AGERE LU3X34FTR

Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Overview
The LU3X34FTR is a fully integrated, 4-port
10/100 Mbits/s physical layer device with an integrated transceiver. This part was designed specifically for 10/100 Mbits/s switches. These applications
typically require stringent functionality in addition to
very tight board space, power, and cost requirements. The LU3X34FTR supports RMII and SMII
interfaces, offering the designer multiple reduced pin
count interfaces to save both real estate and cost in
system design. The LU3X34FTR was designed from
the beginning to conform fully with all pertinent specifications, from the ISO 1/ IEC 2 11801 and EIA 3/TIA
568 cabling guidelines to ANSI 4 X3.263TP-PMD to
IEEE 5 802.3 Ethernet specifications.
■
FX mode configurable on a per-port basis.
■
Built-in analog 10 Mbit receive filter, removing the
need for external filters.
■
Built-in 10 bit transmit filter.
■
10 Mbit PLL, exceeding tolerances for both
preamble and data jitter.
■
100 Mbit PLL, combined with the digital adaptive
equalizer, robustly handles variations in rise-fall
time, excessive attenuation due to channel loss,
duty-cycle distortion, crosstalk, and baseline
wander.
■
Transmit rise-fall time manipulated to provide lower
emissions, amplitude fully compatible for proper
interoperability.
■
Programmable scrambler seed for better FCC
compliancy.
■
IEEE 802.3u Clause 28 compliant autonegotiation
for full 10 Mbits/s and 100 Mbits/s control.
■
Extended management support with interrupt
capabilities.
■
PHY MIB support.
■
Low-power 500 mA max.
— Low-cost 128-pin SQFP packaging with heat
spreader.
Features
■
■
4-port, single-chip, integrated physical layer and
transceivers for 10Base-T, 100Base-TX, or
100Base-FX functions.
IEEE 802.3 compatible 10Base-T and 100Base-T
physical layer interface and ANSI X3.263 TP-PMD
compatible transceiver.
■
Interface support for RMII and SMII switch
applications.
■
Autonegotiation pin configurability on a per-port
basis.
1. ISO is a registered trademark of The International Organization
of Standardization.
2. IEC is a registered trademark of The International Electrotechnical Commission.
3. EIA is a registered trademark of Electronic Industries Association.
4. ANSI is a registered trademark of American National Standards
Institute, Inc.
5. IEEE is a registered trademark of The Institute of Electrical and
Electronics Engineers, Inc.
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Table of Contents
Contents
Page
Overview................................................................................................................................................................... 1
Features ................................................................................................................................................................... 1
Description................................................................................................................................................................ 4
Pin Information ......................................................................................................................................................... 5
Pin Descriptions........................................................................................................................................................ 7
Functional Description ............................................................................................................................................ 13
Reduced Media Independent Interface (RMII) .................................................................................................... 13
Serial Media Independent Interface (SMII).......................................................................................................... 15
Media Independent Interface (MII)—Internal....................................................................................................... 17
100Base-X Module.............................................................................................................................................. 19
Scrambler Block .................................................................................................................................................. 22
100Base-TX Transceiver..................................................................................................................................... 24
10Base-T Module ................................................................................................................................................ 25
Reset Operation .................................................................................................................................................. 28
MII Registers .......................................................................................................................................................... 30
dc and ac Specifications......................................................................................................................................... 43
Absolute Maximum Ratings................................................................................................................................. 43
Clock Timing........................................................................................................................................................... 44
Outline Diagram...................................................................................................................................................... 50
128-Pin SQFP ..................................................................................................................................................... 50
Ordering Information............................................................................................................................................... 51
Tables
Page
Table 1. MII Interface Cross-Reference ................................................................................................................... 7
Table 2. Twisted-Pair Magnetic Interface ................................................................................................................. 8
Table 3. Twisted-Pair Transceiver Control/Transmitter Control ................................................................................. 8
Table 4. MII Interface (RMII Mode) .......................................................................................................................... 8
Table 5. MII Interface (SMII Mode) .......................................................................................................................... 9
Table 6. LED/Configuration Pins............................................................................................................................ 10
Table 7. Special Mode Configurations ................................................................................................................... 11
Table 8. Clock and Chip Reset .............................................................................................................................. 12
Table 9. Power and Ground ................................................................................................................................... 12
Table 10. Receive Data/Status Encoding .............................................................................................................. 16
Table 11. Symbol Code Scrambler ........................................................................................................................ 21
Table 12. Autonegotiation ...................................................................................................................................... 29
Table 13. MII Management Registers .................................................................................................................... 30
Table 14. Control Register (Register 0h) ............................................................................................................... 30
Table 15. Status Register Bit Definitions (Register 1h).......................................................................................... 32
Table 16. PHY Identifier (Register 2h) ................................................................................................................... 34
Table 17. PHY Identifier (Register 3h) ................................................................................................................... 34
Table 18. Advertisement (Register 4h) .................................................................................................................. 35
Table 19. Autonegotiation Link Partner Ability (Register 5h) ................................................................................. 36
Table 20. Autonegotiation Expansion Register (Register 6h) ................................................................................ 36
Table 21. Programable LED (Register 11h) ........................................................................................................... 37
Table 22. False Carrier Counter (Register 13h) ..................................................................................................... 38
Table 23. Receive Error Counter (Register 15h).................................................................................................... 38
Table 24. PHY Control/Status Register (Register 17h).......................................................................................... 38
Table 25. Config 100 Register (Register 18h)........................................................................................................ 39
Table 26. PHY Address Register (Register 19h) ................................................................................................... 40
2
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Table of Contents (continued)
Tables
Page
Table 27. Config 10 Register (Register 1Ah) ..........................................................................................................41
Table 28. Status 100 Register (Register 1Bh) ........................................................................................................41
Table 29. Status 10 Register (Register 1Ch) ..........................................................................................................41
Table 30. Interrupt Mask Register (Register 1Dh) ..................................................................................................42
Table 31. Interrupt Status Register (Register 1Eh).................................................................................................42
Table 32. Absolute Maximum Ratings ....................................................................................................................43
Table 33. Operating Conditions ..............................................................................................................................43
Table 34. dc Characteristics ...................................................................................................................................43
Table 35. Management Clock .................................................................................................................................44
Table 36. RMII Receive Timing...............................................................................................................................45
Table 37. RMII Transmit Timing ..............................................................................................................................45
Table 38. Transmit Timing.......................................................................................................................................46
Table 39. Receive Timing .......................................................................................................................................46
Table 40. SMII Timing.............................................................................................................................................47
Table 41. Reset and Configuration Timing .............................................................................................................48
Table 42. PMD Characteristics ...............................................................................................................................48
Figures
Page
Figure 1. LU3X34FTR Block Diagram......................................................................................................................4
Figure 2. Pin Diagram (RMII Mode) .........................................................................................................................5
Figure 3. Pin Diagram (SMII Mode)..........................................................................................................................6
Figure 4. Functional Description ............................................................................................................................13
Figure 5. RMII Receive Timing from Internal MII Signals.......................................................................................14
Figure 6. SMII Connection Diagram .......................................................................................................................15
Figure 7. Receive Sequence Diagram ...................................................................................................................15
Figure 8. Transmit Sequence Diagram ...................................................................................................................16
Figure 9. 100Base-X Data Path .............................................................................................................................19
Figure 10. 10Base-T Module Data Path.................................................................................................................25
Figure 11. LED Configuration.................................................................................................................................28
Figure 12. Management Clock ...............................................................................................................................44
Figure 13. RMII Receive Timing.............................................................................................................................45
Figure 14. RMII Transmit Timing ............................................................................................................................45
Figure 15. Transmit Timing.....................................................................................................................................46
Figure 16. Receive Timing .....................................................................................................................................46
Figure 17. SMII Timing ...........................................................................................................................................47
Figure 18. Reset and Configuration Timing ...........................................................................................................48
Figure 19. PMD Characteristics .............................................................................................................................48
Figure 20. Connection Diagrams (Single-Channel 10/100BTX Operation)............................................................49
Lucent Technologies Inc.
3
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Description
INTZ
TXD[1:0], TX_EN
RXD[1:0], CRS_DV
RMII/SMII-TO-MII
CONVERSION
MII-TO-RMII/SMII
CONVERSION
PORTS[3:0]
GLOBAL
INTERRUPT
100BASE-T
PCS
100BASE-X
PCS
LED
REF_CLK
10/100 CLOCK
RECOVERY
RX±
SQUELCH/SIG_
DETECT
BLW CORRECTION
ADAPTIVE EQ.
LED OUTPUTS
MANAGEMENT
CONTROL
CLOCK
SYNTHESIS
REGISTERS
AUTONEG/
LINK
10/100
TRANSMIT
MDC MDIO
TX±
5-7520(F)
Figure 1. LU3X34FTR Block Diagram
4
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
104
103
RESERVED
ER
RSTZ
TESTMSEL
FOSEL_1/LEDLNK_1
HD100_1/LEDACT_1
HD10_1/SD–1/LEDFD_1
ANEN_1/SD+1/LEDSP100_1
LEDVDD1
LEDGND1
FOSEL_0/LEDLNK_0
HD100_0/LEDACT_0
HD10_0/SD–0/LEDFD_0
ANEN_0/SD+0/LEDSP100_0
REF_CLK
TXEN_0
RMII_TXD_0[0]
RMII_TXD_0[1]
RMII_RXD_0[0]
RMII_RXD_0[1]
IOVDD1
IOGND1
SUBGND1
HSVDD1
HSGND1
TMVDD1
Pin Information
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
LU3X34FTR
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
RMII_RXER_0
CRS_DV_0
FD100_0/COL_0
TXEN_1
RMII_TXD_1[0]
RMII_TXD_1[1]
RMII_RXD_1[0]
RMII_RXD_1[1]
CRS_DV_1/PHYAD[2]
FD100_1/COL_1
DIGVDD1
DIGGND1
RMII_RXER_1
IOVDD3
IOGND3
RESERVED
RMII_RXER_2
FD10_3
DIGVDD2
DIGGND2
FD10_2
FD10_1
FD10_0
FD100_2/COL_2
CRS_DV_2/PHYAD[3]
RMII_RXD_2[1]
RMII_RXD_2[0]
RMII_TXD_2[1]
RMII_TXD_2[0]
TXEN_2
IOVDD4
IOGND4
RESERVED
RMII_RXER_3
FD100_3/COL_3
CRS_DV_3/PHYAD[4]
IOVDD5
RESERVED
INTZ
PAUSE
TPTXTR
ISOLATE
ANEN_2/SD+2/LEDSP100_2
HD10_2/SD–2/LEDFD_2
HD100_2/LEDACT_2
FOSEL_2/LEDLNK_2
LEDGND2
LEDVDD2
ANEN_3/SD+3/LEDSP100_3
HD10_3/SD–3/LEDFD_3
HD100_3/LEDACT_3
FOSEL_3/LEDLNK_3
TXEN_3
RMII_TXD_3[0]
RMII_TXD_3[1]
RMII_RXD_3[0]
RMII_RXD_3[1]
MDC
MDIO
SUBGND2
HSVDD2
HSGND2
TMGND1
IOGND5
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
RXVDD0
RX+_0
RX–_0
RXGND0
REF100_0
TX+_0
TX–_0
TXVDD0
TXVDD1
TX–_1
TX+_1
REF100_1
RXGND1
RX–_1
RX+_1
RXVDD1
REFGND
CSVDD10
CSGND10
CSGND100
CSVDD100
REF10
RXVDD2
RX+_2
RX–_2
RXGND2
REF100_2
TX+_2
TX–_2
TXVDD2
TXVDD3
TX–_3
TX+_3
REF100_3
RXGND3
RX–_3
RX+_3
RXVDD3
5-7511(F).c.r7
Figure 2. Pin Diagram (RMII Mode)
Lucent Technologies Inc.
