
TXD<3:0>
t6E
FIBOP
t6D
t6C
CRS
Table 36. MII - 100BASE-FX Transmit Timing Parameters / 4B Mode
Sym
Min
Typ1
Max
Units2
TXD<3:0>, TX_EN, TX_ER Setup to TX_CLK High
t6A
10
–
–
ns
TXD<3:0>, TX_EN, TX_ER Hold from TX_CLK High
t6B
5
–
–
ns
Parameter
TX_EN sampled to CRS asserted
t6C
–
3
4
BT
TX_EN sampled to CRS de-asserted
t6D
–
4
16
BT
TX_EN sampled to TPO out (Tx latency)
t6E
6
11
14
BT
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. BT is the duration of one bit as transferred to and from the MAC and is the reciprocal of the bit rate. 100BASE-T bit time = 108
s or 10 ns.
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Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Figure 28. MII - 10BASE-T Receiving Timing
RX_CLK
t7A t7B
t7C
RXD,
RX_DV,
RX_ER
t7E
t7D
CRS
t7F
t7G
TPI
t7I
t7H
COL
Table 37. MII - 10BASE-T Receive Timing Parameters
Sym
Min
Typ1
Max
Units2
RXD, RX_DV, RX_ER Setup to RX_CLK High
t7A
10
–
–
ns
RXD, RX_DV, RX_ER Hold from RX_CLK High
t7B
10
–
–
Parameter
TPI in to RXD out (Rx latency)
t7C
–
–
ns
73
3
3
BT
CRS asserted to RXD, RX_DV, RX_ER asserted
t7D
0
–
69
RXD, RX_DV, RX_ER de-asserted to CRS de-asserted
t7E
0
2.5 - 5.5
6
BT
TPI in to CRS asserted
t7F
0
4
5
BT
TPI quiet to CRS de-asserted
t7G
0
18
19
BT
TPI in to COL asserted
t7H
0
4
5
BT
TPI quiet to COL de-asserted
t7I
0
18
19
BT
BT
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. BT is the duration of one bit as transferred to and from the MAC and is the reciprocal of the bit rate. 10BASE-T bit time = 107
s or 100 ns.
3. CRS is asserted. RXD/RX_DV are driven at the start of SFD (64 BT).
Datasheet
57
LXT970A — Dual-Speed Fast Ethernet Transceiver
Figure 29. MII - 10BASE-T Transmit Timing
TX_CLK
t8B
t8A
TXD,
TX_EN,
TX_ER
t8E
t8C
CRS
t8D
TPO
Table 38. MII - 10BASE-T Transmit Timing Parameters
Sym
Min
Typ1
Max
Units2
TXD, TX_EN, TX_ER Setup to TX_CLK High
t8A
10
–
–
ns
TXD, TX_EN, TX_ER Hold from TX_CLK High
t8B
5
–
–
ns
TX_EN sampled to CRS asserted
t8C
–
0
4
BT
TX_EN sampled to CRS de-asserted
t8D
–
8
–
BT
TX_EN sampled to TPO out (Tx latency)
t8E
–
3-5
–
BT
Parameter
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. BT is the duration of one bit as transferred to and from the MAC and is the reciprocal of the bit rate. 10BASE-T bit time = 107
s or 100 ns.
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Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Figure 30. 10BASE-T SQE (Heartbeat) Timing
