MICREL KSZ8051MLLI

KSZ8051MLL
10Base-T/100Base-TX
Physical Layer Transceiver
Data Sheet Rev. 1.0
General Description
Features
The KSZ8051MLL is a single-supply 10Base-T/100BaseTX Ethernet physical layer transceiver for transmission
and reception of data over standard CAT-5 unshielded
twisted pair (UTP) cable.
The KSZ8051MLL is a highly-integrated, compact solution.
It reduces board cost and simplifies board layout by using
on-chip termination resistors for the differential pairs and
by integrating a low-noise regulator to supply the 1.2V
core.
The KSZ8051MLL offers the Media Independent Interface
(MII) for direct connection with MII-compliant Ethernet
MAC processors and switches.
The KSZ8051MLL provides diagnostic features to facilitate
system bring-up and debugging in production testing and
in product deployment. Parametric NAND tree support
enables fault detection between KSZ8051MLL I/Os and
®
board. Micrel LinkMD TDR-based cable diagnostics
permit identification of faulty copper cabling. Remote and
local loopback functions provide verification of analog and
digital data paths.
The KSZ8051MLL is available in the 48-pin, lead-free
LQFP package (See Ordering Information).
Data sheets and support documentation can be found on
Micrel’s web site at www.micrel.com.
• Single-chip 10Base-T/100Base-TX IEEE 802.3
compliant Ethernet Transceiver
• MII Interface support
• Back-to-Back mode support for 100Mbps copper
repeater or media converter
• MDC/MDIO Management Interface for PHY register
configuration
• Programmable interrupt output
• LED outputs for link, activity and speed status indication
• On-chip termination resistors for the differential pairs
• Baseline Wander Correction
• HP Auto MDI/MDI-X for reliable detection and
correction for straight-through and crossover cables
with disable and enable option
• Auto-negotiation to automatically select the highest link
up speed (10/100 Mbps) and duplex (half/full)
• Power-down and power-saving modes
• LinkMD® TDR-based cable diagnostics for identification
of faulty copper cabling
• Parametric NAND Tree support for fault detection
between chip I/Os and board.
• Loopback modes for diagnostics
• Single 3.3V power supply with VDD I/O options for
1.8V, 2.5V, or 3.3V
• Built-in 1.2V regulator for core
• Available in 48-pin (7mm x 7mm) LQFP package
____________________________________________________________________________________________________________
Functional Diagram
LinkMD is a registered trademark of Micrel, Inc.
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
July 2010
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Micrel, Inc.
KSZ8051MLL
Applications
•
•
•
•
•
•
Game Console
IP Phone
IP Set-top Box
IP TV
LOM
Printer
Ordering Information
Part Number
KSZ8051MLL
KSZ8051MLLI
(1)
Temperature Range
Package
Lead Finish
Description
0°C to +70°C
48-Pin LQFP
Pb-Free
MII, Commercial Temperature
−40°C to +85°C
48-Pin LQFP
Pb-Free
MII, Industrial Temperature
Note:
1.
Contact factory for lead time.
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Revision History
Revision
Date
Summary of Changes
1.0
6/22/10
Data sheet created.
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Contents
General Description .............................................................................................................................................................. 1
Features ................................................................................................................................................................................. 1
Functional Diagram............................................................................................................................................................... 1
Applications........................................................................................................................................................................... 2
Ordering Information ............................................................................................................................................................ 2
Revision History.................................................................................................................................................................... 3
Contents................................................................................................................................................................................. 4
List of Figures........................................................................................................................................................................ 6
List of Tables ......................................................................................................................................................................... 7
Pin Configuration – KSZ8051MLL ....................................................................................................................................... 8
Pin Description – KSZ8051MLL ........................................................................................................................................... 9
Pin Description – KSZ8051MLL (Continued).................................................................................................................... 10
Pin Description – KSZ8051MLL (Continued).................................................................................................................... 11
Pin Description – KSZ8051MLL (Continued).................................................................................................................... 12
Strapping Options – KSZ8051MLL .................................................................................................................................... 13
Functional Description: 10Base-T/100Base-TX Transceiver ......................................................................................... 14
100Base-TX Transmit....................................................................................................................................................... 14
100Base-TX Receive........................................................................................................................................................ 14
10Base-T Transmit ........................................................................................................................................................... 14
10Base-T Receive ............................................................................................................................................................ 14
Scrambler/De-Scrambler (100Base-TX Only) .................................................................................................................. 15
SQE and Jabber Function (10Base-T Only)..................................................................................................................... 15
PLL Clock Synthesizer...................................................................................................................................................... 15
Auto-Negotiation ............................................................................................................................................................... 15
MII Data Interface ................................................................................................................................................................ 16
MII Signal Definition.......................................................................................................................................................... 17
Transmit Clock (TXC) ................................................................................................................................................... 17
Transmit Enable (TXEN) .............................................................................................................................................. 17
Transmit Data [3:0] (TXD[3:0]) ..................................................................................................................................... 17
Receive Clock (RXC).................................................................................................................................................... 17
Receive Data Valid (RXDV).......................................................................................................................................... 17
Receive Data[3:0] (RXD[3:0]) ....................................................................................................................................... 18
Receive Error (RXER) .................................................................................................................................................. 18
Carrier Sense (CRS) .................................................................................................................................................... 18
Collision (COL) ............................................................................................................................................................. 18
MII Signal Diagram ........................................................................................................................................................... 18
Back-to-Back Mode – 100Mbps Copper Repeater / Media Converter............................................................................ 19
MII Back-to-Back Mode (KSZ8051MLL only) ................................................................................................................... 19
MII Management (MIIM) Interface....................................................................................................................................... 20
Interrupt (INTRP) ................................................................................................................................................................. 20
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HP Auto MDI/MDI-X ............................................................................................................................................................. 21
Straight Cable ................................................................................................................................................................... 21
Crossover Cable ............................................................................................................................................................... 22
LinkMD® Cable Diagnostics................................................................................................................................................ 22
NAND Tree Support ............................................................................................................................................................ 23
NAND Tree I/O Testing..................................................................................................................................................... 24
Power Management ............................................................................................................................................................ 25
Power Saving Mode.......................................................................................................................................................... 25
Energy Detect Power-Down Mode ................................................................................................................................... 25
Power-Down Mode ........................................................................................................................................................... 25
Slow Oscillator Mode ........................................................................................................................................................ 25
Reference Circuit for Power and Ground Connections .................................................................................................. 26
Register Map........................................................................................................................................................................ 27
Register Description ........................................................................................................................................................... 27
Register Description (Continued)...................................................................................................................................... 28
Register Description (Continued)...................................................................................................................................... 29
Register Description (Continued)...................................................................................................................................... 30
Register Description (Continued)...................................................................................................................................... 31
Register Description (Continued)...................................................................................................................................... 32
Register Description (Continued)...................................................................................................................................... 33
Register Description (Continued)...................................................................................................................................... 34
Register Description (Continued)...................................................................................................................................... 35
Register Description (Continued)...................................................................................................................................... 36
Absolute Maximum Ratings(1) ............................................................................................................................................ 37
Operating Ratings(2) ............................................................................................................................................................ 37
Electrical Characteristics(3) ................................................................................................................................................ 37
Electrical Characteristics(3) (Continued) ........................................................................................................................... 38
Timing Diagrams ................................................................................................................................................................. 39
MII SQE Timing (10Base-T) ............................................................................................................................................. 39
MII Transmit Timing (10Base-T) ....................................................................................................................................... 40
MII Receive Timing (10Base-T) ........................................................................................................................................ 41
MII Transmit Timing (100Base-TX) .................................................................................................................................. 42
MII Receive Timing (100Base-TX) ................................................................................................................................... 43
Auto-Negotiation Timing ................................................................................................................................................... 44
MDC/MDIO Timing ........................................................................................................................................................... 45
Reset Timing..................................................................................................................................................................... 46
Reset Circuit ........................................................................................................................................................................ 47
Reference Circuits for LED Strapping Pins...................................................................................................................... 48
Magnetics Specification ..................................................................................................................................................... 49
Reference Clock – Connection and Selection.................................................................................................................. 50
Package Information........................................................................................................................................................... 51
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List of Figures
Figure 1. Auto-Negotiation Flow Chart........................................................................................................................... 16
Figure 2. KSZ8051MLL MII Interface............................................................................................................................. 18
Figure 3. KSZ8051MLL and KSZ8041FTL Back-to-Back Media Converter .................................................................. 19
Figure 4. Typical Straight Cable Connection ................................................................................................................. 21
Figure 5. Typical Crossover Cable Connection ............................................................................................................. 22
Figure 6. KSZ8051MLL Power and Ground Connections ............................................................................................. 26
Figure 7. MII SQE Timing (10Base-T) ........................................................................................................................... 39
Figure 8. MII Transmit Timing (10Base-T) ..................................................................................................................... 40
Figure 9. MII Receive Timing (10Base-T) ...................................................................................................................... 41
Figure 10. MII Transmit Timing (100Base-TX)............................................................................................................... 42
Figure 11. MII Receive Timing (100Base-TX)................................................................................................................ 43
Figure 12. Auto-Negotiation Fast Link Pulse (FLP) Timing ........................................................................................... 44
Figure 13. MDC/MDIO Timing........................................................................................................................................ 45
Figure 14. Reset Timing................................................................................................................................................. 46
Figure 15. Recommended Reset Circuit........................................................................................................................ 47
Figure 16. Recommended Reset Circuit for interfacing with CPU/FPGA Reset Output................................................ 47
Figure 17. Reference Circuits for LED Strapping Pins................................................................................................... 48
Figure 18. 25MHz Crystal / Oscillator Reference Clock Connection ............................................................................. 50
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List of Tables
Table 1. MII Signal Definition ......................................................................................................................................... 17
Table 2. MII Signal Connection for MII Back-to-Back Mode (100Base-TX Copper Repeater)...................................... 19
Table 3. MII Management Frame Format – for KSZ8051MLL....................................................................................... 20
Table 4. MDI/MDI-X Pin Definition ................................................................................................................................. 21
Table 5. NAND Tree Test Pin Order – for KSZ8051MLL............................................................................................... 23
Table 6. KSZ8051MLL Power Pin Description............................................................................................................... 26
Table 7. MII SQE Timing (10Base-T) Parameters ......................................................................................................... 39
Table 8. MII Transmit Timing (10Base-T) Parameters .................................................................................................. 40
Table 9. MII Receive Timing (10Base-T) Parameters ................................................................................................... 41
Table 10. MII Transmit Timing (100Base-TX) Parameters ............................................................................................ 42
Table 11. MII Receive Timing (100Base-TX) Parameters ............................................................................................. 43
Table 12. Auto-Negotiation Fast Link Pulse (FLP) Timing Parameters ......................................................................... 44
Table 13. MDC/MDIO Timing Parameters ..................................................................................................................... 45
Table 14. Reset Timing Parameters .............................................................................................................................. 46
Table 15. Magnetics Selection Criteria .......................................................................................................................... 49
Table 16. Qualified Single Port 10/100 Magnetics......................................................................................................... 49
Table 17. 25MHz Crystal / Reference Clock Selection Criteria ..................................................................................... 50
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Pin Configuration – KSZ8051MLL
48-Pin (7mm x 7mm) LQFP
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KSZ8051MLL
Pin Description – KSZ8051MLL
Pin Number
(1)
Pin Name
Type
Pin Function
1
GND
Gnd
Ground
2
GND
Gnd
Ground
3
GND
Gnd
Ground
4
VDD_1.2
P
1.2V core VDD
(power supplied by KSZ8051MLL)
Decouple with 2.2uF and 0.1uF capacitors to ground, and join with pin 31 by power
trace or plane.