5
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
104
103
RESERVED
ER
RSTZ
TESTMSEL
FOSEL_1/LEDLNK_1
HD100_1/LEDACT_1
HD10_1/SD–1/LEDFD_1
ANEN_1/SD+1/LEDSP100_1
LEDVDD1
LEDGND1
FOSEL_0/LEDLNK_0
HD100_0/LEDACT_0
HD10_0/SD–0/LEDFD_0
ANEN_0/SD+0/LEDSP100_0
REF_CLK
SMII_SYNC
SMII_TXD_0
RESERVED
SMII_RXD_0
RESERVED
IOVDD1
IOGND1
SUBGND1
HSVDD1
HSGND1
TMVDD1
Pin Information (continued)
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
LU3X34FTR
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
RESERVED
SMII_EN
FD100_0/COL_0
RESERVED
SMII_TXD_1
RESERVED
SMII_RXD_1
RESERVED
PHYAD[2]
FD100_1/COL_1
DIGVDD1
DIGGND1
RESERVED
IOVDD3
IOGND3
RESERVED
RESERVED
FD10_3
DIGVDD2
DIGGND2
FD10_2
FD10_1
FD10_0
FD100_2/COL_2
PHYAD[3]
RESERVED
SMII_RXD_2
RESERVED
SMII_TXD_2
RESERVED
IOVDD4
IOGND4
RESERVED
RESERVED
FD100_3/COL_3
PHYAD[4]
IOVDD5
RESERVED
INTZ
PAUSE
TPTXTR
ISOLATE
ANEN_2/SD+2/LEDSP100_2
HD10_2/SD–2/LEDFD_2
HD100_2/LEDACT_2
FOSEL_2/LEDLNK_2
LEDGND2
LEDVDD2
ANEN_3/SD+3/LEDSP100_3
HD10_3/SD–3/LEDFD_3
HD100_3/LEDACT_3
FOSEL_3/LEDLNK_3
RESERVED
SMII_TXD_3
RESERVED
SMII_RXD_3
RESERVED
MDC
MDIO
SUBGND2
HSVDD2
HSGND2
TMGND1
IOGND5
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
RXVDD0
RX+_0
RX–_0
RXGND0
REF100_0
TX+_0
TX–_0
TXVDD0
TXVDD1
TX–_1
TX+_1
REF100_1
RXGND1
RX–_1
RX+_1
RXVDD1
REFGND
CSVDD10
CSGND10
CSGND100
CSVDD100
REF10
RXVDD2
RX+_2
RX–_2
RXGND2
REFF100_2
TX+_2
TX–_2
TXVDD2
TXVDD3
TX–_3
TX+_3
REFF100_3
RXGND3
RX–_3
RX+_3
RXVDD3
5-7511(F).br6
Figure 3. Pin Diagram (SMII Mode)
6
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Pin Descriptions
Table 1. MII Interface Cross-Reference
Pin
Number
RMII Mode
SMII Mode
80
81
82
85
100
93
79
68
99
73
53
113
102
112
111
110
109
101
98
97
96
95
86
94
78
90
67
54
55
56
57
69
74
75
76
77
59
58
87
70
65
FD10_0
FD10_1
FD10_2
FD10_3
FD100_0/COL_0
FD100_1/COL_1
FD100_2/COL_2
FD100_3/COL_3
TXEN_1
TXEN_2
TXEN_3
TXEN_0
RMII_RXER_0
RMII_TXD_0[0]
RMII_TXD_0[1]
RMII_RXD_0[0]
RMII_RXD_0[1]
CRS_DV_0
RMII_TXD_1[0]
RMII_TXD_1[1]
RMII_RXD_1[0]
RMII_RXD_1[1]
RMII_RXER_2
CRS_DV_1/PHYAD[2]
CRS_DV_2/PHYAD[3]
RMII_RXER_1
CRS_DV_3/PHYAD[4]
RMII_TXD_3[0]
RMII_TXD_3[1]
RMII_RXD_3[0]
RMII_RXD_3[1]
RMII_RXER_3
RMII_TXD_2[0]
RMII_TXD_2[1]
RMII_RXD_2[0]
RMII_RXD_2[1]
MDIO
MDC
RESERVED
RESERVED
RESERVED
FD10_0
FD10_1
FD10_2
FD10_3
FD100_0
FD100_1
FD100_2
FD100_3
RESERVED
RESERVED
RESERVED
SMII_SYNC
RESERVED
SMII_TXD_0
RESERVED
SMII_RXD_0
RESERVED
SMII_EN
SMII_TXD_1
RESERVED
SMII_RXD_1
RESERVED
RESERVED
PHYAD[2]
PHYAD[3]
RESERVED
PHYAD[4]
SMII_TXD_3
RESERVED
SMII_RXD_3
RESERVED
RESERVED
SMII_TXD_2
RESERVED
SMII_RXD_2
RESERVED
MDIO
MDC
RESERVED
RESERVED
RESERVED
Lucent Technologies Inc.
7
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Pin Descriptions (continued)
Table 2. Twisted-Pair Magnetic Interface
Pin No.
Pin Name
I/O
Pin Description
6, 11, 28, 33
7, 10, 29, 32
TX+_[0:3]
TX–_[0:3]
O
3, 14, 25, 36
2, 15, 24, 37
RX–_[0:3]
RX+_[0:3]
I
Transmit Driver Pairs. These pins are used to
transmit 100Base-T MLT-3 signals across Category
5 UTP cable. 10Base-T Manchester signals across
Category 3, 4, or 5 UTP cable in twisted-pair operation or PECL data in fiber mode.
Receive Pair. These pins receive 100Base-T MLT-3
data or 10Base-T Manchester data from the UTP
cable in twisted-pair mode or PECL data in fiber
mode.
Table 3. Twisted-Pair Transceiver Control/Transmitter Control
Pin No.
Pin Name
I/O
Pin Description
5, 12, 27, 34
REF100_[0:3]
I
22
REF10
I
127
ER
I
41
TPTXTR
I
Reference Pin for 100 Mbits/s Twisted-Pair
Driver. The value of the connected resistor is 301 Ω.
Reference Pin for 10 Mbits/s Twisted-Pair Driver.
The value for the connected resistor is 4.65 kΩ.
Transmit Driver Edge Rate Control. When set to 1,
the rise time of the transmit data will be less than
3.5 ns.
Network Interface 3-State Control. When high, the
transmit drivers for the four ports are 3-stated.
Table 4. MII Interface (RMII Mode)
8
Pin No.
Pin Name*
I/O
Pin Description
99, 73, 53
113
102
TXEN_[1:3]
TXEN_0
RMII_RXER_0
I
I
I/O
112, 111
110, 109
101
RMII_TXD_0[0:1]
RMII_RXD_0[0:1]
CRS_DV_0/SMII_EN
I
I/O
I/O↓
98, 97
96, 95
94
RMII_TXD_1[0:1]
RMII_RXD_1[0:1]
CRS_DV_1/PHYAD[2]
I/O
O
I/O↓
Transmit Enable for Ports 1—3.
Transmit Enable for Port 0.
Receiver Error Output for Port 0. Indicates an
illegal code-group has been received.
Transmit Data for Port 0.
Receive Data for Port 0.
CRS_DV Output for Port 0. During reset, this is an
input pin; logic level of 0 at this pin enables RMII
mode. This pin has an internal 40 kΩ pull-down
resistor that sets the MII interface to RMII mode without an external component. After reset, CRS_DV
output for port 0 is asserted only during receive
activity.
Transmit Data for Port 1.
Receive Data for Port 1.
CRS_DV Output for Port 1. During reset, this is an
input pin for PHY_address[2] configuration. This pin
has an internal 40 kΩ pull-down resistor that sets the
PHY_AD[2] to a 0 without an external component.
After reset, CRS_DV output for port 1 and is
asserted only during receive activity.
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Pin Descriptions (continued)
Table 4. MII Interface (RMII Mode) (continued)
Pin No.
Pin Name*
I/O
Pin Description
90
78
RMII_RXER_1
CRS_DV_2/PHYAD[3]
O
I/O↓
74, 75
76, 77
86
67
RMII_TXD_2[0:1]
RMII_RXD_2[0:1]
RMII_RXER_2
CRS_DV_3/PHYAD[4]
I/O
O
O
I/O↓
54, 55
56, 57
69
59
58
65, 87, 70
RMII_TXD_3[0:1]
RMII_RXD_3[0:1]
RMII_RXER_3
MDIO
MDC
RESERVED
I
I/O
O
I/O
I
O
Receiver Error Output for Port 1.
CRS_DV Output for Port 2. During reset, this is an
input pin for PHY_address[3] configuration. This pin
has an internal 40 kΩ pull-down resistor that sets the
PHY_AD[3] to a 0 without an external component.
After reset, CRS_DV output for port 2 and is
asserted only during receive activity.
Transmit Data for Port 2.
Receive Data for Port 2.
Receiver Error for Port 2.
CRS_DV Output for Port 3. During reset, this is an
input pin for PHY_address[4] configuration. This pin
has an internal 40 kΩ pull-down resistor that sets the
PHY_AD[4] to a 0 without an external component.
After reset, CRS_DV output for port 3 and is
asserted only during receive activity.
Transmit Data for Port 3.
Receive Data for Port 3.
Receive Error Output for Port 3.
Management Data for Serial Register Access.
Management Clock. Max clock rate = 2.5 MHz.
Reserved. Leave this pin float.
* Smaller font indicates that the pin has multiple functions.
Table 5. MII Interface (SMII Mode)
Pin No.
Pin Name*
I/O
Pin Description
113
112
110
101
SMII_SYNC
SMII_TXD_0
SMII_RXD_0
SMII_EN
I
I
I/O
I/O↓
98
96
67, 78, 94
SMII_TXD_1
SMII_RXD_1
PHYAD[4:2]
I/O
O
I/O
54
56
74
76
59
SMII_TXD_3
SMII_RXD_3
SMII_TXD_2
SMII_RXD_2
MDIO
I
I/O
I/O
O
I/O
SMII Sync Input.
Transmit Data for Port 0.
Receive Data for Port 0.
SMII_EN. This pin must be pulled high at powerup or
reset to enable SMII mode. This input has an internal 40 kΩ pull-down resistor.
Transmit Data for Port 1.
Receive Data for Port 1.
Configure PHY Address. These pins configure
PHY_address 4 through 2 at powerup or reset. Each
of these pins has an internal 40 kΩ pull-down resistor that sets the corresponding PHY_AD to 0, without an external component.
Transmit Data for Port 3.
Receive Data for Port 3.
Transmit Data for Port 2.
Receive Data for Port 2.
Management Data for Serial Register Access. An
external resistive pull-up is needed on this pin.
Lucent Technologies Inc.
9
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Pin Descriptions (continued)
Table 5. MII Interface (SMII Mode) (continued)
Pin No.
Pin Name*
I/O
Pin Description
58
53, 55, 73, 75,
97, 99, 111
57, 69, 77, 86,
90, 95, 102,
109
MDC
RESERVED
I
I
Management Clock. Max clock rate = 2.5 MHz.
Reserved. Tie to ground.
RESERVED
0
Reserved. Let this pin float.
* Smaller font indicates that the pin has multiple functions.
Table 6. LED/Configuration Pins
Pin No.
Pin Name
I/O
Pin Description
80, 81, 82, 85
FD10_[0:3]
I
100, 93, 79,
68
FD100_[0:3]/
COL_[0:3]
I↑
Full-Duplex 10 Mbits/s. These pins are latched at
reset to configure the ports to 10 Mbits/s full-duplex
mode if autonegotiation is disabled. These pins will
set bit [6] in register 4h, the autonegotiation ability
register.
Full-Duplex 100 Mbits/s. In switch mode, these pins
are latched at reset to configure the ports to
100 Mbits/s full-duplex mode if autonegotiation is
disabled. These pins will set bit [8] in register 4h, the
autonegotiation ability register. These inputs have
internal 40 kΩ pull-up resistors.
115, 121, 43,
49
LEDSP100_ [0:3]/
ANEN_[0:3]/
SD+[0:3]
I/O↑
Collision Status Output. It is asserted during halfduplex mode when transmit and receive activities
are active simultaneously.
Speed LED Output. In twisted-pair mode, these
LED outputs indicate 100 Mbits/s line speed for
ports 0—3.
Autonegotiation Enable. If the FOSEL pin detects
logic low during reset, these are input pins to configure ports 0—3 to enable autonegotiation and sets bit
12 in register 0h.
Signal Detect +. In fiber mode, these pins are signal
detect + inputs.
These pins have an internal 40 kΩ pull-up resistor.
10
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Pin Descriptions (continued)
Table 6. LED/Configuration Pins (continued)
Pin No.
Pin Name
I/O
116, 122, 44,
50
LEDFD_[0:3]/
HD10_[0:3]/
SD–[0:3]
I/O↑
Pin Description
Full-Duplex LED Output. Indicates full duplex for
ports 0—3.
10 Mbits/s Half-Duplex Operation. If FOSEL is low
during powerup or reset, these are input pins that
configure ports 0—3 for 10 Mbits/s half-duplex operation and sets register 4, bit 5 (see Figure 12). When
autonegotiation is disabled, it sets register 0, bit 13,
the speed bit, to 0 and bit 8, the duplex mode bit, to
0. If fiber mode is selected, bit 5, register 4h will be
set to 0.
Signal Detect –. In fiber mode, these pins are the
negative signal detect input from the fiber module.
117, 123, 45,
51
40
LEDCOL_ [0:3]/
HD100_[0:3]
PAUSE
I/O↑
I
These pins have an internal 40 kΩ pull-up resistor.
Activity LED Outputs. These pins indicate collision
status of ports 0—3, respectively.
100 Mbit/s Half-Duplex Operation. During powerup
or reset, these are input pins to configure ports 0—3
for 100 Mbits/s half-duplex operation and sets register 4, bit 7 (see Figure 12). If autonegotiation is disabled, it sets bit 13 in register 0 to 1. These pins
have an internal 40 kΩ pull-up resistor.
Pause. The logic level of this pin is latched into register 4, bit 10 for all four ports during powerup or
reset. It is used to inform the autonegotiation link
partner that the MAC sublayer has pause/flow control capability when set in full-duplex mode. This
must not be set to 1 unless FD is also set.