TX_CLK
TX_EN
t9A
t9B
COL
Table 39. 10BASE-T SQE (Heartbeat) Timing Parameters
Sym
Min
Typ1
Max
Units
COL (SQE) Delay after TX_EN off
t9A
0.65
1.0
1.6
µs
COL (SQE) Pulse duration
t9B
.5
1.0
1.5
µs
Parameter
Test Conditions
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
Figure 31. 10BASE-T Jab and Unjab Timing
TX_EN
t10A
TXD
t10B
COL
Table 40. 10BASE-T Jab and Unjab Timing Parameters
Sym
Min
Typ1
Maximum Transmit time
t10A
20
96 - 1282
150
ms
Unjab time
t10B
250
525
750
ms
Parameter
Max
Units
Test Conditions
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
2. Typical transmit time may be either of these values depending on internal 32 ms clock synchronization.
Datasheet
59
LXT970A — Dual-Speed Fast Ethernet Transceiver
Figure 32. Auto Negotiation and Fast Link Pulse Timing
Clock Pulse
Data Pulse
t1
t1
Clock Pulse
TPOP
t2
t3
Figure 33. Fast Link Pulse Timing
FLP Burst
FLP Burst
TPOP
t4
t5
Table 41. Auto Negotiation and Fast Link Pulse Timing Parameters
Sym
Min
Typ1
Max
Units
t1
–
100
–
ns
Clock pulse to Data pulse
t2
55.5
62.5
69.5
µs
Clock pulse to Clock pulse
t3
111
125
139
µs
FLP burst width
t4
–
2
–
ms
FLP burst to FLP burst
t5
8
12
24
ms
Clock/Data pulses per burst
–
17
–
33
ea
Parameter
Clock/Data pulse width
Test Conditions
1. Typical values are at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
60
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Figure 34. MDIO Timing when Sourced by STA
MDC
10 ns
10 ns
(Min)
(Min)
MDIO
Figure 35. MDIO Timing when Sourced by PHY
MDC
0 - 300 ns
MDIO
Table 42. MDIO Timing Parameters
Sym
Min
Typ1
Max
Units
Test Conditions
MDIO Setup before MDC
–
10
–
–
ns
When sourced by
STA
MDIO Hold after MDC
–
10
–
–
ns
When sourced by
STA
MDC to MDIO Output delay
–
0
10
300
ns
When sourced by
PHY
Parameter
1. Typical values are at 25° C and are for design aid only; not guaranteed and not subject to production testing.
Datasheet
61
LXT970A — Dual-Speed Fast Ethernet Transceiver
Figure 36. Power-Down Recovery Timing (Over Recommended Range)
VCC = 4.75V
VCC
tHR
RESET
tPDR
MDIO,etc
Table 43. Power-Down Recovery Timing Parameters
Sym
Min
Typ1
Max
Units
Power-Down recovery time
tPDR
–
1.0
–
ms
Hardware reset time
tHR
–
300
–
µs
Parameter
Test Conditions
1. Typical values are at 25° C and are for design aid only; not guaranteed and not subject to production testing.
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Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
5.0
Register Definitions
The LXT970A register set includes a total of twelve 16-bit registers. Refer to Table 44 for a
complete register listing.
• Seven base registers (0 through 6) are defined in accordance with the “Reconciliation Sublayer
and Media Independent Interface” and “Physical Layer Link Signalling for 10/100 Mbps
Auto-Negotiation” sections of the IEEE 802.3 specification (Register 7, Next Page, is not
supported).
• Five additional registers (16 through 20) are defined in accordance with the IEEE 802.3
specification for adding unique chip functions.
Table 44. Register Set
Address
Register Name
Bit Assignments
0
Control Register
Refer to Table 45 on page 64
1
Status Register
Refer to Table 46 on page 65
2
PHY Identification Register 1
Refer to Table 47 on page 66
3
PHY Identification Register 2
Refer to Table 48 on page 66
4
Auto-Negotiation Advertisement Register
Refer to Table 49 on page 67
5
Auto-Negotiation Link Partner Ability Register
Refer to Table 50 on page 68
6
Auto-Negotiation Expansion Register
Refer to Table 51 on page 69
16
Mirror Register
Refer to Table 52 on page 69
17
Interrupt Enable Register
Refer to Table 53 on page 70
18
Interrupt Status Register
Refer to Table 54 on page 70
19
Configuration Register
Refer to Table 55 on page 71
20
Chip Status Register
Refer to Table 56 on page 72
Datasheet
63
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 45. Control Register (Address 0)
Bit
Name
Description
Type 1
Default
R/W
Reset
1 = Reset chip.
0 = Enable normal operation.
0.14
Loopback
1 = Enable loopback mode. When Loopback is enabled, during 100
Mbps operation, the LXT970A disconnects its transmitter and receiver
from the network. Data sent by the controller passes through the chip
and then gets looped back to the MII. During 10 Mbps operation the
preamble, SFD, and data loop directly back to the MII.
0 = Disable loopback mode.