5
NC
-
No connect
6
NC
-
No connect
7
VDDA_3.3
P
3.3V analog VDD
8
NC
-
No connect
9
RXM
I/O
Physical receive or transmit signal (- differential)
10
RXP
I/O
Physical receive or transmit signal (+ differential)
11
TXM
I/O
Physical transmit or receive signal (- differential)
12
TXP
I/O
Physical transmit or receive signal (+ differential)
13
GND
Gnd
Ground
14
XO
O
Crystal feedback – for 25 MHz crystal
This pin is a no connect if oscillator or external clock source is used.
15
XI
I
Crystal / Oscillator / External Clock Input
25MHz +/-50ppm
16
REXT
I
Set PHY transmit output current
17
GND
Gnd
Ground
18
MDIO
I/O
Management Interface (MII) Data I/O
Connect a 6.49KΩ resistor to ground on this pin.
This pin has a weak pull-up, is open-drain like, and requires an external 1.0KΩ
pull-up resistor.
19
MDC
I
Management Interface (MII) Clock Input
This clock pin is synchronous to the MDIO data pin.
20
RXD3 /
Ipu/O
PHYAD0
21
RXD2 /
Ipd/O
PHYAD1
22
RXD1 /
Ipd/O
PHYAD2
23
RXD0 /
Ipu/O
DUPLEX
(2)
MII Mode:
MII Receive Data Output[3]
Config Mode:
The pull-up/pull-down value is latched as PHYADDR[0] at the
de-assertion of reset. See Strapping Options section for details.
MII Mode:
MII Receive Data Output[2]
Config Mode:
The pull-up/pull-down value is latched as PHYADDR[1] at the
de-assertion of reset. See Strapping Options section for details.
MII Mode:
MII Receive Data Output[1]
Config Mode:
The pull-up/pull-down value is latched as PHYADDR[2] at the
de-assertion of reset. See Strapping Options section for details.
MII Mode:
MII Receive Data Output[0]
Config Mode:
The pull-up/pull-down value is latched as DUPLEX at the
de-assertion of reset. See Strapping Options section for details.
(2)
(2)
(2)
24
GND
Gnd
Ground
25
VDDIO
P
3.3V, 2.5V or 1.8V digital VDD
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Pin Description – KSZ8051MLL (Continued)
(1)
Pin Number
Pin Name
Type
Pin Function
26
NC
-
No connect
RXDV /
Ipd/O
MII Mode:
MII Receive Data Valid Output /
Config Mode:
The pull-up/pull-down value is latched as CONFIG2 at the
de-assertion of reset. See Strapping Options section for details.
27
CONFIG2
28
RXC /
Ipd/O
B-CAST_OFF
29
RXER /
Ipd/O
ISO
MII Mode:
MII Receive Clock Output
Config Mode:
The pull-up/pull-down value is latched as B-CAST_OFF at the
de-assertion of reset. See Strapping Options section for details.
MII Mode:
MII Receive Error Output /
Config Mode:
The pull-up/pull-down value is latched as ISOLATE at the
de-assertion of reset. See Strapping Options section for details.
30
GND
Gnd
Ground
31
VDD_1.2
P
1.2V core VDD
(power supplied by KSZ8051MLL)
Decouple with 0.1uF capacitor to ground, and join with pin 4 by power trace or plane.
32
INTRP /
Ipu/Opu
NAND_Tree#
Interrupt Output: Programmable Interrupt Output
This pin has a weak pull-up, is open-drain like, and requires an external 1.0KΩ
pull-up resistor.
Config Mode:
33
TXC
I/O
The pull-up/pull-down value is latched as NAND Tree# at the
de-assertion of reset. See Strapping Options section for details.
MII Mode:
MII Transmit Clock Output
MII Back-to-Back Mode:
MII Transmit Clock Input
34
TXEN
I
MII Mode:
MII Transmit Enable Input
35
TXD0
I
MII Mode:
MII Transmit Data Input[0]
36
TXD1
I
MII Mode:
MII Transmit Data Input[1]
37
GND
Gnd
Ground
38
TXD2
I
MII Mode:
MII Transmit Data Input[2]
39
TXD3
I
MII Mode:
MII Transmit Data Input[3]
40
COL /
Ipd/O
MII Mode:
MII Collision Detect Output /
Config Mode:
The pull-up/pull-down value is latched as CONFIG0 at the
de-assertion of reset. See Strapping Options section for details.
MII Mode:
MII Carrier Sense Output /
Config Mode:
The pull-up/pull-down value is latched as CONFIG1 at the
de-assertion of reset. See Strapping Options section for details.
CONFIG0
41
CRS /
CONFIG1
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Ipd/O
(3)
(3)
(3)
(3)
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KSZ8051MLL
Pin Description – KSZ8051MLL (Continued)
(1)
Pin Number
Pin Name
Type
Pin Function
42
LED0 /
Ipu/O
LED Output:
Programmable LED0 Output /
Config Mode:
Latched as Auto-Negotiation Enable (register 0h, bit 12) at the
de-assertion of reset. See Strapping Options section for details.
NWAYEN
The LED0 pin is programmable via register 1Fh bits [5:4], and is defined as follows.
LED mode = [00]
Link/Activity
Pin State
LED Definition
No Link
High
OFF
Link
Low
ON
Activity
Toggle
Blinking
Pin State
LED Definition
LED mode = [01]
Link
No Link
High
OFF
Link
Low
ON
LED mode = [10], [11]
43
LED1 /
Ipu/O
SPEED
Reserved
LED Output:
Programmable LED1 Output /
Config Mode:
Latched as SPEED (register 0h, bit 13) at the de-assertion of reset.
See Strapping Options section for details.
The LED1 pin is programmable via register 1Fh bits [5:4], and is defined as follows.
LED mode = [00]
Speed
Pin State
LED Definition
10Base-T
High
OFF
100Base-TX
Low
ON
Activity
Pin State
LED Definition
No Activity
High
OFF
Activity
Toggle
Blinking
LED mode = [01]
LED mode = [10], [11]
44
NC
-
No connect
45
NC
-
No connect
46
NC
-
No connect
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Reserved
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KSZ8051MLL
Pin Description – KSZ8051MLL (Continued)
(1)
Pin Number
Pin Name
Type
Pin Function
47
RST#
I
Chip Reset (active low)
48
NC
-
No connect
Notes:
1.
P = Power supply.
Gnd = Ground.
I = Input.
O = Output.
I/O = Bi-directional.
Ipu/O = Input with internal pull-up (see Electrical Characteristics for value) during power-up/reset; output pin otherwise.
Ipd/O = Input with internal pull-down (see Electrical Characteristics for value) during power-up/reset; output pin otherwise.
Ipu/Opu = Input with internal pull-up (see Electrical Characteristics for value) during power-up/reset; output pin with internal pull-up (see
Electrical Characteristics for value) otherwise.
2.
MII Rx Mode: The RXD[3:0] bits are synchronous with RXC. When RXDV is asserted, RXD[3:0] presents valid data to the MAC. RXD[3:0] is
invalid data from the PHY when RXDV is de-asserted.
3.
MII Tx Mode: The TXD[3:0] bits are synchronous with TXC. When TXEN is asserted, TXD[3:0] presents valid data from the MAC. TXD[3:0]
has no effect on the PHY when TXEN is de-asserted.
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Strapping Options – KSZ8051MLL
Pin Number
Pin Name
(1)
Type
Pin Function
22
PHYAD2
Ipd/O
21
PHYAD1
Ipd/O
The PHY Address is latched at de-assertion of reset and is configurable to any value
from 0 to 7.
20
PHYAD0
Ipu/O
The default PHY Address is 00001.
PHY Address 00000 is enabled only if the B-CAST_OFF strapping pin is pulled high.
PHY Address bits [4:3] are set to ‘00’ by default.
The CONFIG[2:0] strap-in pins are latched at the de-assertion of reset.