Table 7. Special Mode Configurations
Pin No.
Pin Name*
I/O
118, 124, 46,
52
LEDLNK_ [0:3]/
FOSEL _[0:3]
I/O↓
39
125
42
INTZ
TESTMSEL
ISOLATE
O
I
I
128, 87, 70,
65
RESERVED
—
Pin Description
Link LED Output. Each of these LEDs turns on
when there is a good link and blinks when there is
activity.
Fiber-Optic Select. These are input pins during
powerup and reset to configure ports 0—3 into fiberoptic mode (see Figure 12). These pins have an
internal 40 kΩ pull-down resistor.
Interrupt. Open drain only pin.
Test Mode Select. This pin should be tied low.
Isolate. If this pin is high, all MII inputs are ignored
and all MII outputs are 3-stated.
Reserved. These are a reserved pins and should be
left floating.
* Smaller font indicates that the pin has multiple functions.
Lucent Technologies Inc.
11
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Pin Descriptions (continued)
Table 8. Clock and Chip Reset
Pin No.
Pin Name
I/O
Pin Description
114
REF_CLK
I
126
RSTZ
I
Reference Clock. In RMII mode, this is the 50 MHz
clock input. In SMII mode, this is the 125 MHz clock
input.
Reset. Active-low reset signal to be asserted for at
least 1 ms.
Table 9. Power and Ground
Plane
Associated Ground Pin
Name
Pin No.
Name
Pin No.
RX Analog
RXVDD0
RXVDD1
RXVDD2
RXVDD3
1
16
23
38
TX Analog
TXVDD0
TXVDD1
TXVDD2
TXVDD3
CSVDD10
CSVDD100
HSVDD1
HSVDD2
DIGVDD1
DIGVDD2
IOVDD1
IOVDD3
IOVDD4
IOVDD5
LEDVDD1
LEDVDD2
TMVDD1
8
9
30
31
18
21
105
61
92
84
108
89
72
66
120
48
103
RXGND0
RXGND1
RXGND2
RXGND3
REFGND
—
4
13
26
35
17
—
CSGND10
CSGND100
HSGND1
HSGND2
DIGGND1
DIGGND2
IOGND1
IOGND3
IOGND4
IOGND5
LEDGND1
LEDGND2
TMGND1
SUBGND1
SUBGND2
19
20
104
62
91
83
107
88
71
64
119
47
63
106
60
CS
Digital
12
VCC Pin
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description
The 100Base-X and 10Base-T sections share the following functional blocks:
The LU3X34FTR integrates four 100Base-X physical
sublayers (PHY), 100Base-TX physical medium dependent (PMD) transceivers, and four complete 10Base-T
modules into a single chip for both 10 Mbits/s and
100 Mbits/s Ethernet operation. It also supports
100Base-FX operation through external fiber-optic
transceivers. This device provides a reduced media
independent interface (RMII) or serial media independent interface (SMII) to communicate between the
physical signaling and the medium access control
(MAC) layers for both 100Base-X and 10Base-T operations. The device is capable of operating in either fullduplex mode or half-duplex mode in either 10 Mbits/s or
100 Mbits/s operation. Operational modes can be
selected by hardware configuration pins or software
settings of management registers, or can be determined by the on-chip autonegotiation logic.
■
100Base-X physical medium attachment (PMA).
■
Twisted-pair transceiver (PMD).
MAC
■
MII registers.
■
IEEE 802.3u autonegotiation.
Reduced Media Independent Interface (RMII)
This interface reduces the interconnect circuits
between a MAC and PHY. In switch applications, this
protocol helps to reduce the pin count on the switch
ASIC significantly. A regular 16-pin MII reduces to a
7-pin (8-pin with an optional RXER pin) RMII. The
interconnect circuits are the following:
1. REF_CLK: A 50 MHz clock.
2. TX_EN.
3. TXD[1:0].
The 100Base-X section of the device implements the
following functional blocks:
100Base-X physical coding sublayer (PCS).
Clock synthesizer module (CSM).
Additionally, there is an interface module that converts
the internal MII signals of the PHY to RMII signal pins.
Each of these functional blocks is described below.
The 10Base-T section of the device consists of the
10 Mbits/s transceiver module with filters and a
Manchester ENDEC module.
■
■
4. RXD[1:0].
5. CRS_DV.
6. RXER: Mandatory for the PHY, but optional for the
switch.
RMII
RMII PHY I/F TO MII PHY I/F
MII MAC I/F TO RMII MAC I/F
TXEN
TXD[3:0]
TXER
TXCLK
COL
CRS
RXDV
RXD[3:0]
RXER
RXCLK
PHY
TXEN
TXD[1:0]
CRS_DV
RXD[1:0]
RXER
REFCLK
TXEN
TXD[3:0]
TXER
TXCLK
COL
CRS
RXDV
RXD[3:0]
RXER
RXCLK
50 MHz
5-7505(F).r1
Figure 4. Functional Description
Lucent Technologies Inc.
13
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
Preliminary Data Sheet
July 2000
REF_CLK). CRS_DV is deasserted asynchronously
with the fall of RX_DV, but CRS_DV keeps toggling as
long as data is being flushed out of the elasticity buffer.
Transmit Data Path
The PHY uses the 50 MHz REF_CLK as its reference
so that TXC (at the internal MII) and REF_CLK maintain a phase relationship. This helps to avoid elasticity
buffers on the transmit side. On the rising edge of
REF_CLK, 2-bit data is provided on the RMII TXD[1:0]
when TXEN is high. TXD[1:0] will be 00 to indicate idle
when TXEN is deasserted.
TX 10 Mbits/s Mode
The REF_CLK frequency is ten times the data rate in
this mode; therefore, the value on TXD[1:0] will be valid
such that TXD[1:0] may be sampled every tenth cycle,
regardless of the starting cycle within the group.
TX 100 Mbits/s Mode
There will be valid data on TXD[1:0] for each REF_CLK
period when TXEN is asserted.
Receive Data Path
RXCLK (at the internal MII) is derived from the incoming data and, hence, does not maintain a phase relationship with REF_CLK. Therefore, an elasticity buffer
is required on the receive path. An 8-nibble deep elasticity buffer is required based on the ppm variation of
the clocks. CRS_DV is asserted asynchronously. Preamble is output onto the RMII once the internal signal
RX_DV is asserted (on the rising edge of the
RX 10 Mbits/s Mode
After the assertion of CRS_DV, the receive data signals, RXD[1:0], will be 00 until the 10Base-T PHY has
recovered the clock and decoded the receive data.
Since REF_CLK is 10 times the data rate in this mode,
the value on RXD[1:0] will be valid such that it can be
sampled every tenth cycle, regardless of the starting
cycle within the group.
RX 100 Mbits/s Mode
After the assertion of CRS_DV, the receive data signals, RXD[1:0] will be 00 until the start-of-stream (SSD)
delimiter has been detected.
Collision Detection
The RMII does not have a collision signal, so all collisions are detected internal to the MAC. This is an AND
function of TXEN and CRS derived from CRS_DV.
CRS_DV cannot be directly ANDed with TXEN,
because CRS_DV may toggle at the end of a frame to
provide separation between CRS and RXDV.
Receiver Error
The RX_ER signal is asserted for one or more
REF_CLK periods to indicate that an error was
detected within the current receive frame.
REF_CLK
CRS
RX_DV
CRS_DV
CRS
RMII_RXD[1:0]
00
01
01
00
5-7506(F).r2
Figure 5. RMII Receive Timing from Internal MII Signals
14
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
Loopback
During normal operation, TXD[1:0] and TX_EN will not be looped back to CRS_DV and RXD[1:0].
Serial Media Independent Interface (SMII)
The SMII allows a further reduction in the number of signals that are required to interface a PHY to a MAC. There
are two global signals, CLK125 and SYNC, and two per-port signals, RXD, TXD. All signals are synchronous to the
125 MHz clock.
LU3X34FTR
MULTI-MAC
SMII_TXD0
PORT 0
SMII_RXD0
SMII_TXD1
PORT 1
SMII_RXD1
SMII_TXD2
PORT 2
SMII_RXD2
SMII_TXD3
PORT 3
SMII_RXD3
SMII_SYNC
REF_CLK
125 MHz
REFERENCE CLOCK
5-7507(F).r4
Figure 6. SMII Connection Diagram
1
2
3
4
5
6
7
8
9
10
11
REF_CLK
SMII_SYNC
SMII_RXD
CRS
RXDV
RXD0
RXD1
RXD2
RXD3
RXD4
RXD5
RXD6
RXD7
5-7507(F).r4
Figure 7. Receive Sequence Diagram
Lucent Technologies Inc.
15
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Functional Description (continued)
Transmit Data Path
Transmit data and control information are signaled in
10-bit segments similar to the receive path. These
10-bit boundaries are delimited by the SYNC signal.
The connected MAC should generate these SYNC
pulses every ten clocks. In 100 Mbits/s mode, each
new segment represents a new byte of data. In
10 Mbits/s mode, each segment is repeated ten times;
therefore, every ten segments represents a new byte of
data. The PHY can sample one of every ten segments.
Receive Path
Receive data and control information are signaled in
10-bit segments. These 10-bit boundaries are delimited
by the SYNC signal. The connected MAC should generate these SYNC pulses every ten clocks. In
100 Mbits/s mode, each segment represents a new
byte of data. In 10 Mbits/s mode, each segment is
repeated ten times, so every ten segments represents
a new byte of data.
The PHY is concerned only with packet data, so there
is no status information passed from the MAC to the
PHY during the interframe gap; this is unlike the
receive side.
The receive sequence contains all of the information
found on the standard MII receive path. RXD[7:0] convey packet data whenever the RXDV bit is set. During
an interframe gap, RXDV bit is set to 0 and RXD[7:0]
indicate receiver status. Bit RXD5 indicates the validity
of the upper nibble of the last byte of data of the previous frame. Bit RXD0 indicates an error detected by the
PHY in the previous frame. Both of these bits will be
valid in the segment immediately following a frame, and
will remain valid until the first data segment of the next
frame.
Collision Detection
The PHY does not directly indicate that a collision has
occurred. It is left up to the MAC to detect the assertion
of both CRS and TXEN.
Table 10. Receive Data/Status Encoding
CRS RXDV
X
0
X
1
RXD0
RXD1
RXD2
RXD3
RXD4
RXD5
RXD6
RXD7
1
Jabber:
Upper nibble: False carrier:
Link:
Duplex:
Speed:
Rcvr
0 = OK
0 = invalid
0 = no link
0 = OK
0 = half
0=
error in
1 = valid
1 = detected
the pre- 10 Mbits/s 1 = full 1 = good link 1 = detected
1=
vious
frame. 100 Mbits/s
One Data Byte (two MII nibbles)
1
2
3
4
5
6
7
8
9
10
11
SMII_CLK
SYNC
TXD
TXER
TXEN
TXD0
TXD1
TXD2
TXD3
TXD4
TXD5
TXD6
TXD7
5-7508(F).r1
Figure 8. Transmit Sequence Diagram
16
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
data paths are 4 bits wide using TXD[3:0] and
RXD[3:0] signal lines.
Media Independent Interface (MII)—Internal
MII Isolate Mode. The LU3X34FTR implements an MII
isolate mode that is controlled by bit 10 of each one of
the four control registers (register 0h). At reset,
LU3X34FTR will initialize this bit to the logic level transition of the ISOLATE pin. Setting the bit to a 1 will also
put the port in MII isolate mode.
The LU3X34FTR implements IEEE 802.3u Clause 22
compliant MII interface which connects to the MII-RMII
module. This module converts the 4-bit MII receive
data to 2-bit RMII receive data. Similarly, it converts the
2-bit RMII transmit data (received from the MAC) to
4-bit MII transmit data. The following describes the
internal MII functions.
Transmit Data Interface
Each internal MII transmit data interface comprises
seven signals: TXD[3:0] are the nibble size data path,
TXEN signals the presence of data on TXD, TXER indicates substitution of data with the HALT symbol, and
TXCLK carries the transmit clock that synchronizes all
the transmit signals. TXCLK is usually supplied by the
on-chip clock synthesizer.
Receive Data Interface
Each internal MII receive data interface also comprises
seven signals: RXD[3:0] are the nibble size data path,
RXDV signals the presence of data on RXD, RXER
indicates the validity of data, and RXCLK carries the
receive clock. Depending upon the operation mode,
RXCLK signal is generated by the clock recovery module of either the 100Base-X or 10Base-T receiver.
Status Interface
Two internal MII status signals, COL and CRS, are generated in each of the four channels to indicate collision
status and carrier sense status. COL is asserted asynchronously whenever the respective channel of
LU3X34FTR is transmitting and receiving at the same
time in a half-duplex operation mode. CRS is asserted
asynchronously whenever there is activity on either the
transmitter or the receiver. In repeater or full-duplex
mode, CRS is asserted only when there is activity on
the receiver.
Operation Modes
Each channel of the LU3X34FTR supports two operation modes and an isolate mode as described below.