R/W
0
0.13
Speed
Selection
1 = 100 Mbps
0 = 10 Mbps
R/W
Note 2
0.12
AutoNegotiation
Enable
1 = Enable auto-negotiate process (overrides speed select and duplex
mode bits).
0 = Disable auto-negotiate process.
R/W
Note 3
0.11
Power Down
1 = Enable power down.
0 = Enable normal operation.
R/W
Note 4
0.10
Isolate
1 = Electrically isolate LXT970A from MII.
0 = Normal operation.
R/W
Note 5
0.9
Restart AutoNegotiation
1 = Restart auto-negotiation process.
0 = Normal operation.
0.8
Duplex Mode
1 = Enable full-duplex.
0 = Enable half-duplex.
R/W
0.7
Collision Test
1 = Enable COL signal test. Bit 0.14 must be enabled to use this bit.
This bit is used in conjunction with bit 0.14 to test the COL output.
0 = Disable COL signal test.
R/W
0.6:4
Transceiver
Test Mode
Not Supported.
RO
0
0.3
Master-Slave
Enable
Not Supported.
RO
0
0.2
Master-Slave
Value
Not Supported.
RO
0
0.1:0
Reserved
R/W
0
0.15
0
SC
R/W
Note 6
SC
Note 7
0
Note
8
1. R/W = Read/Write
SC = Self Clearing
2. If auto-negotiation is enabled, this bit is ignored. If auto-negotiation is disabled, the default value of bit 0.13 is determined by
pin CFG0.
3. The default value of bit 0.12 is determined by pin MF0.
4. The LXT970A internally maintains all set values of the configuration registers upon exiting power-down mode. A delay of 500
ns minimum is required from the time power down is cleared until any register can be written.
5. The default value of bit 0.10 is determined by pin TRSTE.
6. If auto-negotiation is enabled, the default value of bit 0.9 is determined by pin CFG0. If auto-negotiation is disabled, the
default value of
bit 0.9 = 0.
7. If auto-negotiation is enabled, this bit is ignored. If auto-negotiation is disabled, the default value of bit 0.8 is determined by
pin FDE.
8. This bit is ignored unless loopback is enabled (0.14 = 1).
64
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 46. Status Register (Address 1)
Bit
1.15
1.14
1.13
1.12
1.11
1.10
1.9
Type 1
Default
Not Supported.
RO
0
1 = LXT970A able to perform full-duplex 100BASE-X.
RO
1
1 = LXT970A able to perform half-duplex 100BASE-X.
RO
1
1 = LXT970A able to operate at 10 Mb/s in full-duplex mode.
RO
1
1 = LXT970A able to operate at 10 Mb/s in half-duplex mode.
RO
1
Not Supported.
RO
0
Not Supported.
RO
0
Name
100BASE-T4
100BASE-X
full-duplex
100BASE-X
half-duplex
10 Mb/s
full-duplex
10 Mb/s
half-duplex
100BASE-T2
full-duplex
100BASE-T2
half-duplex
Description
1.8
Reserved
Ignore on read.
RO
0
1.7
Master-Slave
Configuration
Fault
Not Supported.
RO
0
1.6
MF Preamble
Suppression
0 = LXT970A will not accept management frames with preamble
suppressed.
RO
0
1.5
Auto-Neg.
Complete
1 = Auto-negotiation process complete.
RO
0
RO/LH
0
RO
1
RO/LL
0
RO/LH
0
RO
1
0 = Auto-negotiation process not complete.
1 = Remote fault condition detected.
0 = No remote fault condition detected.
This bit is set when:
1.4
Remote Fault
Link partner transmits a remote fault condition (bit 5.13 = 1)
Link partner protocol is anything other than CSMA-CD
(bits 5.4:0 = <00001>)
Link partner advertises T4 capability only
(bits 5.9:5 ¼ <10000>)
1.3
Auto-Neg.
Ability
1.2
Link Status
Jabber Detect
1.1
1.0
(10BASE-T
Only)
Extended
Capability
1 = LXT970A is able to perform auto-negotiation.
1 = Link is up.
0 = Link is down.
1 = Jabber condition detected.
0 = No jabber condition detected.