27
CONFIG2
Ipd/O
41
CONFIG1
Ipd/O
CONFIG[2:0]
Mode
40
CONFIG0
Ipd/O
000
MII (default)
110
MII Back-to-Back
001 – 101, 111
Reserved – not used
29
ISO
Ipd/O
ISOLATE mode
Pull-up = Enable
Pull-down (default) = Disable
At the de-assertion of reset, this pin value is latched into register 0h bit 10.
43
SPEED
Ipu/O
SPEED mode
Pull-up (default) = 100Mbps
Pull-down = 10Mbps
At the de-assertion of reset, this pin value is latched into register 0h bit 13 as the
Speed Select, and also is latched into register 4h (Auto-Negotiation Advertisement)
as the Speed capability support.
23
DUPLEX
Ipu/O
DUPLEX mode
Pull-up (default) = Half Duplex
Pull-down = Full Duplex
At the de-assertion of reset, this pin value is latched into register 0h bit 8.
42
NWAYEN
Ipu/O
Nway Auto-Negotiation Enable
Pull-up (default) = Enable Auto-Negotiation
Pull-down = Disable Auto-Negotiation
At the de-assertion of reset, this pin value is latched into register 0h bit 12.
28
B-CAST_OFF
Ipd/O
Broadcast Off – for PHY Address 0
Pull-up = PHY Address 0 is set as an unique PHY address
Pull-down (default) = PHY Address 0 is set as a broadcast PHY address
At the de-assertion of reset, this pin value is latched by the chip.
32
NAND_Tree#
Ipu/Opu
NAND Tree Mode
Pull-up (default) = Disable
Pull-down = Enable
At the de-assertion of reset, this pin value is latched by the chip.
Note:
1.
Ipu/O = Input with internal pull-up (see Electrical Characteristics for value) during power-up/reset; output pin otherwise.
Ipd/O = Input with internal pull-down (see Electrical Characteristics for value) during power-up/reset; output pin otherwise.
Ipu/Opu = Input with internal pull-up (see Electrical Characteristics for value) during power-up/reset; output pin with internal pull-up (see Electrical
Characteristics for value) otherwise.
The strap-in pins are latched at the de-assertion of reset. In some systems, the MAC MII receive input pins may drive
high/low during power-up or reset, and consequently cause the PHY strap-in pins on the MII signals to be latched to the
unintended high/low states. In this case, external pull-ups (4.7K) or pull-downs (1.0K) should be added on these PHY
strap-in pins to ensure the intended values are strapped-in correctly.
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KSZ8051MLL
Functional Description: 10Base-T/100Base-TX Transceiver
The KSZ8051MLL is an integrated single 3.3V supply Fast Ethernet transceiver. It is fully compliant with the IEEE 802.3
Specification, and reduces board cost and simplifies board layout by using on-chip termination resistors for the two
differential pairs and by integrating the regulator to supply the 1.2V core.
On the copper media side, the KSZ8051MLL supports 10Base-T and 100Base-TX for transmission and reception of data
over a standard CAT-5 unshielded twisted pair (UTP) cable, and HP auto MDI/MDI-X for reliable detection of and
correction for straight-through and crossover cables.
On the MAC processor side, the KSZ8051MLL offers the Media Independent Interface (MII) for direct connection with MII
compliant Ethernet MAC processors and switches.
The MII management bus option gives the MAC processor complete access to the KSZ8051MLL control and status
registers. Additionally, an interrupt pin eliminates the need for the processor to poll for PHY status change.
100Base-TX Transmit
The 100Base-TX transmit function performs parallel-to-serial conversion, 4B/5B encoding, scrambling, NRZ-to-NRZI
conversion, and MLT3 encoding and transmission.
The circuitry starts with a parallel-to-serial conversion, which converts the MII data from the MAC into a 125MHz serial bit
stream. The data and control stream is then converted into 4B/5B coding and followed by a scrambler. The serialized data
is further converted from NRZ-to-NRZI format, and then transmitted in MLT3 current output. The output current is set by
an external 6.49kΩ 1% resistor for the 1:1 transformer ratio.
The output signal has a typical rise/fall time of 4ns and complies with the ANSI TP-PMD standard regarding amplitude
balance, overshoot, and timing jitter. The wave-shaped 10Base-T output is also incorporated into the 100Base-TX
transmitter.
100Base-TX Receive
The 100Base-TX receiver function performs adaptive equalization, DC restoration, MLT3-to-NRZI conversion, data and
clock recovery, NRZI-to-NRZ conversion, de-scrambling, 4B/5B decoding, and serial-to-parallel conversion.
The receiving side starts with the equalization filter to compensate for inter-symbol interference (ISI) over the twisted pair
cable. Since the amplitude loss and phase distortion is a function of the cable length, the equalizer must adjust its
characteristics to optimize performance. In this design, the variable equalizer makes an initial estimation based on
comparisons of incoming signal strength against some known cable characteristics, and then tunes itself for optimization.
This is an ongoing process and self-adjusts against environmental changes such as temperature variations.
Next, the equalized signal goes through a DC restoration and data conversion block. The DC restoration circuit is used to
compensate for the effect of baseline wander and to improve the dynamic range. The differential data conversion circuit
converts the MLT3 format back to NRZI. The slicing threshold is also adaptive.
The clock recovery circuit extracts the 125MHz clock from the edges of the NRZI signal. This recovered clock is then used
to convert the NRZI signal into the NRZ format. This signal is sent through the de-scrambler followed by the 4B/5B
decoder. Finally, the NRZ serial data is converted to the MII format and provided as the input data to the MAC.
10Base-T Transmit
The 10Base-T drivers are incorporated with the 100Base-TX drivers to allow for transmission using the same magnetic.
The drivers perform internal wave-shaping and pre-emphasis, and output 10Base-T signals with typical amplitude of 2.5V
peak. The 10Base-T signals have harmonic contents that are at least 27dB below the fundamental frequency when driven
by an all-ones Manchester-encoded signal.
10Base-T Receive
On the receive side, input buffer and level detecting squelch circuits are employed. A differential input receiver circuit and
a PLL performs the decoding function. The Manchester-encoded data stream is separated into clock signal and NRZ data.
A squelch circuit rejects signals with levels less than 400 mV or with short pulse widths to prevent noise at the RXP and
RXM inputs from falsely trigger the decoder. When the input exceeds the squelch limit, the PLL locks onto the incoming
signal and the KSZ8051MLL decodes a data frame. The receive clock is kept active during idle periods in between data
reception.
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KSZ8051MLL
Scrambler/De-Scrambler (100Base-TX Only)
The scrambler is used to spread the power spectrum of the transmitted signal to reduce EMI and baseline wander, and
the de-scrambler is needed to recover the scrambled signal.
SQE and Jabber Function (10Base-T Only)
In 10Base-T operation, a short pulse is put out on the COL pin after each frame is transmitted. This SQE Test is required
as a test of the 10Base-T transmit/receive path. If transmit enable (TXEN) is high for more than 20 ms (jabbering), the
10Base-T transmitter is disabled and COL is asserted high. If TXEN is then driven low for more than 250 ms, the 10BaseT transmitter is re-enabled and COL is de-asserted (returns to low).
PLL Clock Synthesizer
The KSZ8051MLL generates all internal clocks and all external clocks for system timing from an external 25MHz crystal,
oscillator, or reference clock.
Auto-Negotiation
The KSZ8051MLL conforms to the auto-negotiation protocol, defined in Clause 28 of the IEEE 802.3 Specification.
Auto-negotiation allows UTP (Unshielded Twisted Pair) link partners to select the highest common mode of operation.
During auto-negotiation, link partners advertise capabilities across the UTP link to each other, and then compare their own
capabilities with those they received from their link partners. The highest speed and duplex setting that is common to the
two link partners is selected as the mode of operation.
The following list shows the speed and duplex operation mode from highest to lowest priority.
•
Priority 1: 100Base-TX, full-duplex
•
Priority 2: 100Base-TX, half-duplex
•
Priority 3: 10Base-T, full-duplex
•
Priority 4: 10Base-T, half-duplex
If auto-negotiation is not supported or the KSZ8051MLL link partner is forced to bypass auto-negotiation, then the
KSZ8051MLL sets its operating mode by observing the signal at its receiver. This is known as parallel detection, and
allows the KSZ8051MLL to establish link by listening for a fixed signal protocol in the absence of auto-negotiation
advertisement protocol.
Auto-negotiation is enabled by either hardware pin strapping (NWAYEN, pin 42) or software (register 0h, bit 12).
By default, auto-negotiation is enabled after power-up or hardware reset. Afterwards, auto-negotiation can be enabled or
disabled by register 0h, bit 12. If auto-negotiation is disabled, the speed is set by register 0h, bit 13, and the duplex is set
by register 0h, bit 8.
The auto-negotiation link up process is shown in Figure 1.
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KSZ8051MLL
Figure 1. Auto-Negotiation Flow Chart
MII Data Interface
The Media Independent Interface (MII) is compliant with the IEEE 802.3 Specification. It provides a common interface
between MII PHYs and MACs, and has the following key characteristics:
•
Pin count is 15 pins (6 pins for data transmission, 7 pins for data reception, and 2 pins for carrier and collision
indication).
•
10Mbps and 100Mbps data rates are supported at both half and full duplex.
•
Data transmission and reception are independent and belong to separate signal groups.
•
Transmit data and receive data are each 4-bit wide, a nibble.
By default, the KSZ8051MLL is configured to MII mode after it is powered up or hardware reset with the following:
•
A 25MHz crystal connected to XI, XO (pins 15, 14), or an external 25MHz clock source (oscillator) connected to
XI.
•
The CONFIG[2:0] strapping pins (pins 27, 41, 40) set to ‘000’ (default setting).
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KSZ8051MLL
MII Signal Definition
Table 1 describes the MII signals. Refer to Clause 22 of the IEEE 802.3 Specification for detailed information.