100 Mbits/s Mode. For 100 Mbits/s operation, the
internal MII operates in nibble mode with a clock rate of
25 MHz. In normal operation, the internal MII data at
RXD[3:0] and TXD[3:0] are 4 bits wide.
10 Mbits/s Mode. For 10 Mbits/s nibble mode operation, the TXCLK and RXCLK operate at 2.5 MHz. The
Lucent Technologies Inc.
When in isolate mode, the specified port on the
LU3X34FTR does not respond to packet data present
at TXD[3:0], TXEN, and TXER inputs and presents a
high impedance on the TXCLK, RXCLK, RXDV, RXER,
RXD[3:0], COL, and CRS outputs. The LU3X34FTR
will continue to respond to all management transactions while the PHY is in isolate mode.
Serial Management Interface (SMI)
The serial management interface is used to obtain status and to configure the PHY. This mechanism corresponds to the MII specifications for 100Base-X (Clause
22), and supports registers 0 through 6. Additional vendor-specific registers are implemented within the range
of 16 to 31. All the registers are described in the MII
Registers section.
Management Register Access
The SMI consists of two pins, management data clock
(MDC) and management data input/output (MDIO).
The LU3X34FTR is designed to support an MDC frequency specified in the IEEE specification of up to
2.5 MHz. The MDIO line is bidirectional and may be
shared by up to 32 devices.
The MDIO pin requires a 1.5 kΩ pull-up resistor which,
during idle and turnaround periods, will pull MDIO to a
logic one state. Each MII management data frame is
64 bits long. The first 32 bits are preamble consisting of
32 contiguous logic one bits on MDIO and 32 corresponding cycles on MDC. Following preamble is the
start-of-frame field indicated by a <01> pattern. The
next field signals the operation code (OP): <10> indicates read from MII management register operation,
and <01> indicates write to MII management register
operation. The next two fields are PHY device address
and MII management register address. Both of them
are 5 bits wide, and the most significant bit is transferred first.
During read operation, a 2-bit turnaround (TA) time
spacing between the register address field and data
field is provided for the MDIO to avoid contention. Following the turnaround time, a 16-bit data stream is read
from or written into the MII management registers of
the LU3X34FTR.
17
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
The LU3X34FTR supports a preamble suppression
mode as indicated by a 1 in bit 6 of the basic mode status register (BMSR, address 01h). If the station management entity (i.e., MAC or other management
controller) determines that all PHYs in the system support preamble suppression by reading a 1 in this bit,
then the station management entity need not generate
preamble for each management transaction. The
LU3X34FTR requires a single initialization sequence of
32 bits of preamble following powerup/hardware reset.
This requirement is generally met by the mandatory
pull-up resistor on MDIO or the management access
made to determine whether preamble suppression is
supported. While the LU3X34FTR will respond to management accesses without preamble, a minimum of
one idle bit between management transactions is
required as specified in IEEE 802.3u.
The PHY device address is stored in bits [4:0] of the
PHY address register (register address 19h). During
powerup or hardware reset, the upper 3 bits of this field
18
Preliminary Data Sheet
July 2000
are initialized by the three I/O pins designated as
PHY[4:2] and can be subsequently changed by writing
into this register address (19h). The lower 2 bits are initialized to 00, and represent the PHY address for port
1. All subsequent ports have their PHY address increment from this base address (i.e., PHY address for port
1 = 10h, PHY address for port 2 = 11h, PHY address
for port 3 = 12h, PHY address for port 4 = 13h).
MDIO Interrupt
The LU3X34FTR implements interrupt capability that
can be used to notify the management station of certain events. Interrupt requested by any of the four PHYs
is combined in this pin. It generates an active-low interrupt pulse of 80 ns wide on the INTZ output pin whenever one of the interrupt status registers (register
address 1Eh) becomes set while its corresponding
interrupt mask register (register address 1Dh) is unmasked. Reading the interrupt status register (register
1Eh) shows the source of the interrupt and clears the
interrupt output signal.
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
100Base-X Module
The LU3X34FTR implements 100Base-X compliant PCS and PMA and 100Base-TX compliant TP-PMD as illustrated in Figure 9. Bypass options for each of the major functional blocks within the 100Base-X PCS provides flexibility for various applications. 100 Mbits/s PHY loopback is included for diagnostic purposes.
BYP_4B5B
BYP_ALIGN
RYP_SCR
CRS
RXDV
RX STATE MACHINE
RXEN
100BASE-X RECEIVER
EQUALIZER
TPRX±
100M PHY LOOPBACK
4B/5B
DECODE
CLOCK RECOVERY
RXD[3:0]
SERIAL-TO-PARALLEL
CRS_DV
FORX±
FOSD±
DESCRAMBLER
RXD[1:0]
MII-TO-RMII/SMII CONVERSION
RXCLK
TX STATE MACHINE
BYP_ALIGN
PARALLEL-TO-SERIAL
BYP_SCR
SCRAMBLER
BYP_4B5B
4B/5B DECODE
TXD[1:0]
COL
TXCLK
TXEN
TXER
TXD[3:0]
TXEN
RMII/SMII-TO-MII CONVERSION
REF_CLK
MLI-3
STATE
MACHINE
10/100
TX
DRIVER
TPTX±
FIBER
OPTIC
DRIVER
FOTX±
100BASE-X TRANSMITTER
5-7519(F)
Figure 9. 100Base-X Data Path
Lucent Technologies Inc.
19
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
100Base-X Transmitter
The 100Base-X transmitter consists of functional
blocks which convert synchronous 4-bit nibble data, as
provided by the internal MII, to a 125 Mbits/s serial
data stream. This data stream may be routed either to
the on-chip twisted-pair PMD for 100Base-TX signaling, or to an external fiber-optic PMD for 100Base-FX
applications. The LU3X34FTR implements the
100Base-X transmit state machine as specified in the
IEEE 802.3u Standard, Clause 24 and comprises the
following functional blocks in its data path:
■
Symbol encoder.
■
Scrambler block.
■
Parallel/serial converter and NRZ/NRZI encoder
block.
20
Preliminary Data Sheet
July 2000
Symbol Encoder
The symbol encoder converts 4-bit (4B) nibble data
generated by the RMII-MII module into 5-bit (5B) symbols for transmission. This conversion is required to
allow control symbols to be combined with data symbols. Refer to Table 11 for 4B to 5B symbol mapping.
Following onset of the TXEN signal, the 4B/5B symbol
encoder replaces the first two nibbles of the preamble
from the MAC frame with a /J/K code-group pair (11000
10001) start-of-stream delimiter (SSD). The symbol
encoder then replaces subsequent 4B codes with corresponding 5B symbols. Following negation of the
TXEN signal, the encoder substitutes the first two idle
symbols with a /T/R code-group pair (01101 00111)
end-of-stream delimiter (ESD) then continuously injects
idle symbols into the transmit data stream until the next
transmit packet is detected.
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
Table 11. Symbol Code Scrambler
Symbol
Name
5B Code
[4:0]
4B Code
[3:0]
0
1
2
3
4
5
6
7
8
9
A
B
C
D
E
F
I
J
K
T
R
H
V
V
V
V
V
V
V
V
V
V
11110
01001
10100
10101
01010
01011
01110
01111
10010
10011
10110
10111
11010
11011
11100
11101
11111
11000
10001
01101
00111
00100
00000
00001
00010
00011
00101
00110
01000
01100
10000
11001
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
undefined
0101
0101
undefined
undefined
undefined
undefined
undefined
undefined
undefined
undefined
undefined
undefined
undefined
undefined
undefined
Lucent Technologies Inc.
Interpretation
Data 0.
Data 1.
Data 2.
Data 3.
Data 4.
Data 5.
Data 6.
Data 7.
Data 8.
Data 9.
Data A.
Data B.
Data C.
Data D.
Data E.
Data F.
Idle: interstream fill code.
First start-of-stream delimiter.
Second start-of-stream delimiter.
First end-of-stream delimiter.
Second end-of-stream delimiter.
Halt: transfer error.
Invalid code.
Invalid code.
Invalid code.
Invalid code.
Invalid code.
Invalid code.
Invalid code.
Invalid code.
Invalid code.
Invalid code.
21
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
Scrambler Block
For 100Base-TX applications, the scrambler is required
to control the radiated emissions at the media connector and on the twisted-pair cable.
The LU3X34FTR implements a data scrambler as
defined by the TP-PMD stream cipher function. The
scrambler uses an 11-bit ciphering linear feedback shift
register (LFSR) with the following recursive linear function:
Preliminary Data Sheet
July 2000
125 Mbits/s receive data stream may originate from the
on-chip twisted-pair transceiver in a 100Base-TX application. Alternatively, the receive data stream may be
generated by an external optical receiver as in a
100Base-FX application.
The receiver block consists of the following functional
blocks:
■
Equalizer.
■
Clock recovery module.
■
NRZI/NRZ and serial/parallel decoder.
■
Descrambler.
■
Symbol alignment block.
■
Symbol decoder.
■
Collision detect block.
■
Carrier sense block.
■
Stream decoder block.
X[n] = X[n – 11] + X[n – 9] (modulo 2)
The output of the LFSR is combined with data from the
encoder via an exclusive-OR logic function. By scrambling the data, the total energy launched onto the cable
is randomly distributed over a wide frequency range.
A seed value for the scrambler function can be loaded
by setting bit 4 of register 18h. When this bit is set, the
contents of bits [10:0] of register 19h (that are composed of the 5-bit PHY address and a 6-bit user seed)
will be loaded into the LFSR. By specifying unique
seed value for each PHY in a system, the total EMI
energy produced by a repeater application can be
reduced.
Parallel-to-Serial and NRZ-to-NRZI Conversion
After the transmit data stream is scrambled, data is
loaded into a shift register and clocked out with a
125 MHz clock into a serial bit stream. The serialized
data is further converted from NRZ-to-NRZI format,
which produces a transition on every logic one and no
transition on logic zero.
Clock Recovery
The clock recovery module accepts 125 Mbits/s scrambled NRZI data stream from either the on-chip
100Base-TX receiver or from an external 100Base-FX
transceiver. The LU3X34FTR uses an onboard digital
phase-locked loop (PLL) to extract clock information of
the incoming NRZI data, which is then used to retime
the data stream and set data boundaries.
After power-on or reset, the PLL locks to a free-running
25 MHz clock derived from the external clock source.
When initial lock is achieved, the PLL switches to lock
to the data stream, extracts a 125 MHz clock from the
data, and uses it for bit framing of the recovered data.
Collision Detect
NRZI-to-NRZ and Serial-to-Parallel Conversion
During 100 Mbits/s half-duplex operation, collision condition is detected if the transmitter and receiver become
active simultaneously. Collision detection is indicated
by the COL signal of the internal MII. For full-duplex
applications, the COL signal is never asserted.
The recovered data is converted from NRZI to NRZ.
The data is not necessarily aligned to 4B/5B codegroup’s boundary.
100Base-X Receiver
The descrambler acquires synchronization with the
data stream by recognizing idle bursts of 40 or more
bits and locking its deciphering linear feedback shift
register (LFSR) to the state of the scrambling LFSR.
Upon achieving synchronization, the incoming data is
XORed by the deciphering LFSR and descrambled.
The 100Base-X receiver consists of functional blocks
required to recover and condition the 125 Mbits/s
receive data stream. The LU3X34FTR implements the
100Base-X receive state machine diagram as given in
ANSI/IEEE Standard 802.3u, Clause 24. The
22
Data Descrambling
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
Functional Description (continued)
In order to maintain synchronization, the descrambler
continuously monitors the validity of the unscrambled
data that it generates. To ensure this, a link state monitor and a hold timer are used to constantly monitor the
synchronization status. Upon synchronization of the
descrambler, the hold timer starts a 722 µs countdown.
Upon detection of sufficient idle symbols within the
722 µs period, the hold timer will reset and begin a new
countdown. This monitoring operation will continue
indefinitely given a properly operating network connection with good signal integrity. If the link state monitor
does not recognize sufficient unscrambled idle symbols
within the 722 µs period, the descrambler will be forced
out of the current state of synchronization and reset in
order to reacquire synchronization. Register 18h, bit 3,
can be used to extend the timer to 2 ms.
Symbol Alignment
The symbol alignment circuit in the LU3X34FTR determines code word alignment by recognizing the /J/K
delimiter pair. This circuit operates on unaligned data
from the descrambler. Once the /J/K symbol pair
(11000 10001) is detected, subsequent data is aligned
on a fixed boundary.
Symbol Decoding
The symbol decoder functions as a look-up table that
translates incoming 5B symbols into 4B nibbles. The
symbol decoder first detects the /J/K symbol pair preceded by idle symbols and replaces the symbol with
MAC preamble. All subsequent 5B symbols are converted to the corresponding 4B nibbles for the duration
of the entire packet. This conversion ceases upon the
detection of the /T/R symbol pair denoting the end-ofstream delimiter (ESD). The translated data is presented on the RXD[3:0] signal lines with RXD[0] represents the least significant bit of the translated nibble.