1 = Extended register capabilities.
1. RO = Read Only
LL = Latching Low (This bit remains Low until read, and then returns High).
LH = Latching High (This bit remains High until read, and then returns Low).
Datasheet
65
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 47. PHY Identification Register 1 (Address 2)
Bit
2.15:0
Name
PHY ID
Number
Description
Type 1
Default
RO
7810 hex
The PHY identifier composed of bits 3 through 18 of the OUI.
1. RO = Read Only
Table 48. PHY Identification Register 2 (Address 3)
Bit
Name
Description
Type 1
Default
3.15:10
PHY ID number
The PHY identifier composed of bits 19 through 24 of the OUI.
RO
000000 bin
3.9:4
Manufacturer’s
model number
6 bits containing manufacturer’s part number.
RO
000000 bin
3.3:0
Manufacturer’s
revision number
4 bits containing manufacturer’s revision number.
RO
0011 bin
1. RO = Read Only
Figure 37. PHY Identifier Bit Mapping
a b c
r
s
x
Manufacturers
Part Number
Organizationally Unique Identifier
1 2 3
18 19
15 14 13 12 11 10 9
8
7 6
PHY ID Register 1
5
4 3
Revision
2
1
24
Number
5 4 3 2 1 0
0 15 14 13 12 11 10 9
8
7 6
5
3 2 1 0
4 3
2
1
0
PHY ID Register 2
The Intel OUI is 00207B hex.
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Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 49. Auto Negotiation Advertisement Register (Address 4)
Bit
Name
Description
Type 1
Default
4.15
Next Page
Not Supported
RO
0
4.14
Reserved
Ignore on read.
RO
0
4.13
Remote Fault
1 = Remote fault.
0 = No remote fault.
R/W
0
4.12:11
Reserved
Ignore on read.
R/W
0
4.10
Pause
R/W
0
R/W
0
1 = Pause operation is enabled for full-duplex links.
0 = Pause operation is disabled.
1 = 100BASE-T4 capability is available.
0 = 100BASE-T4 capability is not available.
4.9
4.8
4.7
4.6
4.5
100BASE-T4
(The LXT970A does not support 100BASE-T4, but allows this bit to be set
to advertise in the Auto-Negotiation sequence for 100BASE-T4 operation.
An external 100BASE-T4 transceiver could be switched in if this capability
is desired.)
100BASE-TX
1 = DTE is 100BASE-TX full-duplex capable.
0 = DTE is not 100BASE-TX full-duplex capable.
R/W
Note 2
100BASE-TX
1 = DTE is 100BASE-TX capable.
0 = DTE is not 100BASE-TX capable.
R/W
Note 3
10BASE-T
1 = DTE is 10BASE-T full-duplex capable.
full-duplex
0 = DTE is not 10BASE-T full-duplex capable.
R/W
Note 4
R/W
Note 5
R/W
00001
full-duplex
10BASE-T
1 = DTE is 10BASE-T capable.
0 = DTE is not 10BASE-T capable.
<00001> = IEEE 802.3
4.4:0
Selector Field,
S<4:0>
<00010> = IEEE 802.9 ISLAN-16T
<00000> = Reserved for future Auto-Negotiation development
<11111> = Reserved for future Auto-Negotiation development
Unspecified or reserved combinations should not be transmitted.
1. R/W = Read/Write
RO = Read Only
2. The default value of bit 4.8 is determined by pin FDE AND’ed with pin MF4.
3. The default value of bit 4.7 is determined by pin MF4.
4. The default value of bit 4.6 is determined by pin FDE AND’ed with pin CFG1.
5. The default value of bit 4.5 is determined by pin CFG1.
Datasheet
67
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 50. Auto Negotiation Link Partner Ability Register (Address 5)
Bit
Name
5.15
Next Page
5.14
Acknowledge
5.13
Remote Fault
5.12:11
Reserved
5.10
Pause
5.9
100BASE-T4
5.8
5.7
5.6
5.5
Description
1 = Link Partner has ability to send multiple pages.
0 = Link Partner has no ability to send multiple pages.
1 = Link Partner has received Link Code Word from LXT970A.
0 = Link Partner has not received Link Code Word from LXT970A.