Direction
(with respect to PHY,
KSZ8051MLL signal)
Direction
(with respect to MAC)
Output
Input
TXEN
Input
Output
Transmit Enable
TXD[3:0]
Input
Output
Transmit Data [3:0]
Output
Input
RXDV
Output
Input
Receive Data Valid
RXD[3:0]
Output
Input
Receive Data [3:0]
RXER
Output
Input, or (not required)
Receive Error
CRS
Output
Input
Carrier Sense
COL
Output
Input
Collision Detection
MII Signal Name
TXC
RXC
Description
Transmit Clock
(2.5MHz for 10Mbps; 25MHz for 100Mbps)
Receive Clock
(2.5MHz for 10Mbps; 25MHz for 100Mbps)
Table 1. MII Signal Definition
Transmit Clock (TXC)
TXC is sourced by the PHY. It is a continuous clock that provides the timing reference for TXEN and TXD[3:0].
TXC is 2.5MHz for 10Mbps operation and 25MHz for 100Mbps operation.
Transmit Enable (TXEN)
TXEN indicates the MAC is presenting nibbles on TXD[3:0] for transmission. It is asserted synchronously with the first
nibble of the preamble and remains asserted while all nibbles to be transmitted are presented on the MII, and is negated
prior to the first TXC following the final nibble of a frame.
TXEN transitions synchronously with respect to TXC.
Transmit Data [3:0] (TXD[3:0])
TXD[3:0] transitions synchronously with respect to TXC. When TXEN is asserted, TXD[3:0] are accepted for transmission
by the PHY. TXD[3:0] is ”00” to indicate idle when TXEN is de-asserted. Values other than “00” on TXD[3:0] while TXEN
is de-asserted are ignored by the PHY.
Receive Clock (RXC)
RXC provides the timing reference for RXDV, RXD[3:0], and RXER.
•
In 10Mbps mode, RXC is recovered from the line while carrier is active. RXC is derived from the PHY’s reference
clock when the line is idle, or link is down.
•
In 100Mbps mode, RXC is continuously recovered from the line. If link is down, RXC is derived from the PHY’s
reference clock.
RXC is 2.5MHz for 10Mbps operation and 25MHz for 100Mbps operation.
Receive Data Valid (RXDV)
RXDV is driven by the PHY to indicate that the PHY is presenting recovered and decoded nibbles on RXD[3:0].
•
In 10Mbps mode, RXDV is asserted with the first nibble of the SFD (Start of Frame Delimiter), “5D”, and remains
asserted until the end of the frame.
• In 100Mbps mode, RXDV is asserted from the first nibble of the preamble to the last nibble of the frame.
RXDV transitions synchronously with respect to RXC.
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KSZ8051MLL
Receive Data[3:0] (RXD[3:0])
RXD[3:0] transitions synchronously with respect to RXC. For each clock period in which RXDV is asserted, RXD[3:0]
transfers a nibble of recovered data from the PHY.
Receive Error (RXER)
RXER is asserted for one or more RXC periods to indicate that a Symbol Error (e.g. a coding error that a PHY is capable
of detecting, and that may otherwise be undetectable by the MAC sub-layer) was detected somewhere in the frame
presently being transferred from the PHY.
RXER transitions synchronously with respect to RXC. While RXDV is de-asserted, RXER has no effect on the MAC.
Carrier Sense (CRS)
CRS is asserted and de-asserted as follows:
•
In 10Mbps mode, CRS assertion is based on the reception of valid preambles. CRS de-assertion is based on the
reception of an end-of-frame (EOF) marker.
•
In 100Mbps mode, CRS is asserted when a start-of-stream delimiter, or /J/K symbol pair is detected. CRS is deasserted when an end-of-stream delimiter, or /T/R symbol pair is detected. Additionally, the PMA layer de-asserts
CRS if IDLE symbols are received without /T/R.
Collision (COL)
COL is asserted in half-duplex mode whenever the transmitter and receiver are simultaneously active on the line. This is
used to inform the MAC that a collision has occurred during its transmission to the PHY.
COL transitions asynchronously with respect to TXC and RXC.
MII Signal Diagram
The KSZ8051MLL MII pin connections to the MAC are shown in Figure 2.
Figure 2. KSZ8051MLL MII Interface
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KSZ8051MLL
Back-to-Back Mode – 100Mbps Copper Repeater / Media Converter
Two KSZ8051MLL devices can be connected back-to-back to form a 100Base-TX to 100Base-TX copper repeater.
A KSZ8051MLL and a KSZ8041FTL can be connected back-to-back to provide a low-cost media converter solution.
Media conversion is between 100Base-TX copper and 100Base-FX fiber. On the copper side, link up at 10Base-T is not
allowed, and is blocked during auto-negotiation.
Figure 3. KSZ8051MLL and KSZ8041FTL Back-to-Back Media Converter
MII Back-to-Back Mode (KSZ8051MLL only)
In MII Back-to-Back mode, a KSZ8051MLL interfaces with another KSZ8051MLL, or a KSZ8041FTL to provide a
complete 100Mbps copper repeater, or media converter solution, respectively.
The KSZ8051MLL devices are configured to MII Back-to-Back mode after power-up or reset with the following:
•
Strapping pin CONFIG[2:0] (pins 27, 41, 40) set to ‘110’
•
A common 25MHz reference clock connected to XI (pin 15)
•
MII signals connected as shown in Table 2.
KSZ8051MLL (100Base-TX copper)
KSZ8051MLL (100Base-TX copper)
[Device 1]
[Device 2]
Pin Name
Pin Number
Pin Type
Pin Name
Pin Number
Pin Type
RXC
28
Output
TXC
33
Input
RXDV
27
Output
TXEN
34
Input
RXD3
20
Output
TXD3
39
Input
RXD2
21
Output
TXD2
38
Input
RXD1
22
Output
TXD1
36
Input
RXD0
23
Output
TXD0
35
Input
TXC
33
Input
RXC
28
Output
TXEN
34
Input
RXDV
27
Output
TXD3
39
Input
RXD3
20
Output
TXD2
38
Input
RXD2
21
Output
TXD1
36
Input
RXD1
22
Output
TXD0
35
Input
RXD0
23
Output
Table 2. MII Signal Connection for MII Back-to-Back Mode (100Base-TX Copper Repeater)
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KSZ8051MLL
MII Management (MIIM) Interface
The KSZ8051MLL supports the IEEE 802.3 MII Management Interface, also known as the Management Data Input /
Output (MDIO) Interface. This interface enables upper-layer device, like a MAC processor, to monitor and control the state
of the KSZ8051MLL. An external device with MIIM capability is used to read the PHY status and/or configure the PHY
settings. Further details on the MIIM interface can be found in Clause 22.2.4 of the IEEE 802.3 Specification.
The MIIM interface consists of the following:
•
A physical connection that incorporates the clock line (MDC) and the data line (MDIO).
•
A specific protocol that operates across the aforementioned physical connection that allows the external controller
to communicate with one or more PHY devices.
•
A set of 16-bit MDIO registers. Registers [0:8] are standard registers, and their functions are defined per the IEEE
802.3 Specification. The additional registers are provided for expanded functionality. See “Register Map” section
for details.
As the default, the KSZ8051MLL supports unique PHY addresses 1 to 7, and broadcast PHY address 0. The latter is
defined per the IEEE 802.3 Specification, and can be used to read/write to a single KSZ8051MLL device, or write to
multiple KSZ8051MLL devices simultaneously.
Optionally, PHY address 0 can be disabled as the broadcast address by either hardware pin strapping (B-CAST_OFF, pin
28) or software (register 16h, bit 9), and assigned as a unique PHY address.
The PHYAD[2:0] strapping pins are used to assign a unique PHY address between 0 and 7 to each KSZ8051MLL device.
Table 3 shows the MII Management frame format for the KSZ8051MLL.
Preamble
Start of
Frame
Read/Write
Read
32 1’s
01
10
Write
32 1’s
01
01
OP Code
PHY
REG
Address
Address
Bits [4:0]
Bits [4:0]
00AAA
RRRRR
Z0
DDDDDDDD_DDDDDDDD
Z
00AAA
RRRRR
10
DDDDDDDD_DDDDDDDD
Z
Data
TA
Idle
Bits [15:0]
Table 3. MII Management Frame Format – for KSZ8051MLL
Interrupt (INTRP)
INTRP (pin 32) is an optional interrupt signal that is used to inform the external controller that there has been a status
update to the KSZ8051MLL PHY register. Register 1Bh, bits [15:8] are the interrupt control bits to enable and disable the
conditions for asserting the INTRP signal. Register 1Bh, bits [7:0] are the interrupt status bits to indicate which interrupt
conditions have occurred. The interrupt status bits are cleared after reading register 1Bh.
Register 1Fh, bit 9 sets the interrupt level to active high or active low. The default is active low.
The MII management bus option gives the MAC processor complete access to the KSZ8051MLL control and status
registers. Additionally, an interrupt pin eliminates the need for the processor to poll the PHY for status change.
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KSZ8051MLL
HP Auto MDI/MDI-X
HP Auto MDI/MDI-X configuration eliminates the confusion of whether to use a straight cable or a crossover cable
between the KSZ8051MLL and its link partner. This feature allows the KSZ8051MLL to use either type of cable to connect
with a link partner that is in either MDI or MDI-X mode. The auto-sense function detects transmit and receive pairs from
the link partner, and then assigns transmit and receive pairs of the KSZ8051MLL accordingly.
HP Auto MDI/MDI-X is enabled by default. It is disabled by writing a one to register 1Fh, bit 13. MDI and MDI-X mode is
selected by register 1Fh, bit 14 if HP Auto MDI/MDI-X is disabled.
An isolation transformer with symmetrical transmit and receive data paths is recommended to support auto MDI/MDI-X.
Table 4 illustrates how the IEEE 802.3 Standard defines MDI and MDI-X.