Valid Data Signal
The valid data signal (RXDV) indicates that recovered
and decoded nibbles are being presented on the
RXD[3:0] outputs synchronous to RXCLK. RXDV is
asserted when the first nibble of translated /J/K is
ready for transfer over the internal MII. It remains active
until either the /T/R delimiter is recognized, link test
indicates failure, or no signal is detected. On any of
these conditions, RXDV is deasserted.
Receiver Errors
The RXER signal is used to communicate receiver
error conditions. While the receiver is in a state of holdLucent Technologies Inc.
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
ing RXDV asserted, the RXER will be asserted for each
code word that does not map to a valid code-group.
100Base-X Link Monitor
The 100Base-X link monitor function allows the
receiver to ensure that reliable data is being received.
Without reliable data reception, the link monitor will halt
both transmit and receive operations until such time
that a valid link is detected.
The LU3X34FTR performs the link integrity test as outlined in IEEE 100Base-X (Clause 24) link monitor state
diagram. The link status is multiplexed with 10 Mbits/s
link status to form the reportable link status bit in serial
management register 1 and driven to the LNKLED
pins.
When persistent signal energy is detected on the network, the logic moves into a link-ready state after
approximately 500 µs and waits for an enable from the
autonegotiation module. When received, the link-up
state is entered, and the transmit and receive logic
blocks become active. Should autonegotiation be disabled, the link integrity logic moves immediately to the
link-up state after entering the link-ready state.
Carrier Sense
Carrier sense (CRS) for 100 Mbits/s operation is
asserted upon the detection of two noncontiguous
zeros occurring within any 10-bit boundary of the
receive data stream.
The carrier sense function is independent of symbol
alignment. In switch mode, CRS is asserted during
either packet transmission or reception. For repeater
mode, CRS is asserted only during packet reception.
When the idle symbol pair is detected in the receive
data stream, CRS is deasserted. In repeater mode,
CRS is only asserted due to receive activity. CRS is
intended to encapsulate RXDV.
Bad SSD Detection
A bad start-of-stream delimiter (bad SSD) is an error
condition that occurs in the 100Base-X receiver if carrier is detected (CRS asserted) and a valid /J/K set of
code-groups (SSD) is not received.
If this condition is detected, then the LU3X34FTR will
assert RXER and present RXD[3:0] = 1110 to the internal MII for the cycles that correspond to received 5B
code-groups until at least two idle code-groups are
detected. In addition, the false carrier counter (address
13h) will be incremented by one. Once at least two idle
code-groups are detected, RXER and CRS become
deasserted.
23
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Functional Description (continued)
100Base-TX Transceiver
Far-End Fault Indication
LU3X34FTR implements a TP-PMD compliant transceiver for 100Base-TX operation. The differential transmit driver is shared by the 10Base-T and 100Base-TX
subsystems. This arrangement results in one device
that uses the same external magnetics for both the
10Base-T and the 100Base-TX transmission with simple RC component connections. The individually waveshaped 10Base-T and 100Base-TX transmit signals
are multiplexed in the transmit output driver section.
Autonegotiation provides a mechanism for transferring
information from the local station to the link partner that
a remote fault has occurred for 100Base-TX. As autonegotiation is not currently specified for operation over
fiber, the far-end fault indication function (FEFI) provides this capability for 100Base-FX applications.
A remote fault is an error in the link that one station can
detect while the other cannot. An example of this is a
disconnected wire at a station’s transmitter. This station
will be receiving valid data and detect that the link is
good via the link integrity monitor, but will not be able to
detect that its transmission is not propagating to the
other station.
A 100Base-FX station that detects such a remote fault
may modify its transmitted idle stream from all ones to
a group of 84 ones followed by a single 0. This is
referred to as the FEFI idle pattern.
The FEFI function is controlled by bit 11 of register 18h.
It is initialized to 1 (enabled) if the FOSEL pin is at logic
high level during powerup or reset. If the FEFI function
is enabled, the LU3X34FTR will halt all current operations and transmit the FEFI idle pattern when FOSD
signal is deasserted following a good link indication
from the link integrity monitor. FOSD signal is generated internally from the FORX± circuit. Transmission of
the FEFI idle pattern will continue until FORX± signal is
asserted. If three or more FEFI idle patterns are
detected by the LU3X34FTR, then bit 4 of the basic
mode status register (address 01h) is set to one until
read by management. Additionally, upon detection of
far-end fault, all receive and transmit MII activity is disabled/ignored.
24
Transmit Drivers
The LU3X34FTR 100Base-TX transmit driver implements MLT-3 translation and wave-shaping functions.
The rise/fall time of the output signal is closely controlled to conform to the target range specified in the
ANSI TP-PMD standard.
Twisted-Pair Receiver
For 100Base-TX operation, the incoming signal is
detected by the on-chip twisted-pair receiver that comprises the differential line receiver, an adaptive equalizer, and baseline wander compensation circuits.
The LU3X34FTR uses an adaptive equalizer which
changes filter frequency response in accordance with
cable length. The cable length is estimated based on
the incoming signal strength. The equalizer tunes itself
automatically for any cable length to compensate for
the amplitude and phase distortions incurred from the
cable.
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
The LU3X34FTR 10Base-T module is comprised of
the following functional blocks:
10Base-T Module
The 10Base-T transceiver module is IEEE 802.3 compliant. It includes the receiver, transmitter, collision,
heartbeat, loopback, jabber, waveshaper, and link
integrity functions, as defined in the standard. Figure 10
provides an overview for the 10Base-T module.
■
Manchester encoder and decoder.
■
Collision detector.
■
Link test function.
■
Transmit driver and receiver.
■
Serial and parallel interface.
■
Jabber and SQE test functions.
■
Polarity detection and correction.
RXCLK
CRS_DV
CRS
TPRX±
RECEIVE
FILTER
FILTER
SMART
SQUELCH
CLOCK
RECOVERY
10BASE-T
RECEIVE
PCS
RXD[3:0]
MII-TO-RMII/SMII
CONVERTER
RXD[1:0]
RXDV
COL
REF_CLK
TXEN
TXEN
TPTX±
10/100
TX DRIVER
WAVE
SHAPER
10BASE-T
RECEIVE
PCS
TXER
RMII/SMII-TO-MII
CONVERTER
TXD[1:0]
TXD[3:0]
TXCLK
TXCLK
5-7521(F)
Figure 10. 10Base-T Module Data Path
Lucent Technologies Inc.
25
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
Preliminary Data Sheet
July 2000
Operation Modes
Only after all of these conditions have been satisfied
will a control signal be generated to indicate to the
remainder of the circuitry that valid data is present.
The LU3X34FTR 10Base-T module is capable of operating in either half-duplex mode or full-duplex mode. In
half-duplex mode, the LU3X34FTR functions as an
IEEE 802.3 compliant transceiver with fully integrated
filtering. The COL signal is asserted during collisions or
jabber events, and the CRS signal is asserted during
transmit and receive. In full-duplex mode, the
LU3X34FTR can simultaneously transmit and receive
data.
Valid data is considered to be present until the squelch
level has not been generated for a time longer than
200 ns, indicating end of packet. Once good data has
been detected, the squelch levels are reduced to minimize the effect of noise, causing premature end-ofpacket detection. The receive squelch threshold level
can be lowered for use in longer cable applications.
This is achieved by setting bit 11 of register address
1Ah.
Manchester Encoder/Decoder. Data encoding and
transmission begins when the transmit enable input
(TXEN) goes high and continues as long as the transceiver is in good link state. Transmission ends when the
transmit enable input goes low. The last transition
occurs at the center of the bit cell if the last bit is a 1, or
at the boundary of the bit cell if the last bit is 0.
Carrier Sense. Carrier sense (CRS) is asserted due to
receive activity once valid data is detected via the
smart squelch function.
Decoding is accomplished by a differential input
receiver circuit and a phase-locked loop that separates
the Manchester-encoded data stream into clock signals
and NRZ data. The decoder detects the end of a frame
when no more midbit transitions are detected. Within
one and a half bit times after the last bit, carrier sense
is deasserted.
Transmit Driver and Receiver. The LU3X34FTR integrates all the required signal conditioning functions in
its 10Base-T block such that external filters are not
required. Only an isolation transformer and impedancematching resistors are needed for the 10Base-T transmit and receive interface. The internal transmit filtering
ensures that all the harmonics in the transmit signal are
attenuated properly.
Smart Squelch. The smart squelch circuit is responsible for determining when valid data is present on the
differential receive. The LU3X34FTR implements an
intelligent receive squelch on the TPRX+/– differential
inputs to ensure that impulse noise on the receive
inputs will not be mistaken for a valid signal. The
squelch circuitry employs a combination of amplitude
and timing measurements (as specified in the IEEE
802.3 10Base-T standard) to determine the validity of
data on the twisted-pair inputs.
The signal at the start of the packet is checked by the
analog squelch circuit and any pulses not exceeding
the squelch level (either positive or negative, depending upon polarity) will be rejected. Once this first
squelch level is overcome correctly, the opposite
squelch level must then be exceeded within 150 ns.
Finally, the signal must exceed the original squelch
level within an additional 150 ns to ensure that the input
waveform will not be rejected.
26
For 10 Mbits/s half-duplex operation, CRS is asserted
during either packet transmission or reception.
For 10 Mbits/s full-duplex operation, the CRS is
asserted only due to receive activity.
In repeater mode, CRS is only asserted due to receive
activity. CRS is deasserted following an end of packet.
Collision Detection. The RMII does not have a collision pin. Collision is detected internal to the MAC,
which is generated by an AND function of TXEN and
CRS derived from CRS_DV. CRS_DV cannot be
directly ANDed with TXEN because CRS_DV may toggle at the end of a frame to provide separation between
CRS and RXDV. The internal MII will still generate the
COL signal, but this information is not passed to the
MAC via the RMII.
Jabber Function. The jabber function monitors the
LU3X34FTR's output and disables the transmitter if it
attempts to transmit a longer than legal-sized packet. If
TXEN is high for greater than 24 ms, the 10Base-T
transmitter will be disabled. Once disabled by the jabber function, the transmitter stays disabled for the
entire time that the TXEN signal is asserted. This signal has to be deasserted for approximately 256 ms (the
unjab time) before the jabber function re-enables the
transmit outputs. The jabber function can be disabled
by setting bit 10 of register 1Ah.
Link Test Function. A link pulse is used to check the
integrity of the connection with the remote end. If valid
link pulses are not received, the link detector disables
the 10Base-T twisted-pair transmitter, receiver, and collision detection functions.
The link pulse generator produces pulses as defined in
the IEEE 802.3 10Base-T standard. Each link pulse is
nominally 100 ns in duration and is transmitted every
16 ms, in the absence of transmit data.
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
Functional Description (continued)
Automatic Link Polarity Detection. The
LU3X34FTR's 10Base-T transceiver module incorporates an automatic link polarity detection circuit. The
inverted polarity is determined when seven consecutive
link pulses of inverted polarity or three consecutive
packets are received with inverted end-of-packet
pulses. If the input polarity is reversed, the error condition will be automatically corrected and reported in
bit 15 of register 1Ch.
The automatic link polarity detection function can be
disabled by setting bit 3 of register 1Ah.
Clock Synthesizer
The LU3X34FTR implements a clock synthesizer that
generates all the reference clocks needed from a single
external frequency source. The clock source must be a
TTL level signal at 25 MHz ± 50 ppm.
Autonegotiation
The autonegotiation function provides a mechanism for
exchanging configuration information between two
ends of a link segment and automatically selecting the
highest-performance mode of operation supported by
both devices. Fast link pulse (FLP) bursts provide the
signaling used to communicate autonegotiation abilities
between two devices at each end of a link segment. For
further detail regarding autonegotiation, refer to
Clause 28 of the IEEE 802.3u specification. The
LU3X34FTR supports four different Ethernet protocols,
so the inclusion of autonegotiation ensures that the
highest-performance protocol will be selected based on
the ability of the link partner.
The autonegotiation function within the LU3X34FTR
can be controlled either by internal register access or
by the use of configuration pins. At powerup and at
device reset, the configuration pins are sampled. If disabled, autonegotiation will not occur until software
enables bit 12 in register 0. If autonegotiation is
enabled, the negotiation process will commence immediately.
When autonegotiation is enabled, the LU3X34FTR
transmits the abilities programmed into the autonegotiation advertisement register at address 4h via FLP
bursts. Any combination of 10 Mbits/s, 100 Mbits/s,
half-duplex, and full-duplex modes may be selected.
Autonegotiation controls the exchange of configuration
information. Upon successful autonegotiation, the abilities reported by the link partner are stored in the autonegotiation link partner ability register at address 5h.
Lucent Technologies Inc.
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
The contents of the autonegotiation link partner ability
register are used to automatically configure to the
highest-performance protocol between the local and
far-end nodes. Software can determine which mode
has been configured by autonegotiation by comparing
the contents of register 04h and 05h and then selecting
the technology whose bit is set in both registers of highest priority relative to the following list.
1. 100Base-TX full duplex (highest priority).
2. 100Base-TX half duplex.
3. 10Base-T full duplex.