1 = Remote fault.
0 = No remote fault.
Ignore on read.
1 = Pause operation is enabled for link partner.
0 = Pause operation is disabled.
1 = Link Partner is 100BASE-T4 capable.
0 = Link Partner is not 100BASE-T4 capable.
100BASE-TX
1 = Link Partner is 100BASE-TX full-duplex capable.
full-duplex
0 = Link Partner is not 100BASE-TX full-duplex capable.
100BASE-TX
1 = Link Partner is 100BASE-TX capable.
0 = Link Partner is not 100BASE-TX capable.
10BASE-T
1 = Link Partner is 10BASE-T full-duplex capable.
full-duplex
0 = Link Partner is not 10BASE-T full-duplex capable.
10BASE-T
1 = Link Partner is 10BASE-T capable.
0 = Link Partner is not 10BASE-T capable.
Type 1
Default
RO
N/A
RO
N/A
RO
N/A
RO
N/A
RO
N/A
RO
N/A
RO
N/A
RO
N/A
RO
N/A
RO
N/A
RO
N/A
<00001> = IEEE 802.3
5.4:0
Selector Field
S[4:0]
<00010> = IEEE 802.9 ISLAN-16T
<00000> = Reserved for future Auto-Negotiation development
<11111> = Reserved for future Auto-Negotiation development
Unspecified or reserved combinations shall not be transmitted.
1. RO = Read Only
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Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 51. Auto Negotiation Expansion (Address 6)
Bit
6.15:5
Name
Description
Type 1
Default
0
Reserved
Ignore.
RO
6.4
Parallel
Detection Fault
1 = Parallel detection fault has occurred.
RO/
0 = Parallel detection fault has not occurred.
LH
6.3
Link Partner
Next Page Able
1 = Link partner is next page able.
6.2
Next Page Able
6.1
Page Received
6.0
Link Partner
Auto Neg Able
0
RO
0
Not Supported.
RO
0
1 = 3 identical and consecutive link code words have been received from
link partner.
RO/
0 = Link partner is not next page able.
0 = 3 identical and consecutive link code words have not been received
from link partner.
1 = Link partner is auto-negotiation able.
LH
0
RO
0
Description
Type 1
Default
This register is intended for use in checking the MII serial port and has no
effect on chip operation.
R/W
0
0 = Link partner is not auto-negotiation able.
1. RO = Read Only
LH = Latching High (This bit remains High until read, and then returns Low).
Table 52. Mirror Register (Address 16, Hex 10)
Bit
16.15:0
Name
User Defined
1. R/W = Read /Write
Datasheet
69
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 53. Interrupt Enable Register (Address 17, Hex 11)
Bit
17.15:4
17.3
Type 1
Default
Write as 0; ignore on read.
R/W
N/A
1 = Reduced MII driver levels. Pull-down strength of the MII driver is
reduced by a factor of 10, and the pull-up strength is reduced by a factor
of 8. Reduced driver levels on the MII I/O pins are recommended for
managed multi-port applications.
R/W
0
R/W
0
R/W
0
R/W
0
Name
Reserved
MIIDRVLVL
Description
0 = High-strength MII driver levels that can effectively source 50 - 60 mA.
Series termination resistors (55Ω) are recommended on all output
signals when using this level to avoid undershoot or overshoot.
LNK
17.2
CRITERIA
1 = Enhanced link loss criteria. Link loss criteria is independent of symbol
error rate. Loss of scrambler lock for more than 1 - 2 msec will brings the
link down. Link up criteria is based on symbol error rate.
0 = Standard link criteria. Both link up and link loss are based on symbol
error rate.
17.1
INTEN
1 = Enable interrupts. Must be enabled for bit 17.0 or 19.12 to be
effective.
0 = Disable interrupts.
1 = Forces MDINT Low and sets bit 18.15 = 1. Also forces interrupt
pulse on MDIO when bit 19.12 = 1.
17.0
TINT
0 = Normal operation.
This bit is ignored unless the interrupt function is enabled (17.1 = 1).
1. R/W = Read /Write
Table 54. Interrupt Status Register (Address 18, Hex 12)
Bit
Name
Description
Type 1
Default
RO
N/A
RO
0
RO
0
1 = Indicates MII interrupt pending.