MDI
MDI-X
RJ-45 Pin
Signal
RJ-45 Pin
Signal
1
2
TX+
1
RX+
TX-
2
RX-
3
RX+
3
TX+
6
RX-
6
TX-
Table 4. MDI/MDI-X Pin Definition
Straight Cable
A straight cable connects a MDI device to a MDI-X device, or a MDI-X device to a MDI device. Figure 4 depicts a typical
straight cable connection between a NIC card (MDI) and a switch, or hub (MDI-X).
Figure 4. Typical Straight Cable Connection
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KSZ8051MLL
Crossover Cable
A crossover cable connects a MDI device to another MDI device, or a MDI-X device to another MDI-X device. Figure 5
depicts a typical crossover cable connection between two switches or hubs (two MDI-X devices).
Figure 5. Typical Crossover Cable Connection
LinkMD® Cable Diagnostics
The LinkMD® function utilizes time domain reflectometry (TDR) to analyze the cabling plant for common cabling problems,
such as open circuits, short circuits and impedance mismatches.
LinkMD® works by sending a pulse of known amplitude and duration down the MDI or MDI-X pair, and then analyzing the
shape of the reflected signal to determine the type of fault. The time duration for the reflected signal to return provides the
approximate distance to the cabling fault. The LinkMD® function processes this TDR information and presents it as a
numerical value that can be translated to a cable distance.
LinkMD® is initiated by accessing register 1Dh, the LinkMD® Control/Status Register, in conjunction with register 1Fh, the
PHY Control 2 Register. The latter register is used to disable auto MDI/MDI-X and to select either MDI or MDI-X as the
cable differential pair for testing.
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KSZ8051MLL
NAND Tree Support
The KSZ8051MLL provides parametric NAND tree support for fault detection between chip I/Os and board. The NAND
tree is a chain of nested NAND gates in which each KSZ8051MLL digital I/O (NAND tree input) pin is an input to one
NAND gate along the chain. At the end of the chain, the CRS pin provides the output for the nested NAND gates.
The NAND tree test process includes:
•
Enabling NAND tree mode
•
Pulling all NAND tree input pins high
•
Driving low each NAND tree input pin sequentially per the NAND tree pin order
•
Checking the NAND tree output to ensure there is a toggle high-to-low or low-to-high for each NAND tree input
driven low
Table 5 lists the NAND tree pin order.
Pin Name
NAND Tree
Description
18
MDIO
Input
19
MDC
Input
20
RXD3
Input
21
RXD2
Input
22
RXD1
Input
23
RXD0
Input
27
RXDV
Input
28
RXC
Input
29
RXER
Input
32
INTRP
Input
33
TXC
Input
34
TXEN
Input
35
TXD0
Input
36
TXD1
Input
38
TXD2
Input
39
TXD3
Input
42
LED0
Input
43
LED1
Input
40
COL
Input
41
CRS
Output
Pin Number
Table 5. NAND Tree Test Pin Order – for KSZ8051MLL
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KSZ8051MLL
NAND Tree I/O Testing
The following procedure can be used to check for faults on the KSZ8051MLL digital I/O pin connections to the board:
1. Enable NAND tree mode by either hardware pin strapping (NAND_Tree#, pin 32) or software (register 16h, bit 5).
2. Use board logic to drive all KSZ8051MLL NAND tree input pins high.
3. Use board logic to drive each NAND tree input pin, per KSZ8051MLL NAND Tree pin order, as follow:
a. Toggle the first pin (MDIO) from high to low, and verify the CRS pin switch from low to high to indicate
that the first pin is connected properly.
b. Leave the first pin (MDIO) low.
c. Toggle the second pin (MDC) from high to low, and verify the CRS pin switch from high to low to indicate
that the second pin is connected properly.
d. Leave the first pin (MDIO) and the second pin (MDC) low.
e. Toggle the third pin (RXD3) from high to low, and verify the CRS pin switch from low to high to indicate
that the third pin is connected properly.
f. Continue with this sequence until all KSZ8051MLL NAND tree input pins have been toggled (tested).
Each KSZ8051MLL NAND tree input pin must cause the CRS output pin to toggle high-to-low or low-to-high to indicate a
good connection. If the CRS pin fails to toggle when the KSZ8051MLL input pin toggles from high to low, the input pin has
a fault.
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KSZ8051MLL
Power Management
The KSZ8051MLL offers the following power management modes:
Power Saving Mode
Power-Saving Mode is used to reduce the transceiver power consumption when the cable is unplugged. It is enabled by
writing a one to register 1Fh, bit 10, and is in effect when auto-negotiation mode is enabled and cable is disconnected (no
link).
In this mode, the KSZ8051MLL shuts down all transceiver blocks, except for transmitter, energy detect and PLL circuits.
By default, Power-Saving Mode is disabled after power-up.
Energy Detect Power-Down Mode
Energy Detect Power-Down Mode is used to further reduce the transceiver power consumption when the cable is unplugged. It is enabled by writing a zero to register 18h, bit 11, and is in effect when auto-negotiation mode is enabled and
cable is disconnected (no link).
In this mode, the KSZ8051MLL shuts down all transceiver blocks, except for transmitter and energy detect circuits.
Further power consumption is achieved by extending the time interval in between transmissions of link pulses to check for
the presence of a link partner. The periodic transmission of link pulses is needed to ensure two link partners in the same
low power state and with auto MDI/MDI-X disabled can wake up when the cable is connected between them.
By default, Energy Detect Power-Down Mode is disabled after power-up.
Power-Down Mode
Power-Down Mode is used to power down the KSZ8051MLL device when it is not in use after power-up. It is enabled by
writing a one to register 0h, bit 11.
In this mode, the KSZ8051MLL disables all internal functions, except for the MII management interface. The
KSZ8051MLL exits (disables) Power-Down Mode after register 0h, bit 11 is set back to zero.
Slow Oscillator Mode
Slow Oscillator Mode is used to disconnect the input reference crystal/clock on XI (pin 15) and select the on-chip slow
oscillator when the KSZ8051MLL device is not in use after power-up. It is enabled by writing a one to register 11h, bit 5.
Slow Oscillator Mode works in conjunction with Power-Down Mode to put the KSZ8051MLL device in the lowest power
state with all internal functions disabled, except for the MII management interface. To properly exit this mode and return to
normal PHY operation, use the following programming sequence:
1. Disable Slow Oscillator Mode by writing a zero to register 11h, bit 5.
2. Disable Power-Down Mode by writing a zero to register 0h, bit 11.
3. Initiate software reset by writing a one to register 0h, bit 15.
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KSZ8051MLL
Reference Circuit for Power and Ground Connections
The KSZ8051MLL is a single 3.3V supply device with a built-in regulator to supply the 1.2V core. The power and ground
connections are shown in Figure 6 and Table 6 for 3.3V VDDIO.
Figure 6. KSZ8051MLL Power and Ground Connections
Power Pin
Pin Number
VDD_1.2
4
VDDA_3.3
7
VDDIO
25
VDD_1.2
31
Description
Connect with pin 31 by power trace or plane.
Decouple with 2.2uF and 0.1uF capacitors to ground.
Connect to board’s 3.3V supply thru ferrite bead.
Decouple with 22uF and 0.1uF capacitors to ground.
Connect to board’s 3.3V supply for 3.3V VDDIO.
Decouple with 22uF and 0.1uF capacitors to ground.
Connect with pin 4 by power trace or plane.
Decouple with 0.1uF capacitor to ground.
Table 6. KSZ8051MLL Power Pin Description
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Register Map
Register Number (Hex)
Description
0h
Basic Control
1h
Basic Status
2h
PHY Identifier 1
3h
PHY Identifier 2
4h
Auto-Negotiation Advertisement
5h
Auto-Negotiation Link Partner Ability
6h
Auto-Negotiation Expansion
7h
Auto-Negotiation Next Page
8h
Link Partner Next Page Ability
9h – 10h
Reserved
11h
AFE Control 1
12h – 14h
Reserved
15h
RXER Counter
16h
Operation Mode Strap Override
17h
Operation Mode Strap Status
18h
Expanded Control
19h – 1Ah
Reserved
1Bh
Interrupt Control/Status
1Ch
Reserved
1Dh
LinkMD® Control/Status
1Eh
PHY Control 1
1Fh
PHY Control 2
Register Description
Address
Name
(1)
Description
Mode
Default
RW/SC
0
RW
0
Register 0h – Basic Control
1 = Software reset
0.15
Reset
0 = Normal operation
This bit is self-cleared after a ‘1’ is written to it.
0.14
Loop-back
1 = Loop-back mode
0 = Normal operation
1 = 100Mbps
0.13
Speed Select
Set by SPEED strapping pin.
0 = 10Mbps
RW
This bit is ignored if auto-negotiation is enabled
(register 0.12 = 1).
1 = Enable auto-negotiation process
0.12
July 2010
AutoNegotiation
Enable
0 = Disable auto-negotiation process
If enabled, auto-negotiation result overrides
settings in register 0.13 and 0.8.
27
See “Strapping Options” section
for details.
Set by NWAYEN strapping pin.
RW
See “Strapping Options” section
for details.
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KSZ8051MLL
Register Description (Continued)
Address
Name
(1)
Description
Mode
Default
RW
0
Register 0h – Basic Control
1 = Power down mode
0 = Normal operation
0.11
Power Down
0.10
Isolate
0.9
Restart AutoNegotiation
If software reset (register 0.15) is used to exit
Power Down mode (register 0.11 = 1), two
software reset writes (register 0.15 = 1) are
required. First write clears Power Down mode;
second write resets chip and re-latches the pin
strapping pin values.
1 = Electrical isolation of PHY from MII
0 = Normal operation
Set by ISO strapping pin.
RW
See “Strapping Options” section
for details.
RW/SC
0
1 = Restart auto-negotiation process
0 = Normal operation.