4. 10Base-T half duplex (lowest priority).
The basic mode control register at address 00h provides control of enabling, disabling, and restarting of
the autonegotiation function. When autonegotiation is
disabled, the speed selection bit (bit 13) controls
switching between 10 Mbits/s or 100 Mbits/s operation,
while the duplex mode bit (bit 8) controls switching
between full-duplex operation and half-duplex operation. The speed selection and duplex mode bits have
no effect on the mode of operation when the autonegotiation enable bit (bit 12) is set.
The basic mode status register at address 01h indicates the set of available abilities for technology types
(bits 15 to 11), autonegotiation ability (bit 3), and
extended register capability (bit 0). These bits are hardwired to indicate the full functionality of the
LU3X34FTR. The BMSR also provides status on:
1. Whether autonegotiation is complete (bit 5).
2. Whether the link partner is advertising that a remote
fault has occurred (bit 4).
3. Whether a valid link has been established (bit 2).
The autonegotiation advertisement register at address
04h indicates the autonegotiation abilities to be advertised by the LU3X34FTR. All available abilities are
transmitted by default, but any ability can be suppressed by writing to this register or configuring external pins.
The autonegotiation link partner ability register at
address 05h indicates the abilities of the link partner as
indicated by autonegotiation communication. The contents of this register are considered valid when the
autonegotiation complete bit (bit 5, register address
01h) is set.
27
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
Reset Operation
The LU3X34FTR can be reset either by hardware or
software. A hardware reset is accomplished by applying a negative pulse, with a duration of at least 1 ms to
the RSTZ pin of the LU3X34FTR during normal operation. A software reset is activated by setting the reset
bit in the basic mode control register (bit 15, register
00h). This bit is self-clearing and, when set, will return
a value of 1 until the software reset operation has completed.
Hardware reset operation samples the pins and initializes all registers to their default values. This process
includes re-evaluation of all hardware-configurable registers. A hardware reset affects all four PHYs in the
device.
A software reset can reset an individual PHY, and it
does not latch the external pins or reset the registers to
their respective default values.
Preliminary Data Sheet
July 2000
Logic levels on several I/O pins are detected during a
hardware reset to determine the initial functionality of
LU3X34FTR. Some of these pins are used as output
ports after reset operation.
Care must be taken to ensure that the configuration
setup will not interfere with normal operation. Dedicated configuration pins can be tied to Vcc or ground
directly. Configuration pins multiplexed with logic level
output functions should be either weakly pulled up or
weakly pulled down through resistors. Configuration
pins multiplexed with LED outputs should be set up
with one of the following circuits shown in Figure 11.
The 10 kΩ resistor is required only for nondefault configuartion.
Pins ANEN, FD10, FD100, and HD100 have internal
pull-up resistors, making their default value a 1 without
any external components. Pins FOSEL, SMII_EN, and
PHYAD[2:4] have internal pull-down resistors, making
their default value a 0 without any external components.
Note: The MDIO pin is pulled low during reset.
I/O PIN
10 kΩ
10 kΩ
I/O PIN
LOGIC 1 CONFIGURATION
LOGIC 0 CONFIGURATION
5-6783(F).a
Figure 11. LED Configuration
PHY Address
The PHY device address is stored in bits [4:0] of the PHY address register (register address 19h). The upper 3 bits
of this field are initialized by the three I/O pins designated as PHY[4:2] during powerup or hardware reset and can
be changed afterward by writing into this register address (19h). The lower 2 bits are initialized to 00 and represent
the PHY address for port 0. The PHY address for all subsequent ports are increments from this base address (i.e.,
PHY address for port 0 = 10h, PHY address for port 1 = 11h, PHY address for port 2 = 12h, PHY address for
port 3 = 13h). These unique 5-bit addresses are used during serial management interface communication.
28
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Functional Description (continued)
Autonegotiation and Speed Configuration
The four sets of five pins listed in Table 13 configure the speed capability of each channel of LU3X34FTR. The
logic state of these pins, at powerup or reset, is latched into the advertisement register (register address 04h) for
autonegotiation purposes. These pins are also used for evaluating the default value in the base mode control register (register 00h) according to Table 12.
Table 12. Autonegotiation
Configuration Pins at Reset
Registers Initial Value
ANEN
FD100
(bit 4.8)
HD100
(bit 4.7)
FD10
(bit 4.6)
HD10
(bit 4.5)
AUTONEG
reg 0.12
SPEED
reg 0.13
DUPLEX
reg 0.8
0
0
0
0
0
1
1
0
0
0
0
X
X
1
1
0
0
X
X
1
0
1
0
X
X
X
X
X
1
X
0
0
0
0
0
1
1
1
1
0
0
0
1
1
0
1
0
0
LED Configuration
The LU3X34FTR provides four LED output pins for each of its four ports. In addition to the default functions associated with their pin names, there are several registers that allow users to customize LED operations.
Register 11h (programmable LED register) at PHY address 2 implements even more flexible LED configurations.
Register 11h at PHY address 4 controls all even-numbered ports, and register 11h at address 5 controls all oddnumbered ports. Via the programmable LED register, each of the LEDs may be configured to operate in one of the
following modes: link, speed, duplex, receive, transmit, solid when link is up and blinks during activity, remote fault,
and collision. Bits [0:3] in these registers allow the user to invert the on/off logic for each of these four programmable LEDs individually.
Note that all LED circuits are switched under the control of the programmable LED register whenever the content of
register 11h differs from its default value.
Register 17h implements more LED configuration functions. With these registers, unused LED can be individually
turned off to reduce power consumption.
Fiber Mode Select
A logic one level on pins FOSEL[0:3] sets each channel in fiber mode individually. These pins are latched during
reset operation.
MII Registers
The LU3X34FTR has four independent PHYs in it. Each PHY has its own identical set of registers as tabulated
below. The PHY address differentiates which PHY to be read or written into. The following tables of registers are
applicable to each register.
Lucent Technologies Inc.
29
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
MII Registers
Table 13. MII Management Registers
Address
0h
1h
2h—3h
4h
5h
6h
7h—Fh
12h
13h
15h
17h
18h
19h
1Ah
1Bh
1Ch
1Dh
1Eh
Register Name
Basic/Extended
Control Register
Status Register
PHY Identifier Register
Autonegotiation Advertisement Register
Autonegotiation Link Partner Ability Register
Autonegotiation Expansion Register
IEEE Reserved
Isolate Counter
False Carrier Counter
Receive Error Counter
PHY Control/Status Register
Config 100 Register
PHY Address Register
Config 10 Register
Status 100 Register
Status 10 Register
Interrupt Mask Register
Interrupt Status Register
B
B
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
Legend:
RO
Read only.
R/W
Read and write capable.
SC
Self-clearing.
LL
Latching low, unlatch on read.
LH
Latching high, unlatch on read.
COR Clear on read.
Table 14. Control Register (Register 0h)
Bit(s)
Name
Description
R/W
Default
15
Reset
1—PHY reset
0—Normal operation
Setting this bit initiates the software reset
function that resets the selected port,
except for the phase-locked loop circuit. It
will not relatch in all hardware configuration pin values, but it will set all registers to
their default values. The software reset
process takes 25 µs to complete. This bit,
which is self-clearing, returns a value of 1
until the reset process is complete.
R/W
SC
0h
30
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
MII Registers (continued)
Table 14. Control Register (Register 0h) (continued)
Bit(s)
Name
Description
R/W
Default
14
Loopback
R/W
0h
13
Speed Selection
R/W
Pin
12
Autonegotiation Enable
R/W
Pin
11
Powerdown
R/W
0h
10
Isolate
1—Enable loopback mode
0—Disable loopback mode
This bit controls the PHY loopback operation that isolates the network transmitter
outputs (TPTX+/– and FOTX+/–) and
routes the MII transmit data to the MII
receive data path. This function should
only be used when autonegotiation is disabled (bit 12 = 0). The specific PHY
(10Base-T or 100Base-X) used for this
operation is determined by bits 12 and 13
of this register.
1—100 Mbits/s
0—10 Mbits/s
Link speed is selected by this bit or by
autonegotiation if bit 12 of this register is
set (in which case, the value of this bit is
ignored). At powerup or reset, this bit will
be set unless ANEN, FD100, and HD100
pins are all in logic low state.
1—Enable autonegotiation process
0—Disable autonegotiation process
This bit determines whether the link speed
should be set up by the autonegotiation
process. It is set at powerup or reset if the
ANEN pin detects a logic 1 input level.
1—Powerdown
0—Normal operation
Setting this bit puts the LU3X34FTR into
powerdown mode. During the powerdown
mode, TPTX+/– and all LED outputs are
3-stated, FOTX+/– outputs are turned off,
and the MII interface is isolated. RESETZ
is used to clear register.
Note: Powerdown is an optional function
and is not implemented in this device. Setting this bit does not significantly impact
the power consumption.
1—Isolate PHY from MII
0—Normal operation
Setting this control bit isolates the part
from the MII, with the exception of the
serial management interface. When this
bit is asserted, the LU3X34FTR does not
respond to TXD[3:0], TXEN, and TXER
inputs, and it presents a high impedance
on its TXCLK, RXCLK, RXDV, RXER,
RXD[3:0], COL, and CRS outputs.
R/W
Pin
Lucent Technologies Inc.
31
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
MII Registers (continued)
Table 14. Control Register (Register 0h) (continued)
Bit(s)
Name
9
Restart Autonegotiation
8
Duplex Mode
7
Collision Test (only
applicable while in PHY
loopback mode)
6:0
Reserved
Description
R/W
R/W, SC
1—Restart autonegotiation process
0—Normal operation
Setting this bit while autonegotiation is
enabled forces a new autonegotiation process to start. This bit is self-clearing and
returns to 0 after the autonegotiation process has commenced.
R/W
1—Full-duplex mode
0—Half-duplex mode
If autonegotiation is disabled, this bit
determines the duplex mode for the link.
At powerup or reset, this bit is set to 0 if
the SW_RPTRZ input is low. This bit is set
to 1, if ANEN pin detects a logic 0 and
either FD100 or FD10 pin detects a logic
1.
R/W
1—Enable COL signal test
0—Disable COL signal test
When set, this bit will cause the COL signal of MII interface to be asserted in
response to the assertion of TXEN.
Not used.
RO
Default
0h
Pin
0h
0h
Note: While maintaining a good link, modifying any bit in the control register (register 0) will cause the link to drop.
Table 15. Status Register Bit Definitions (Register 1h)
Bit(s)
Name
Description
R/W
Default
15
100Base-T4
RO
0h
14
100Base-X Full Duplex
RO
1h
13
100Base-X Half Duplex
1—Capable of 100Base-T4
0—Not capable of 100Base-T4
This bit is hardwired to 0, indicating that
the LU3X34FTR does not support
100Base-T4.
1—Capable of 100Base-X full-duplex
mode
0—Not capable of 100Base-X full-duplex
mode
This bit is hardwired to 1, indicating that
the LU3X34FTR supports 100Base-X
full-duplex mode.
1—Capable of 100Base-X half-duplex
mode
0—Not capable of 100Base-X half-duplex
mode
This bit is hardwired to 1, indicating that
the LU3X34FTR supports 100Base-X
half-duplex mode.
RO
1h
32
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
MII Registers (continued)
Table 15. Status Register Bit Definitions (Register 1h) (continued)
Bit(s)
Name
12
10 Mbits/s Full Duplex
11
10
9:7
6
5
4
Description
1—Capable of 10 Mbits/s full-duplex
mode
0—Not capable of 10 Mbits/s full-duplex
mode
This bit is hardwired to 1, indicating that
the LU3X34FTR supports 10Base-T
full-duplex mode.
10 Mbits/s Half Duplex
1—Capable of 10 Mbits/s half-duplex
mode
0—Not capable of 10 Mbits/s half-duplex
mode
This bit is hardwired to 1, indicating that
the LU3X34FTR supports 10Base-T
half-duplex mode.
100Base-T2
1—Capable of 100Base-T2
0—Not capable of 100Base-T2
This bit is hardwired to 0, indicating that
the LU3X34FTR does not support
100Base-T2.
Reserved
Ignore when read.
MF Preamble Suppression 1—Accepts management frames with
preamble suppressed
0—Will not accept management frames
with preamble suppressed
This bit is hardwired to 1, indicating that
the LU3X34FTR accepts management
frame without preamble. A minimum of 32
preamble bits are required following
power-on or hardware reset. One idle bit
is required between any two management transactions as per IEEE 802.3u
specification.
Autonegotiation Complete 1—Autonegotiation process completed
0—Autonegotiation process not completed
If autonegotiation is enabled, this bit indicates whether the autonegotiation process has been completed.
Remote Fault
1—Remote fault detected
0—Remote fault not detected
This bit is latched to 1 if the RF bit in the
autonegotiation link partner ability register (bit 13, register address 05h) is set or
the receive channel meets the far-end
fault indication function criteria. It is
unlatched when this register is read.
Lucent Technologies Inc.