18.15
MINT
18.14
XTALOK
0 = Indicates no MII interrupt pending. This bit is cleared by reading
Register 1 followed by reading Register 18.
1 = Indicates that the LXT970A is fully powered up and the on-chip clocks
are stable.
0 = Indicates that XTAL circuit is not stable.
18.13:0
Reserved
Ignore
1. RO = Read Only
70
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
Table 55. Configuration Register (Address 19, Hex 13)
Bit
19.15
19.14
Name
Description
Type 1
Default
Reserved
Write as 0; ignore on read.
R/W
N/A
Txmit Test
(100BASE-TX)
1 = 100BASE-T transmit test enabled, LXT970A transmits data
regardless of link status. This function is the analog of the link test
function (19.8) for 100BASE-TX.
R/W
0
R/W
Note 2
R/W
0
R/W
0
R/W
0
R/W
0
R/W
Note 3
R/W
0,0
R/W
0
R/W
Note 4
R/W
Note 5
0 = Normal operation.
19.13
Repeater Mode
19.12
MDIO_INT
1 = Enable Repeater Mode.
0 = Enable DTE Mode.
1 = Enable interrupt signaling on MDIO (if 17.1 = 1).
0 = Normal operation (MDIO Interrupt disabled).
Bit is ignored unless the interrupt function is enabled (17.1 = 1).
19.11
19.10
19.9
19.8
TP Loopback
(10BASE-T)
1 = Disable 10BT TP Loopback. Data transmitted by the MAC will not
loopback to the RXD, RX_DV, and CRS pins.
0 = Enable 10BT TP Loopback - Preamble, SFD, and data are directly
looped back to the MII.
SQE
1 = Enable SQE.
(10BASE-T)
0 = Disable SQE (Default).
Jabber
1 = Disable jabber.
(10BASE-T)
0 = Normal operation (jabber enabled).
Link Test
1 = Disable 10BASE-T link integrity test.
(10BASE-T)
0 = Normal operation (10BASE-T link integrity test enabled).
Determine condition indicated by LEDC.
bit 7 bit 6
19.7:6
19.5
LEDC
Programming bits
Advance TX Clock
Description
0
0
LEDC indicates collision
0
1
LEDC is off
1
0
LEDC indicates activity.
1
1
LEDC is continuously on (for diagnostic use).
1 = TX clock is advanced relative to TXD<4:0> and TX_ER by 1/2
TX_CLK cycle.
0 = Normal operation.
5B Symbol/
19.4
(100BASE-X only)
1 = 5-bit Symbol Mode (Bypass encoder/decoder);
RXD<4:0> symbol data is not aligned.
4B Nibble
0 = 4-bit Nibble Mode (Normal operation).
1 = Bypass transmit scrambler and receive descrambler.
19.3
Scrambler
0 = Normal operation (scrambler and descrambler enabled).
(100BASE-X only)
In FX mode, the LXT970A automatically bypasses the Scrambler.
Selecting Scrambler bypass in FX mode causes the LXT970A to also
bypass the 4B/5B encoder and enable Symbol mode MII operation.
1. R/W = Read/Write
2. The default value of bit 19.13 is determined by pin MF1.
3. If auto-negotiation is disabled, the default value of bit 19.8 is determined by pin CFG1. If auto-neg is enabled, the default
value of bit 19.8 = 0.
4. The default value of bit 19.4 is determined by pin MF2 Operation.
5. The default value of bit 19.3 is determined by pin MF3 Operation.
6. If auto-negotiation is disabled, default value of bit 19.2 is determined by pin MF4. If auto-negotiation is enabled, default value
of bit 19.2 = 0.
Datasheet
71
LXT970A — Dual-Speed Fast Ethernet Transceiver
Table 55. Configuration Register (Address 19, Hex 13) (Continued)
Bit
Name
Description
1 = Enable 100BASE fiber interface.
19.2
100BASE-FX
19.1
Reserved
Write as 0; Ignore on read.
19.0
Transmit
Disconnect
1 = Disconnect TP transmitter from line.