This bit is self-cleared after a ‘1’ is written to it.
0.8
Duplex Mode
0.7
Collision Test
0.6:0
Reserved
1 = Full-duplex
RW
0 = Half-duplex
1 = Enable COL test
0 = Disable COL test
Inverse of DUPLEX strapping pin
value.
See “Strapping Options” section
for details.
RW
0
RO
000_0000
RO
0
RO
1
RO
1
RO
1
RO
1
RO
0000
RO
1
RO
0
RO/LH
0
RO
1
Register 1h – Basic Status
1 = T4 capable
1.15
100Base-T4
1.14
100Base-TX
Full Duplex
1 = Capable of 100Mbps full-duplex
1.13
100Base-TX
Half Duplex
1 = Capable of 100Mbps half-duplex
1.12
10Base-T Full
Duplex
1 = Capable of 10Mbps full-duplex
1.11
10Base-T Half
Duplex
1 = Capable of 10Mbps half-duplex
1.10:7
Reserved
1.6
No Preamble
1.5
AutoNegotiation
Complete
1.4
Remote Fault
1.3
AutoNegotiation
Ability
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0 = Not T4 capable
0 = Not capable of 100Mbps full-duplex
0 = Not capable of 100Mbps half-duplex
0 = Not capable of 10Mbps full-duplex
0 = Not capable of 10Mbps half-duplex
1 = Preamble suppression
0 = Normal preamble
1 = Auto-negotiation process completed
0 = Auto-negotiation process not completed
1 = Remote fault
0 = No remote fault
1 = Capable to perform auto-negotiation
0 = Not capable to perform auto-negotiation
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KSZ8051MLL
Register Description (Continued)
Address
Name
1.2
Link Status
1.1
Jabber Detect
1.0
Extended
Capability
(1)
Mode
Default
RO/LL
0
RO/LH
0
1 = Supports extended capabilities registers
RO
1
Assigned to the 3rd through 18th bits of the
Organizationally Unique Identifier (OUI).
Kendin Communication’s OUI is 0010A1 (hex)
RO
0022h
Description
1 = Link is up
0 = Link is down
1 = Jabber detected
0 = Jabber not detected (default is low)
Register 2h – PHY Identifier 1
2.15:0
PHY ID
Number
Register 3h – PHY Identifier 2
3.15:10
PHY ID
Number
Assigned to the 19th through 24th bits of the
Organizationally Unique Identifier (OUI).
Kendin Communication’s OUI is 0010A1 (hex)
RO
0001_01
3.9:4
Model Number
Six bit manufacturer’s model number
RO
01_0101
3.3:0
Revision
Number
Four bit manufacturer’s revision number
RO
Indicates silicon revision
RW
0
RO
0
RW
0
RO
0
RW
00
RO
0
Register 4h – Auto-Negotiation Advertisement
4.15
Next Page
4.14
Reserved
4.13
Remote Fault
4.12
Reserved
1 = Next page capable
0 = No next page capability.
1 = Remote fault supported
0 = No remote fault
[00] = No PAUSE
4.11:10
Pause
[10] = Asymmetric PAUSE
[01] = Symmetric PAUSE
[11] = Asymmetric & Symmetric PAUSE
1 = T4 capable
4.9
100Base-T4
4.8
100Base-TX
Full-Duplex
1 = 100Mbps full-duplex capable
4.7
100Base-TX
Half-Duplex
1 = 100Mbps half-duplex capable
4.6
10Base-T
Full-Duplex
1 = 10Mbps full-duplex capable
4.5
10Base-T
Half-Duplex
1 = 10Mbps half-duplex capable
4.4:0
Selector Field
[00001] = IEEE 802.3
July 2010
0 = No T4 capability
Set by SPEED strapping pin.
0 = No 100Mbps full-duplex capability
RW
See “Strapping Options” section
for details.
Set by SPEED strapping pin.
0 = No 100Mbps half-duplex capability
0 = No 10Mbps full-duplex capability
0 = No 10Mbps half-duplex capability
29
RW
See “Strapping Options” section
for details.
RW
1
RW
1
RW
0_0001
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Register Description (Continued)
Address
Name
(1)
Description
Mode
Default
RO
0
RO
0
RO
0
RO
0
RO
00
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0_0001
RO
0000_0000_000
RO/LH
0
RO
0
RO
1
RO/LH
0
RO
0
Register 5h – Auto-Negotiation Link Partner Ability
5.15
Next Page
5.14
Acknowledge
5.13
Remote Fault
5.12
Reserved
1 = Next page capable
0 = No next page capability
1 = Link code word received from partner
0 = Link code word not yet received
1 = Remote fault detected
0 = No remote fault
[00] = No PAUSE
5.11:10
Pause
[10] = Asymmetric PAUSE
[01] = Symmetric PAUSE
[11] = Asymmetric & Symmetric PAUSE
1 = T4 capable
5.9
100Base-T4
5.8
100Base-TX
Full-Duplex
1 = 100Mbps full-duplex capable
5.7
100Base-TX
Half-Duplex
1 = 100Mbps half-duplex capable
5.6
10Base-T
Full-Duplex
1 = 10Mbps full-duplex capable
5.5
10Base-T
Half-Duplex
1 = 10Mbps half-duplex capable
5.4:0
Selector Field
[00001] = IEEE 802.3
0 = No T4 capability
0 = No 100Mbps full-duplex capability
0 = No 100Mbps half-duplex capability
0 = No 10Mbps full-duplex capability
0 = No 10Mbps half-duplex capability
Register 6h – Auto-Negotiation Expansion
6.15:5
Reserved
6.4
Parallel
Detection Fault
1 = Fault detected by parallel detection
Link Partner
Next Page
Able
1 = Link partner has next page capability
6.3
6.2
Next Page
Able
6.1
Page Received
6.0
Link Partner
AutoNegotiation
Able
July 2010
0 = No fault detected by parallel detection.
0 = Link partner does not have next page
capability
1 = Local device has next page capability
0 = Local device does not have next page
capability
1 = New page received
0 = New page not received yet
1 = Link partner has auto-negotiation capability
0 = Link partner does not have auto-negotiation
capability
30
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Register Description (Continued)
Address
Name
(1)
Description
Mode
Default
RW
0
RO
0
RW
1
RW
0
RO
0
RW
000_0000_0001
RO
0
RO
0
RO
0
RO
0
RO
0
RO
000_0000_0000
RW
0000_0000_00
RW
0
RW
0_0000
RO/SC
0000h
Register 7h – Auto-Negotiation Next Page
7.15
Next Page
7.14
Reserved
7.13
Message Page
7.12
Acknowledge2
7.11
Toggle
1 = Additional next page(s) will follow
0 = Last page
1 = Message page
0 = Unformatted page
1 = Will comply with message
0 = Cannot comply with message
1 = Previous value of the transmitted link code
word equaled logic one
0 = Logic zero
7.10:0
Message Field
11-bit wide field to encode 2048 messages
Register 8h – Link Partner Next Page Ability
8.15
Next Page
8.14
Acknowledge
8.13
Message Page
8.12
Acknowledge2
8.11
Toggle
8.10:0
Message Field
1 = Additional Next Page(s) will follow
0 = Last page
1 = Successful receipt of link word
0 = No successful receipt of link word
1 = Message page
0 = Unformatted page
1 = Able to act on the information
0 = Not able to act on the information
1 = Previous value of transmitted link code
word equal to logic zero
0 = Previous value of transmitted link code
word equal to logic one
Register 11h – AFE Control 1
11.15:6
11.5
Reserved
Slow-Oscillator
Slow Oscillator Mode is used to disconnect the
input reference crystal/clock on the XI pin and
select the on-chip slow oscillator when the
KSZ8051 device is not in use after power-up.
Mode Enable
1 = Enable
0 = Disable
This bit automatically sets software power down
to the analog side when enabled.
11.4:0
Reserved
Register 15h – RXER Counter
15.15:0
July 2010
RXER Counter
Receive error counter for Symbol Error frames
31
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Register Description (Continued)
Address
Name
(1)
Description
Mode
Default
Register 16h – Operation Mode Strap Override
16.15:11
Reserved
RW
0000_0
16.10
Reserved
RO
0
16.9
B-CAST_OFF
override
RW
0
16.8
Reserved
RW
0
16.7
MII B-to-B
override
RW
0
16.6
Reserved
RW
0
16.5
NAND Tree
override
RW
0
16.4:1
Reserved
RW
0000
16.0
MII override
RW
1
1 = Override strap-in for B-CAST_OFF
If bit is ‘1’, PHY Address 0 is non-broadcast.
1 = Override strap-in for MII Back-to-Back
mode (set also bit 0 of this register to 1)
1 = Override strap-in for NAND Tree mode
1 = Override strap-in for MII mode
Register 17h – Operation Mode Strap Status
[000] = Strap to PHY Address 0
[001] = Strap to PHY Address 1
[010] = Strap to PHY Address 2
17.15:13
PHYAD[2:0]
strap-in status
[011] = Strap to PHY Address 3
RO
[100] = Strap to PHY Address 4
[101] = Strap to PHY Address 5
[110] = Strap to PHY Address 6
[111] = Strap to PHY Address 7
17.12:10
Reserved
17.9
B-CAST_OFF
strap-in status
17.8
Reserved
17.7
MII B-to-B
strap-in status
17.6
Reserved
17.5
NAND Tree
strap-in status
17.4:1
Reserved
17.0
MII
strap-in status
July 2010
RO
1 = Strap to B-CAST_OFF
If bit is ‘1’, PHY Address 0 is non-broadcast.