R/W
Default
RO
1h
RO
1h
RO
0h
RO
RO
0h
1h
RO
0h
RO, LH
0h
33
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
MII Registers (continued)
Table 15. Status Register Bit Definitions (Register 1h) (continued)
Bit(s)
Name
Description
R/W
Default
3
Autonegotiation Ability
RO
1h
2
Link Status
RO,
LL
0h
1
Jabber Detect
RO,
LH
0h
0
Extended Capability
1—Capable of autonegotiation
0—Not capable of autonegotiation
This bit defaults to 1, indicating that
LU3X34FTR is capable of autonegotiation.
1—Link is up
0—Link is down
This bit reflects the current state of the
link-test-fail state machine. Loss of a valid
link causes a 0 latched into this bit. It
remains 0 until this register is read by the
serial management interface.
1—Jabber condition detected
0—Jabber condition not detected
During 10Base-T operation, this bit indicates the occurrence of a jabber condition. It is implemented with a latching
function so that it becomes set until it is
cleared by a read.
1—Extended register set
0—No extended register set
This bit defaults to 1, indicating that the
LU3X34FTR implements extended registers.
RO
1h
Table 16. PHY Identifier (Register 2h)
Bit(s)
Name
15:0
PHY-ID[15:0]
Description
R/W
Default
IEEE address
RO
0043h
Table 17. PHY Identifier (Register 3h)
Bit(s)
Name
Description
R/W
Default
15:0
PHY-ID[15:0]
IEEE
address/Model
No./ Rev. No.
RO
7440h
34
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
MII Registers (continued)
Table 18. Advertisement (Register 4h)
Bit(s)
Name
Description
R/W
Default
15
Next Page
RO
0h
14
13
Reserved
Remote Fault
RO
R/W
0h
0h
12:11
10
IEEE Reserved
Flow Control
R/W
R/W
0h
Pin
9
Technology Ability Field for
100Base-T4
RO
0h
8:5
Technology Ability Field
R/W
Pin
4:0
Selector Field
1—Capable of next page function
0—Not capable of next page function
This bit is defaults to 0, indicating that
LU3X34FTR is not next page capable.
Reserved.
1—Remote fault has been detected
0—No remote fault has been detected
This bit is written by serial management
interface for the purpose of communicating the remote fault condition to the autonegotiation link partner.
These bits default to 0.
1—MAC sublayer is capable of pausebased flow control
0—MAC sublayer not capable of pausebased flow control
This bit advertises the MAC sublayer has
pause/flow control capability of operation
when set in full-duplex mode. This must
be set only when the PHY is advertising
10FD/100FD modes. At hardware reset,
this bit is set to 1, if the PAUSE pin
detects logic 1.
Note: It is the user’s responsibility to
ensure that the flow control bit is set only
when the PHY is advertising
10FD/100FD modes.
This bit defaults to 0, indicating that the
LU3X34FTR does not support
100Base-T4.
This 4-bit field contains the advertised
ability of this PHY. At powerup or reset,
the logic level of 100FDEN, 100HDEN,
10FDEN, and 10HDEN pins are latched
into bits 8 through 5, respectively.
These 5 bits are hardwired to 00001h,
indicating that the LU3X34FTR supports
IEEE 802.3 CSMA/CD.
RO
01h
Lucent Technologies Inc.
35
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
MII Registers (continued)
Table 19. Autonegotiation Link Partner Ability (Register 5h)
Bit(s)
Name
Description
R/W
Default
15
Next Page
RO
0h
14
Acknowledge
RO
0h
13
Remote Fault
RO
0h
12:5
4:0
Technology Ability Field
Selector Field
1—Capable of next page function
0—Not capable of next page function
1—Link partner acknowledges reception
of the ability data word
0—Not acknowledged
1—Remote fault has been detected
0—No remote fault has been detected
Supported technologies.
Encoding definitions.
RO
RO
0h
0h
R/W
Default
RO
RO, LH
0h
0h
RO
0h
RO
0h
RO, LH
0h
RO
0h
Table 20. Autonegotiation Expansion Register (Register 6h)
Bit(s)
Name
15:5
4
Reserved
Parallel Detection Fault
3
2
1
0
36
Description
Reserved.
1—Fault has been detected
0—No fault detected
This bit is set if the parallel detection fault
state of the autonegotiation arbitration
state machine is polled during the autonegotiation process. It will remain set until
this register is read.
Link Partner Next Page Capa- 1—Link partner is next page capable
ble
0—Link partner is not next page capable
This bit indicates whether the link partner
is next page capable. It is meaningful only
when the autonegotiation complete bit (bit
5, register 1) is set.
Next Page Able
1—Local device is next page capable
0—Local device is not next page capable
This bit defaults to 0, indicating that
LU3X34FTR is not next page capable.
Page Received
1—A new page has been received
0—No new page has been received
This bit is latched to 1 when a new link
code word page has been received. This
bit is automatically cleared when the
autonegotiation link partner ability register (register 05h) is read by management
interface.
Link Partner Autonegotiable 1—Link partner is autonegotiable
0—Link partner is not autonegotiable
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
MII Registers (continued)
Table 21. Programable LED (Register 11h)
Bit(s)
15:13
Name
Activity LED Function
12:10
Full-Duplex LED Function
9:7
Speed 100 LED Function
6:4
Link LED Function
3:0
LED Inversion Mode
Description
Programable LED output with the following settings:
011: link
010: speed
001: duplex
000: receive
111: activity/transmit
110: solid when link is up, blinks during
activity
101: remote fault
100: collision
Programable LED output with the following settings:
000: link
001: speed
010: duplex
011: receive
100: activity/transmit
101: solid when link is up, blinks during
activity
110: remote fault
111: collision
Programable LED output with the following settings:
101: link
100: speed
111: duplex
110: receive
001: activity/transmit
000: solid when link is up, blinks during
activity
011: remote fault
010: collision
Programable LED output with the following settings:
000: link
001: speed
010: duplex
011: receive
100: activity/transmit
101: solid when link is up, blinks during
activity
110: remote fault
111: collision
Inversion option for the LEDs for each
port [0:3]. For example, if set to 1, LED is
on when activity is not present, and off
during activity.
R/W
R/W
Default
100
R/W
010
R/W
001
R/W
000
R/W
0000
Notes: The following bit sequence will restore the old LED functionality: 1110100001010000.
PHY address 2 will set the LED functionality for all ports. However, the individual port’s LED functionality can be set on a PHY address by
PHY address basis. (i.e., PHY 0’s LEDs can be set to be different from PHY 1, PHY 2, and PHY 3.
Lucent Technologies Inc.
37
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
MII Registers (continued)
Table 22. False Carrier Counter (Register 13h)
Bit(s)
Name
Description
R/W
Default
15:0
False Carrier Count
Number of false carrier conditions since
reset or read. The counter is incriminated
once for each packet that has false carrier
condition detected. This counter may roll
over depending on value of CSMODE bit
(bit 13 of register 17h).
RO,
COR
0h
Table 23. Receive Error Counter (Register 15h)
Bit(s)
Name
Description
R/W
Default
15:0
RX Error Count
Number of receive errors since last reset.
The counter is incriminated once for each
packet that has receive error condition
detected. This counter may roll over
depending on value of the CSMODE bit
(bit 13 of register 17h).
RO,
COR
0h
R/W
Default
RO
RO
0h
Pin
R/W
0h
R/W
Pin
R/W
0h
Table 24. PHY Control/Status Register (Register 17h)
Bit(s)
Name
15
14
Reserved
FOSEL
13
12
11
38
Description
Reserved.
1—Fiber mode
0—TX mode
For 100Base-X operation, this bit determines whether LU3X34FTR interfaces
with the network through the internal
100Base-TX transceiver or using external
fiber-optic transceiver. It is initialized to the
logic level of FOSEL pin (pin 124, 117, 46,
and 52 for four PHYs) at powerup or reset.
CSMODE
1—Counter sticks at FFFFh
0—Counters roll over
This bit controls the operation of isolate
counter, false carrier counter, and receive
error counters.
TPTXTR
1—3-state transmit pairs
0—Normal operation
When this bit is set, the twisted-pair transmitter outputs if all four ports are 3-stated.
Note that the twisted-pair transmit driver
can be 3-stated by either this bit or the
TPTXTR pin (pin 41).
ThunderLAN Interrupt Enable 1—MDIO ThunderLAN interrupt enabled
0—MDIO ThunderLAN interrupt disabled
This bit enables/disables the TI ThunderLAN interrupt mechanism.
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
MII Registers (continued)
Table 24. PHY Control/Status Register (Register 17h) (continued)
Bit(s)
Name
10
MF Preamble Suppression
Enable
9
8
7
6
5
4
3
2
1
0
Description
1—MDIO preamble suppression enabled
0—MDIO preamble suppression disabled
LU3X34FTR can accept management
frames without preamble as described in
bit 6 of register 1h. This bit allows the user
to enable or disable the preamble suppression function.
Speed Status
1—Part is in 100 Mbit mode
0—Part is in 10 Mbit mode
This value is not defined during the autonegotiation period.
Duplex Status
1—Part is in full-duplex mode
0—Part is in half-duplex mode
This value is not defined during the autonegotiation period.
Reserved
Reserved.
Reserved
Reserved.
ACTLED Off
1—3-state ACTLED output
0—Normal operation
LEDLNK Off
1—3-state LEDLNK output
0—Normal operation
Reserved
Reserved.
LEDFD Off
1—3-state LEDFD output
0—Normal operation
LEDSP Off
1—3-state LEDSP output
0—Normal operation
LED Pulse Stretching Disable 1—LED pulse stretching disabled
0—LED pulse stretching enabled
When set to 1 all LED outputs are
stretched 48 ms—72 ms.
R/W
Default
R/W
1h
RO
0h
RO
0h
R/W
R/W
R/W
1h
1h
0
R/W
0
R/W
R/W
1h
0
R/W
0
R/W
0
Table 25. Config 100 Register (Register 18h)
Bit(s)
Name
15
BPSCR
14
13
12
Reserved
Reserved
Reserved
Lucent Technologies Inc.
Description
1—Disable scrambler/descrambler
0—Enable scrambler/descrambler
Reserved.
Reserved.
Reserved.
R/W
Default
R/W
FOSEL
RO
RO
RO
0h
0h
0h
39
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
MII Registers (continued)
Table 25. Config 100 Register (Register 18h) (continued)
Bit(s)
Name
11
Enable FEFI
10
9
Reserved
Force Good Link 100
8:6
5
Reserved
Accept Halt
4
Load Seed
3
Burst Mode
2:0
Reserved
Description
R/W
R/W
1—Enable FEFI
0—Disable FEFI
This bit enables/disables far-end fault indicator function for 100Base-FX and
10Base-T operation. It is initialized to the
logic level of FOSEL pin (pin 124, 117, 52,
and 46) at powerup or reset. After reset,
this bit is writable if and only if the FOSEL
register (bit 14 of register 17h) is set.
Reserved.
RO
1—Force good link in 100 Mbit mode
R/W
0—Normal operation
Reserved.
RO
1—Passes halt symbols to the MII
R/W
0—Normal operation
R/W, SC
1—Loads the scrambler seed
0—Normal operation
Setting this bit loads the user seed stored
in register 19h into the 100Base-X scrambler. The content of this bit returns to 0
after the loading process is completed and
no transmit is active.
R/W
1—Burst mode
0—Normal operation
Setting this bit expands the 722 µs scrambler time-out period to 2,000 µs.
Reserved.
RO
Default
Pin
0h
0h
1h
0h
0h
0h
0h
Table 26. PHY Address Register (Register 19h)
Bit(s)
Name
Description
R/W
Default
15:11
10:5
Reserved
User Seed
RO
R/W
0h
21h
4:0
PHY Address
Reserved.
User-modifiable seed data. When the
load seed bit (bit 4 of register 18h) is set,
bits 10 through 0 of this register are
loaded into the 100Base-X scrambler.
These 5 bits store the part address used
by the serial management interface. Top
three of these bits are latched from the
pins during powerup of hard reset. Lower
2 bits are assigned automatically.
R/W
Pin
40
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
MII Registers (continued)
Table 27. Config 10 Register (Register 1Ah)
Bit(s)
Name
Description
R/W
Default
15
SMII Mode
RO
Pin
14
Force 10 Mbit Good Link
R/W
0h
13
12
Reserved
SQE_EN
RO
R/W
0h
0h
11
Low Squelch Select
R/W
0h
10
Jabber Disable
R/W
0h
9
100Meg_Detect
R/W
0h
8
7
Reserved
Digital Filter Disable
RO
R/W
0h
0h
6:4
3
Reserved
Autopolarity Disable
RO
R/W
0h
0h
2:0
Reserved
1—SMII mode
0—SMII mode
This bit is initilized to the logic level of pin
101 at powerup or reset.
1—Force 10 Mbit good link
0—Normal operation
Reserved.
1—Signal quality error test enabled
0—Default SQE is disabled
1—Low squelch level selected
0—Normal squelch level selected
1—Jabber function disabled
0—Normal operation
1—Restart autonegotiation when
LU3X34FTR is in 10 Mbit mode and
detects 100 Mbit data
0—Normal operation
Reserved.