0 = Enable 100BASE twisted-pair interface.
0 = Normal operation.
Type 1
Default
R/W
Note 6
R/W
0
R/W
0
1. R/W = Read/Write
2. The default value of bit 19.13 is determined by pin MF1.
3. If auto-negotiation is disabled, the default value of bit 19.8 is determined by pin CFG1. If auto-neg is enabled, the default
value of bit 19.8 = 0.
4. The default value of bit 19.4 is determined by pin MF2 Operation.
5. The default value of bit 19.3 is determined by pin MF3 Operation.
6. If auto-negotiation is disabled, default value of bit 19.2 is determined by pin MF4. If auto-negotiation is enabled, default value
of bit 19.2 = 0.
Table 56. Chip Status Register (Address 20, Hex 14)
Bit
Name
Description
Type 1
Default
20.15:1
4
Reserved
Ignore on read.
RO
N/A
20.13
Link
1 = Link is up.
0 = Link is down.
Link bit 20.13 is a duplicate of bit 1.2, except that it is a dynamic
indication, whereas bit 1.2 latches Low.
RO
0
20.12
Duplex Mode
1 = Full-duplex.
0 = Half-duplex.
RO
Note 2
20.11
Speed
1 = 100 Mbps operation.
0 = 10 Mbps operation.
RO
Note 2
20.10
Reserved
Ignore on read.
RO
N/A
Auto-Negotiation
Complete
1 = Auto-negotiation process complete.
0 = Auto-negotiation process not complete.
Auto-Negotiation Complete bit 20.9 is a duplicate of bit 1.5.
RO/LH
0
20.8
Page Received
1 = Three identical and consecutive link code words have been
received.
0 = Three identical and consecutive link code words have not been
received.
Page Received bit 20.8 is a duplicate of bit 6.1
RO/LH
0
20:7
Reserved
Ignore on read.
RO
0
20.6
Reserved
Ignore on read.
RO
0
20.5
Reserved
Ignore on read.
RO
N/A
20.4
Reserved
Ignore on read.
RO
N/A
20.3
Reserved
Ignore on read.
RO
N/A
20.2
Low-Voltage
RO
N/A
20.1
Reserved
Ignore on read.
RO
N/A
20.0
Reserved
Ignore on read.
RO
N/A
20.9
1 = Low-voltage fault on VCC has occurred.
0 = No fault.
1. RO = Read Only
LH = Latching High (This bit remains High until read, and then returns Low).
2. Bits 20.12 and 20.11 reflect the current operating mode of the LXT970A.
72
Datasheet
Dual-Speed Fast Ethernet Transceiver — LXT970A
6.0
Mechanical Specifications
Figure 38. 64-Pin QFP Package Diagram
64-Pin Quad Flat Pack
• Part Number - LXT970AQC
• Commercial Temperature Range (0 to +70ºC)
D
D1
D3
Millimeters
Dim
e
E3
E1
e/
2
E
Min
Max
A
–
3.30
A1
0.000
0.25
A2
2.55
3.05
B
0.30
0.45
D
17.65
18.15
D1
13.95
14.05
D3
θ3
L1
E
17.65
18.15
E1
13.95
14.05
E3
12.00 REF
e
0.80 BSC
L
A2
A
θ3
L
Datasheet
0.73
1.03
1.95 REF
L1
θ
A1
12.00 REF
θ3
5°
16°
θ
0°
7°
B
73
LXT970A — Dual-Speed Fast Ethernet Transceiver
Figure 39. 64-Pin TQFP Package Diagram
64-Pin Thin Quad Flat Pack
• Part Number - LXT970ATC
• Commercial Temperature Range (0 to +70ºC)
D
D1
Millimeters
Dim
Min
Max
A
–
1.20
A1
0.05
0.15
A2
0.95
1.05
B
0.17
0.27
D
12.0 REF
D1
10.0 REF
E
12.0 REF
E1
10.0 REF
e
0.50 REF
L
0.45
θ
e e/
2
0.75
11o
0
o
13o
7o
1. Basic Spacing between Centers.
θ3
L1
A2
A
A1
L
74
E
1.00 REF
L1
θ3
E1
B
θ
θ3
Datasheet
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