RO
RO
1 = Strap to MII Back-to-Back mode
RO
RO
1 = Strap to NAND Tree mode
RO
RO
1 = Strap to MII mode
RO
32
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Register Description (Continued)
Address
Name
(1)
Description
Mode
Default
RW
0000
RW
1
RW
0
RW
000
RW
0
RW
00_0000
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RO/SC
0
RO/SC
0
Register 18h – Expanded Control
18.15:12
Reserved
18.11
EDPD
Disabled
Energy Detect Power Down mode
1 = Disable
0 = Enable
18.10
100Base-TX
Preamble
Restore
18.9:7
Reserved
18.6
10Base-T
Preamble
Restore
18.5:0
Reserved
1 = Restore received preamble to MII output
(random latency)
0 = Consume 1-byte preamble before sending
frame to MII output for fixed latency
1 = Restore received preamble to MII output
0 = Remove all 7-bytes of preamble before
sending frame (starting with SFD) to MII
output
Register 1Bh – Interrupt Control/Status
1b.15
Jabber
Interrupt
Enable
1 = Enable Jabber Interrupt
1b.14
Receive Error
Interrupt
Enable
1 = Enable Receive Error Interrupt
1b.13
Page Received
Interrupt
Enable
1 = Enable Page Received Interrupt
1b.12
Parallel Detect
Fault Interrupt
Enable
1 = Enable Parallel Detect Fault Interrupt
Link Partner
Acknowledge
Interrupt
Enable
1 = Enable Link Partner Acknowledge Interrupt
1b.11
1b.10
Link Down
Interrupt
Enable
1= Enable Link Down Interrupt
1b.9
Remote Fault
Interrupt
Enable
1 = Enable Remote Fault Interrupt
1b.8
Link Up
Interrupt
Enable
1 = Enable Link Up Interrupt
1b.7
Jabber
Interrupt
1 = Jabber occurred
1b.6
Receive Error
Interrupt
1 = Receive Error occurred
July 2010
0 = Disable Jabber Interrupt
0 = Disable Receive Error Interrupt
0 = Disable Page Received Interrupt
0 = Disable Parallel Detect Fault Interrupt
0 = Disable Link Partner Acknowledge
Interrupt
0 = Disable Link Down Interrupt
0 = Disable Remote Fault Interrupt
0 = Disable Link Up Interrupt
0 = Jabber did not occurred
0 = Receive Error did not occurred
33
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Register Description (Continued)
(1)
Address
Name
Description
1b.5
Page Receive
Interrupt
1 = Page Receive occurred
1b.4
Parallel Detect
Fault Interrupt
1 = Parallel Detect Fault occurred
1b.3
Link Partner
Acknowledge
Interrupt
1 = Link Partner Acknowledge occurred
1b.2
Link Down
Interrupt
1 = Link Down occurred
1b.1
Remote Fault
Interrupt
1 = Remote Fault occurred
1b.0
Link Up
Interrupt
1 = Link Up occurred
0 = Page Receive did not occurred
0 = Parallel Detect Fault did not occurred
0 = Link Partner Acknowledge did not occurred
0 = Link Down did not occurred
0 = Remote Fault did not occurred
0 = Link Up did not occurred
Mode
Default
RO/SC
0
RO/SC
0
RO/SC
0
RO/SC
0
RO/SC
0
RO/SC
0
RW/SC
0
RO
00
RO
0
RW
000
RO
0_0000_0000
RO
0000_00
RO
0
RO
0
Register 1Dh – LinkMD® Control/Status
1d.15
Cable
Diagnostic
Test Enable
1 = Enable cable diagnostic test. After test
has completed, this bit is self-cleared.
0 = Indicates cable diagnostic test (if enabled)
has completed and the status information
is valid for read.
[00] = normal condition
1d.14:13
Cable
Diagnostic
Test Result
[01] = open condition has been detected in
cable
[10] = short condition has been detected in
cable
[11] = cable diagnostic test has failed
1d.12
Short Cable
Indicator
1d.11:9
Reserved
1d.8:0
Cable Fault
Counter
1 = Short cable (<10 meter) has been detected
by LinkMD®.
Distance to fault
Register 1Eh – PHY Control 1
1e.15:10
Reserved
1e.9
Enable Pause
(Flow Control)
1e.8
Link Status
1e.7
Polarity Status
1e.6
Reserved
1e.5
MDI/MDI-X
State
1e.4
July 2010
Energy Detect
1 = Flow control capable
0 = No flow control capability
1 = Link is up
0 = Link is down
1 = Polarity is reversed
RO
0 = Polarity is not reversed
RO
1 = MDI-X
0
RO
0 = MDI
1 = Presence of signal on receive differential
pair
0 = No signal detected on receive differential
pair
34
RO
0
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Register Description (Continued)
Address
Name
1e.3
PHY Isolate
(1)
Description
1 = PHY in isolate mode
0 = PHY in normal operation
Mode
Default
RW
0
RO
000
RW
1
RW
0
RW
0
RW
0
RW
0
RW
0
RW
0
RW
1
RW
00
[000] = still in auto-negotiation
[001] = 10Base-T half-duplex
[010] = 100Base-TX half-duplex
1e.2:0
Operation
Mode
Indication
[011] = reserved
[100] = reserved
[101] = 10Base-T full-duplex
[110] = 100Base-TX full-duplex
[111] = reserved
Register 1Fh – PHY Control 2
1f:15
HP_MDIX
1 = HP Auto MDI/MDI-X mode
0 = Micrel Auto MDI/MDI-X mode
When Auto MDI/MDI-X is disabled,
1 = MDI-X Mode
1f:14
MDI/MDI-X
Select
Transmit on RXP,RXM (pins 10,9) and
Receive on TXP,TXM (pins 12,11)
0 = MDI Mode
Transmit on TXP,TXM (pins 12,11) and
Receive on RXP,RXM (pins 10,9)
1f:13
Pair-Swap
Disable
1f.12
Reserved
1 = Disable auto MDI/MDI-X
0 = Enable auto MDI/MDI-X
1 = Force link pass
0 = Normal link operation
1f.11
Force Link
1f.10
Power Saving
1f.9
Interrupt Level
1f.8
Enable Jabber
1f.7:6
Reserved
July 2010
This bit bypasses the control logic and allow
transmitter to send pattern even if there is no
link.
1 = Enable power saving
0 = Disable power saving
1 = Interrupt pin active high
0 = Interrupt pin active low
1 = Enable jabber counter
0 = Disable jabber counter
35
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Register Description (Continued)
Address
Name
(1)
Description
[00] =
Mode
Default
RW
00
RW
0
RW
0
RW
0
RW
0
LED1 : Speed
LED0 : Link/Activity
1f.5:4
LED mode
[01] =
LED1 : Activity
LED0 : Link
[10], [11] = Reserved
Disable
1 = Disable transmitter
Transmitter
0 = Enable transmitter
1f.2
Remote
Loop-back
1 = Remote (analog) loop back is enable
1f.1
Enable SQE
Test
1 = Enable SQE test
1f.0
Disable Data
Scrambling
1 = Disable scrambler
1f.3
0 = Normal mode
0 = Disable SQE test
0 = Enable scrambler
Note:
1.
RW = Read/Write.
RO = Read only.
SC = Self-cleared.
LH = Latch high.
LL = Latch low.
July 2010
36
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Absolute Maximum Ratings(1)
Operating Ratings(2)
Supply Voltage
(VDD_1.2) .................................................. −0.5V to +1.8V
(VDDIO, VDDA_3.3) ....................................... −0.5V to +4.0V
Input Voltage (all inputs) .............................. −0.5V to +4.0V
Output Voltage (all outputs) ......................... −0.5V to +4.0V
Lead Temperature (soldering, 10sec.)....................... 260°C
Storage Temperature (Ts) ......................... −55°C to +150°C
Supply Voltage
(VDDIO_3.3, VDDA_3.3) .......................... +3.135V to +3.465V
(VDDIO_2.5)........................................ +2.375V to +2.625V
(VDDIO_1.8)........................................ +1.710V to +1.890V
Ambient Temperature
(TA , Commercial)...................................... 0°C to +70°C
(TA , Industrial) ...................................... −40°C to +85°C
Maximum Junction Temperature (TJ max.) ................ 125°C
Thermal Resistance (θJA) .........................................76°C/W
Thermal Resistance (θJC) .........................................15°C/W
Electrical Characteristics(3)
Symbol
Parameter
Condition
Min.
Typ.
Max.
Units
(4)
Supply Current (VDDIO, VDDA_3.3 = 3.3V)
IDD1
10Base-T
Full-duplex traffic @ 100% utilization
39.5
mA
IDD2
100Base-TX
Full-duplex traffic @ 100% utilization
48.9
mA
IDD3
Power Saving Mode
Ethernet cable disconnected (reg. 1F.10 = 1)
30.0
mA
IDD4
Power-Down Mode
Software power down (reg. 0.11 = 1)
2.0
mA
CMOS Level Inputs
VIH
VIL
IIN
Input High Voltage
Input Low Voltage
Input Current
VDDIO = 3.3V
2.0
V
VDDIO = 2.5V
1.8
V
VDDIO = 1.8V
1.3
V
VDDIO = 3.3V
0.8
V
VDDIO = 2.5V
0.7
V
VDDIO = 1.8V
0.5
V
10
µA
VIN = GND ~ VDDIO
-10
CMOS Level Outputs
VOH
VOL
|Ioz|
Output High Voltage
Output Low Voltage
VDDIO = 3.3V
2.4
V
VDDIO = 2.5V
2.0
V
VDDIO = 1.8V
1.5
V
VDDIO = 3.3V
0.4
V
VDDIO = 2.5V
0.4
V
VDDIO = 1.8V
0.3
V
10
µA
Output Tri-State Leakage
LED Outputs
ILED
Output Drive Current
Each LED pin (LED0, LED1)
8
mA
Strapping Pins
pu
pd
July 2010
Internal Pull-Up Resistance
Internal Pull-Down Resistance
VDDIO = 3.3V
29
43
76
KΩ
VDDIO = 2.5V
37
59
102
KΩ
VDDIO = 1.8V
57
100
187
KΩ
VDDIO = 3.3V
27
43
76
KΩ
VDDIO = 2.5V
35
60
110
KΩ
VDDIO = 1.8V
55
100
190
KΩ
37
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Electrical Characteristics(3) (Continued)
Symbol
Parameter
Condition
Min.