1—Disable digital filter
0—Normal operation
Reserved.
1—Disable autopolarity function
0—Enable autopolarity function
Reserved.
RO
0h
R/W
Default
RO
RO
0h
0h
RO,
LH
RO
0h
0h
R/W
Default
RO
0h
RO
0h
Table 28. Status 100 Register (Register 1Bh)
Bit(s)
Name
15:14
13
Reserved
PLL Lock Status
12
False Carrier Status
11:0
Reserved
Description
Reserved.
1—100 Mbit PLL locked
0—100 Mbit PLL not locked
1—False carrier detected
0—Normal operation
Reserved.
Table 29. Status 10 Register (Register 1Ch)
Bit(s)
Name
15
Polarity
14:0
Reserved
Lucent Technologies Inc.
Description
1—Polarity of cable is swapped
0—Polarity of cables is correct
Reserved.
41
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
MII Registers (continued)
Table 30. Interrupt Mask Register (Register 1Dh)
Bit(s)
Name
15
False Carrier Status
14
13
12
11
10
9
8
7
6:0
Description
0—Enable interrupt
1—Disable interrupt
Receiver Error Counter 0—Enable interrupt
Full
1—Disable interrupt
Reserved
Reserved.
Remote Fault
0—Enable interrupt
1—Disable interrupt
Autonegotiation Com- 0—Enable interrupt
plete
1—Disable interrupt
Link Up
0—Enable interrupt
1—Disable interrupt
Link Down
0—Enable interrupt
1—Disable interrupt
Data Recovery 100 Lock 0—Enable interrupt
Up
1—Disable interrupt
Data Recovery Lock
0—Enable interrupt
Down
1—Disable interrupt
Reserved
Reserved.
R/W
Default
R/W
0h
R/W
0h
R/W
R/W
0h
0h
R/W
0h
R/W
0h
R/W
0h
R/W
0h
R/W
0h
RO
0h
R/W
Default
RO, LH
0h
RO, LH
0h
RO, LH
RO, LH
0h
0h
RO, LH
0h
RO, LH
0h
RO, LH
0h
RO, LH
0h
RO, LH
0h
RO
0h
Table 31. Interrupt Status Register (Register 1Eh)
Bit(s)
Name
15
False Carrier Counter
Full
14
13
12
11
10
9
8
7
6:0
42
Description
1—False carrier counter has rolled over
0—False carrier counter has not rolled
over
Receiver Error Counter 1—Receive error counter has rolled over
Full
0—Receive error counter has not rolled
over
Reserved
Reserved.
Remote Fault
1—Remote fault observed by PHY
0—Remote fault not observed by PHY
Autonegotiation Com- 1—Autonegotiation has completed
plete
0—Autonegotiation has not completed
Link Up
1—Link is up
0—No change on link status
Link Down
1—Link has gone down
0—No change on link status
Data Recovery 100 Lock 1—Data recovery has locked
Up
0—Data recovery is not locked
Data Recovery 100 Lock 1—Data recovery is not locked
Down
0—Data recovery has locked
Reserved
Reserved
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
dc and ac Specifications
Absolute Maximum Ratings
Stresses in excess of the absolute maximum ratings can cause permanent damage to the device. These are absolute stress ratings only. Functional operation of the device is not implied at these or any other conditions in excess
of those given in the operational sections of the data sheet. Exposure to absolute maximum ratings for extended
periods can adversely affect device reliability.
Table 32. Absolute Maximum Ratings
Parameter
Symbol
Min
Max
Unit
Ambient Operating Temperature
Storage Temperature
Voltage on Any Pin with Respect to Ground
Maximum Supply Voltage
TA
Tstg
—
—
0
–65
–0.5
—
70
150
5
5
°C
°C
V
V
Table 33. Operating Conditions
Parameter
Operating Supply Voltage
Power Dissipation:
100 Mbits/s TX with LEDs
100 Mbits/s FX with LEDs
10 Mbits/s with LEDs
Autonegotiating with LEDs
Symbol
—
Min
3.135
Typ*
3.3
Max
3.46
Unit
V
PD
PD
PD
PD
—
—
—
—
—
—
—
—
480
450
480
200
mA
mA
mA
mA
* Typical power dissipations are specified at 3.3 V and 25 °C. This is the power dissipated by the LU3X34FTR.
Table 34. dc Characteristics
Parameter
Symbol
TTL Input High Voltage
VIH
TTL Input Low Voltage
VIL
TTL Output High Voltage
VOH
TTL Output Low Voltage
VOL
LED Output Current
ILED
MII Output Current
IMII
PECL Input High Voltage
VIH
PECL Input Low Voltage
VIL
PECL Output High Voltage
VOH
PECL Output Low Voltage
VOL
Oscillator Input (25 MHz)
XIN
Crystal Freq. Stability
XIN/XOUT
(25 MHz)
Input Capacitance
MII CIN
Lucent Technologies Inc.
Conditions
VDD = 3.3 V, VSS = 0.0 V
VDD = 3.3 V, VSS = 0.0 V
VDD = 3.3 V, VSS = 0.0 V
VDD = 3.3 V, VSS = 0.0 V
—
—
—
—
—
—
—
—
—
Min
Max
2.0
—
—
0.8
2.4
—
—
0.4
—
10
—
4
VDD – 1.16 VDD – 0.88
VDD – 1.81 VDD – 1.47
VDD – 1.02
—
DD
—
V – 1.62
–50
50
–50
50
—
8
Unit
V
V
V
V
mA
mA
V
V
V
V
ppm
ppm
pF
43
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Clock Timing
Table 35. Management Clock
Symbol
t1
t2
t3
t4
t5
t6
Parameter
MDC High Pulse Width
MDC Low Pulse Width
MDC Period
MDIO(I) Setup to MDC Rising Edge
MDIO(O) Hold Time from MDC Rising Edge
MDIO(O) Valid from MDC Rising Edge
Min
Max
Unit
200
200
400
10
10
0
—
—
—
—
—
300
ns
ns
ns
ns
ns
ns
t2
t1
t3
MDC
t5
t4
MDIO(I)
t6
MDIO(O)
5-6786(F).a
Figure 12. Management Clock
44
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Clock Timing (continued)
Table 36. RMII Receive Timing
Symbol
Parameter
Min
Typ
Max
Unit
t1
RXER, CRS_DV, RXD[3:0] Setup to RXCLK
Rise
RXER, CRS_DV, RXD[3:0] Hold After RXCLK
Rise
REF_CLK Period (±50 ppm)
REF_CLK Duty Cycle
4
—
—
ns
2
—
—
ns
20
35
—
—
20
65
ns
%
t2
t3
t4
t3
t1
t4
t4
t2
REF_CLK
RXER, CRS_DV,
RXD[1:0]
5-6787(F).a.r1
Figure 13. RMII Receive Timing
Table 37. RMII Transmit Timing
Symbol
t1
t2
Parameter
Min
Max
Unit
4
2
—
—
ns
ns
TXEN, TXD[1:0] Setup to REF_CLK Rise
TXER, TXEN, TXD[3:0] Hold After TXCLK
Rise
t1
t2
REF_CLK
TXEN,
TXD[1:0]
5-6788(F).a
Figure 14. RMII Transmit Timing
Lucent Technologies Inc.
45
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Clock Timing (continued)
Table 38. Transmit Timing
Symbol
t1
t2
Parameter
Min
Max
Unit
6
4
—
14
—
17
Mbits/s
Mbits/s
Mbits/s
—
5
Mbits/s
Transmit Latency (100 Mbit)
Transmit Latency (10 Mbit)
Sampled TXEN Inactive to End of Frame
(100 Mbit)
Sampled TXEN Inactive to End of Frame
(10 Mbit)
RXCLK
TXEN
t1
TPTX
t2
PREAMBLE
5-6789(F).a.r1
Figure 15. Transmit Timing
Table 39. Receive Timing
Symbol
t1
t2
Parameter
Receive Frame to CRS_DV High (100 Mbit)
Receive Frame to CRS_DV High (10 Mbit)
End of Receive Frame to CRS_DV Low
(100 Mbit)
End of Receive Frame to CRS_DV Low
(10 Mbit)
Min
Max
Unit
—
—
13
20
22
24
Mbits/s
Mbits/s
Mbits/s
—
4.5
Mbits/s
REF_CLK
t1
CRS_DV
t2
TPRX
DATA
5-6790(F).a
Figure 16. Receive Timing
46
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Clock Timing (continued)
Table 40. SMII Timing
Symbol
t1
t2
t3
t4
Parameter
Min
Max
Unit
REF_CLK Period (±50 ppm)
Output Delay
Input Delay
Input Hold
8
2
1.5
1
8
5
—
—
ns
ns
ns
ns
t2
1
t3
2
3
t4
4
t1
5
6
7
8
9
10
11
REF_CLK
SYNC
Rx
Tx
CRS
TXER
RXDV
TXEN
RXD0
TXD0
RXD1
TXD1
RXD2
TXD2
RXD3
TXD3
RXD4
TXD4
RXD5
TXD5
RXD6
TXD6
RXD7
TXD7
5-7508(F).ar1
Figure 17. SMII Timing
Lucent Technologies Inc.
47
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Clock Timing (continued)
Table 41. Reset and Configuration Timing
Symbol
t1
t2
t3
t4
Parameter
Power On to Reset High
Reset Pulse Width
Configuration Pin Setup
Configuration Pin Hold
Min
Max
Unit
0.5
0.5
0.5
0.5
—
—
—
—
ms
ms
ms
ms
VCC
t2
t1
RSTZ
t3
t4
CONFIG
5-6791(F).a
Figure 18. Reset and Configuration Timing
Table 42. PMD Characteristics
Symbol
t1
t2
t3
t4
t5
t6
Parameter
TPTX+/TPTX– Rise Time
TPTX+/TPTX– Fall Time
TP Skew
FOTX+/FOTX– Rise Time
FOTX+/FOTX– Fall Time
FO Skew
Min
Max
Unit
3
3
—
—
—
—
5
5
0.5
—
—
—
ns
ns
ns
ns
ns
ns
t1
t2
TPTX+
t3
TPTX–
t4
t5
FOTX+
t6
FOTX–
5-6792(F)
Figure 19. PMD Characteristics
48
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Clock Timing (continued)
VDD
DIGITAL_VDD
fb
0.1 µF
TX_VDD
22 µF
RX_VDD
fb
1Ω
VDD
CSVCC
4.7 µF
1:1
MAGNETICS
TPTX+
R145
TX+
TX–
RX+
NC
NC
RX–
NC
NC
50 Ω
50 Ω
TPTX–
TPRX+
54 Ω
54 Ω
TPRX–
1000 pF
0.1 µF
0.1 µF
75 Ω
75 Ω
75 Ω
75 Ω
CHASSIS_GND
R1
REF100
R2
REF10
TX_GND
RX_GND
DIGITAL_GND
680 pF—1000 pF 2 kV
CHASSIS_GND
5-7510(F).r4
Figure 20. Connection Diagrams (Single-Channel 10/100BTX Operation)
Lucent Technologies Inc.
49
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Preliminary Data Sheet
July 2000
Outline Diagram
128-Pin SQFP
Dimensions are in millimeters.
17.20 ± 0.25
14.00 ± 0.20
PIN #1
IDENTIFIER ZONE
128
103
1
102
20.00
± 0.20
23.20
± 0.25
38
65
39
64
DETAIL A
DETAIL B
2.72 ± 0.15
3.40 MAX
SEATING PLANE
0.08
0.50 TYP
0.25 MIN
1.60 REF
0.13/0.23
0.25
GAGE PLANE
0.13/0.28
SEATING PLANE
0.12
0.73/1.03
DETAIL A
M
DETAIL B
5-3759(F)
50
Lucent Technologies Inc.
Preliminary Data Sheet
July 2000
LU3X34FTR
Quad 3 V 10/100 Ethernet Transceiver TX/FX
Ordering Information
Device Code
Package
Temperature
ComCode
LU3X34FTR-HS128-DB
128-Pin SQFP with
heat spreader
0 °C to 70 °C
1085571900
Lucent Technologies Inc.
51
For additional information, contact your Microelectronics Group Account Manager or the following:
http://www.lucent.com/micro
INTERNET:
[email protected]
E-MAIL:
N. AMERICA: Microelectronics Group, Lucent Technologies Inc., 555 Union Boulevard, Room 30L-15P-BA, Allentown, PA 18109-3286
1-800-372-2447, FAX 610-712-4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106)
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200233 P. R. China Tel. (86) 21 6440 0468, ext. 325, FAX (86) 21 6440 0652
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Tel. (81) 3 5421 1600, FAX (81) 3 5421 1700
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Lucent Technologies Inc. reserves the right to make changes to the product(s) or information contained herein without notice. No liability is assumed as a result of their use or application. No
rights under any patent accompany the sale of any such product(s) or information.
Copyright © 2000 Lucent Technologies Inc.
All Rights Reserved
July 2000
DS00-215LAN (Replaces DS99-247LAN)