Typ.
Max.
Units
1.05
V
2
%
100Base-TX Transmit (measured differentially after 1:1 transformer)
VO
Peak Differential Output Voltage
100Ω termination across differential output
VIMB
Output Voltage Imbalance
100Ω termination across differential output
tr, tf
0.95
Rise/Fall Time
3
5
ns
Rise/Fall Time Imbalance
0
0.5
ns
+ 0.25
ns
5
%
Duty Cycle Distortion
Overshoot
VSET
Reference Voltage of ISET
Output Jitter
V
0.65
Peak-to-peak
0.7
1.4
ns
2.8
V
3.5
ns
10Base-T Transmit (measured differentially after 1:1 transformer)
VP
tr, tf
Peak Differential Output Voltage
100Ω termination across differential output
Jitter Added
Peak-to-peak
Rise/Fall Time
2.2
25
ns
400
mV
10Base-T Receive
VSQ
Squelch Threshold
5MHz square wave
Notes:
1. Exceeding the absolute maximum rating may damage the device. Stresses greater than the absolute maximum rating may cause permanent
damage to the device. Operation of the device at these or any other conditions above those specified in the operating sections of this specification
is not implied. Maximum conditions for extended periods may affect reliability.
2. The device is not guaranteed to function outside its operating rating.
3. TA = 25°C. Specification is for packaged product only.
4. Current consumption is for the single 3.3V supply KSZ8051MLL device only, and includes the transmit driver current and the 1.2V supply voltage
(VDD_1.2) that are supplied by the KSZ8051MLL.
July 2010
38
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Timing Diagrams
MII SQE Timing (10Base-T)
Figure 7. MII SQE Timing (10Base-T)
Timing Parameter
Description
Min.
Typ.
Max.
Unit
tP
TXC period
400
ns
tWL
TXC pulse width low
200
ns
tWH
TXC pulse width high
200
ns
tSQE
COL (SQE) delay after TXEN de-asserted
1.8
us
tSQEP
COL (SQE) pulse duration
1.0
us
Table 7. MII SQE Timing (10Base-T) Parameters
July 2010
39
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
MII Transmit Timing (10Base-T)
Figure 8. MII Transmit Timing (10Base-T)
Timing Parameter
Description
tP
TXC period
Min.
Typ.
400
Max.
Unit
ns
tWL
TXC pulse width low
200
ns
tWH
TXC pulse width high
200
ns
tSU1
TXD[3:0] setup to rising edge of TXC
120
ns
tSU2
TXEN setup to rising edge of TXC
120
ns
tHD1
TXD[3:0] hold from rising edge of TXC
0
ns
tHD2
TXEN hold from rising edge of TXC
0
tCRS1
TXEN high to CRS asserted latency
200
ns
tCRS2
TXEN low to CRS de-asserted latency
550
ns
ns
Table 8. MII Transmit Timing (10Base-T) Parameters
July 2010
40
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
MII Receive Timing (10Base-T)
Figure 9. MII Receive Timing (10Base-T)
Timing Parameter
Description
Min.
Typ.
Max.
Unit
tP
RXC period
400
ns
tWL
RXC pulse width low
200
ns
tWH
RXC pulse width high
200
ns
tOD
(RXDV, RXD[3:0], RXER) output
delay from rising edge of RXC
185
ns
tRLAT
CRS to (RXDV, RXD[3:0]) latency
6.5
us
Table 9. MII Receive Timing (10Base-T) Parameters
July 2010
41
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
MII Transmit Timing (100Base-TX)
Figure 10. MII Transmit Timing (100Base-TX)
Timing Parameter
Description
tP
TXC period
Min.
Typ.
40
ns
tWL
TXC pulse width low
20
ns
20
Max.
Unit
tWH
TXC pulse width high
tSU1
TXD[3:0] setup to rising edge of TXC
10
ns
ns
tSU2
TXEN setup to rising edge of TXC
10
ns
tHD1
TXD[3:0] hold from rising edge of TXC
0
ns
tHD2
TXEN hold from rising edge of TXC
0
tCRS1
TXEN high to CRS asserted latency
35
ns
tCRS2
TXEN low to CRS de-asserted latency
36
ns
ns
Table 10. MII Transmit Timing (100Base-TX) Parameters
July 2010
42
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
MII Receive Timing (100Base-TX)
Figure 11. MII Receive Timing (100Base-TX)
Timing Parameter
Description
Min.
Typ.
Max.
Unit
tP
RXC period
40
ns
tWL
RXC pulse width low
20
ns
tWH
RXC pulse width high
20
ns
tOD
(RXDV, RXD[3:0], RXER) output
delay from rising edge of RXC
23
ns
tRLAT
CRS to (RXDV, RXD[3:0] latency
130
ns
Table 11. MII Receive Timing (100Base-TX) Parameters
July 2010
43
M9999-071210-1.0
Micrel, Inc.
KSZ8051MLL
Auto-Negotiation Timing
Figure 12. Auto-Negotiation Fast Link Pulse (FLP) Timing
Timing Parameter
Description
Min.
Typ.
Max.
8
16
24
Units
tBTB
FLP Burst to FLP Burst
tFLPW
FLP Burst width
ms
tPW
Clock/Data Pulse width
tCTD
Clock Pulse to Data Pulse
55.5
64
69.5
µs
tCTC
Clock Pulse to Clock Pulse
111
128
139
µs
Number of Clock/Data Pulse per
FLP Burst
17
2
ms
100
ns
33
Table 12. Auto-Negotiation Fast Link Pulse (FLP) Timing Parameters
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MDC/MDIO Timing
Figure 13. MDC/MDIO Timing
Timing Parameter
Description
tP
MDC period
tMD1
MDIO (PHY input) setup to rising edge of MDC
10
ns
tMD2
MDIO (PHY input) hold from rising edge of MDC
4
ns
tMD3
Min.
Typ.
400
MDIO (PHY output) delay from rising edge of MDC
* [can vary with MDC clock frequency]
*
Max.
Unit
ns
ns
Table 13. MDC/MDIO Timing Parameters
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Reset Timing
The KSZ8051MLL reset timing requirement is summarized in Figure 14 and Table 14.
Figure 14. Reset Timing
Parameter
Description
tsr
Stable supply voltage (VDDIO, VDDA_3.3) to reset high
Min.
10
Max.
Units
ms
tcs
Configuration setup time
5
ns
tch
Configuration hold time
5
ns
trc
Reset to strap-in pin output
6
ns
Table 14. Reset Timing Parameters
After the de-assertion of reset, it is recommended to wait a minimum of 100µs before starting programming on the MIIM
(MDC/MDIO) Interface.
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Reset Circuit
Figure 15 shows a reset circuit recommended for powering up the KSZ8051MLL if reset is triggered by the power supply.
Figure 15. Recommended Reset Circuit
Figure 16 represents a reset circuit recommended for applications where reset is driven by another device (e.g., CPU or
FPGA). At power-on-reset, R, C and D1 provide the necessary ramp rise time to reset the KSZ8051MLL device. The
RST_OUT_n from CPU/FPGA provides the warm reset after power up.
Figure 16. Recommended Reset Circuit for interfacing with CPU/FPGA Reset Output
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Reference Circuits for LED Strapping Pins
The pull-up, float and pull-down reference circuits for the LED1/SPEED and LED0/NWAYEN strapping pins are shown in
Figure 17.
Figure 17. Reference Circuits for LED Strapping Pins
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Magnetics Specification
A 1:1 isolation transformer is required at the line interface. An isolation transformer with integrated common-mode chokes
is recommended for exceeding FCC requirements.
Table 15 and Table 16 list recommended magnetic characteristics and qualified magnetics for the KSZ8051MLL.
Parameter
Value
Turns ratio
1 CT : 1 CT
Test Condition
Open-circuit inductance (min.)
350μH
100mV, 100kHz, 8mA
Insertion loss (max.)
-1.0dB
100kHz – 100MHz
HIPOT (min.)
1500Vrms
Table 15. Magnetics Selection Criteria
Magnetic Manufacturer
Part Number
Auto MDI-X
Number of Port
Bel Fuse
S558-5999-U7
Yes
1
Bel Fuse (Mag Jack)
SI-46001-F
Yes
1
Bel Fuse (Mag Jack)
SI-50170-F
Yes
1
Delta
LF8505
Yes
1
LANKom
LF-H41S-1
Yes
1
Pulse
H1102
Yes
1
Pulse (low cost)
H1260
Yes
1
Transpower
HB726
Yes
1
TDK (Mag Jack)
TLA-6T718A
Yes
1
Table 16. Qualified Single Port 10/100 Magnetics
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Reference Clock – Connection and Selection
A crystal or external clock source, such as an oscillator, is used to provide the reference clock for the KSZ8051MLL. For
the KSZ8051MLL in all operating modes, the reference clock is 25MHz. The reference clock connections to XI (Pin 15)
and XO (Pin 14), and the reference clock selection criteria are provided in Figure 18 and Table 17.
Figure 18. 25MHz Crystal / Oscillator Reference Clock Connection
Characteristics
Value
Units
Frequency
25
MHz
Frequency tolerance (max)
±50
ppm
Table 17. 25MHz Crystal / Reference Clock Selection Criteria
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Package Information
48-Pin (7mm x 7mm) LQFP
Note:
ALL DIMENSIONS ARE IN MILLIMETERS.
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http://www.micrel.com
The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its
use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product
can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical
implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user.
A Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to
fully indemnify Micrel for any damages resulting from such use or sale.
© 2010 Micrel, Incorporated.
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