MICREL KS8001LI

KS8001
1.8V, 3.3V 10/100BASETX/FX
Physical Layer Transceiver
DATASHEET V 1.01
General Description
Features
The KS8001 is a 10BASE-T/100BASE-TX/FX Physical
Layer Transceiver, operating the core at 1.8 volts to meet
low voltage and low power requirements. The solution
provides MII/RMII/SMII interfaces to transmit and receive
data.
A unique mixed-signal design extends signaling
distance while reducing power consumption.
•
•
•
HP Auto MDI/MDI-X provides the most robust solution for
eliminating the need to differentiate between crossover and
straight-through cables.
Featuring LinkMD cable diagnostics, which allows
detection of common cabling plant problems such as open
and short circuits, the KS8001 represents a new level of
features and performance and is an ideal choice of
physical layer transceiver for 100BASE-TX/10BASET/100BASE-FX applications.
•
•
•
•
•
•
•
Single chip 100BASE-TX/100BASE-FX/10BASE-T
physical layer solution
1.8V CMOS design, power consumption 250 mW
Robust (130m+) operation over standard cables
Supports Media Independent Interface (MII), Reduced
MII (RMII), and Serial MII (SMII)
LinkMD feature to determine cable length and
diagnose faulty cables up 200 m with +/- 2 m accuracy
Supports HP MDI/MDI-X auto crossover
Supports power down mode and power saving mode
MDC/MDIO to 12.5 MHz for rapid configuration
Fully compliant to IEEE 802.3u standard
Supports auto-negotiation and manual selection for
10/100Mbps speed and full / half-duplex mode
Functional Diagram
TX+
TX-
TRANSMITTER
10/100
PULSE
SHAPER
NRZ/NRZI
MLT3 ENCODER
4B/5B ENCODER
SCRAMBLER
PARALLEL/SERIAL
PARALLEL/SERIAL
MANCHESTER ENCODER
ADAPTIVE EQ
BASELINE WANDER
CORRECTION
MLT3 DECODER
NRZI/NRZ
RX+
RX-
CLOCK
RECOVERY
4B/5B DECODER
DESCRAMBLER
SERIAL/PARALLEL
MII/RMII/SMII
REGISTERS
AND
CONTROLLER
INTERFACE
AUTO
NEGOTIATION
10BASE-T
RECEIVER
MANCHESTER DECODER
SERIAL/PARALLEL
POWER DOWN/
POWER SAVING
XI
XO
LINK
LED
DRIVER
PLL
TXD3
TXD2
TXD1
TXD0
TXER
TXC
TXEN
CRS
COL
MDIO
MDC
RXD3
RXD2
RXD1
RXD0
RXER
RXDV
RXC
PWRDWN
COL
FDX
SPD
Micrel, Inc. • 1849 Fortune Drive • San Jose, CA 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 944-0970 • http://www.micrel.com
May 2005
KS8001
MICREL CONFIDENTIAL. DO NOT DISTRIBUTE.
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Features (continued)
Ordering Information
•
Part
Number
KS8001L
KSZ8001L
KS8001LI
KS8001S
KSZ8001S
•
•
•
•
•
Configurable through MII serial management ports or via
external control pins
Programmable LED outputs for link, activity, full/half
duplex, collision and speed
On-chip built-in analog front end filtering for both
100BASE-TX and 10BASE-T
Supports back to back, FX to TX for media converter
applications
Single 3.3V power supply with built-in 1.8V regulator (‘L’
parts)
48 Pin LQFP, 48 Pin SSOP, 48 Pin QFN (targeted)
Temp.
Range
0o–70o C
0o–70o C
- 40o–85o C
0o–70o C
0o–70o C
Package
48-LQFP
48-LQFP
48-LQFP
48-SSOP
48-SSOP
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2
Lead
Finish
Standard
Lead-free
Standard
Standard
Lead-free
KS8001
KS8001
Micrel
Revision History
Revision
Date
PRELIMINARY
25 Mar 2004
0.8
9 Aug 2004
•
•
•
Updated pin 38 (VDDRCV) definition to 3.3V
Corrected pin configuration diagrams to reflect NC on pins 42 and 43
Updated crystal tolerance to +/- 50 ppm
0.81
17 Sep 2004
•
Updated series resistance for crystal specification to 40 Ω
0.82
25 Jan 2005
•
•
•
•
•
LinkMD distance coefficient changed to 0.39
Interrupt register status bits set to RO/SC
Recommended reset circuit added
RMII timing added
Added lead-free part numbers
•
•
•
Changed REXT value to 6.65 KΩ
Removed preliminary status
Added KS8001S to ordering information
1.00
31 Mar 2005
1.01
16 May 2005
Summary of Changes
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Table of Contents
Pin Description .................................................................................................................................................................................... 6
Strapping Options ............................................................................................................................................................................. 10
Pin Configuration .............................................................................................................................................................................. 11
Functional Description...................................................................................................................................................................... 12
100BASE-TX Transmit .................................................................................................................................................................... 12
100BASE-TX Receive ..................................................................................................................................................................... 12
PLL Clock Synthesizer .................................................................................................................................................................... 12
Scrambler/De-scrambler (100BASE-TX only).................................................................................................................................. 12
10BASE-T Transmit......................................................................................................................................................................... 12
10BASE-T Receive.......................................................................................................................................................................... 12
SQE and Jabber Function (10BASE-T only) ................................................................................................................................... 13
Auto-Negotiation.............................................................................................................................................................................. 13
MII Management Interface................................................................................................................................................................. 13
MII Data Interface ............................................................................................................................................................................ 13
RMII (Reduced MII) Data Interface.................................................................................................................................................... 14
RMII Signal Definition ...................................................................................................................................................................... 14
Reference Clock (REF_CLK)........................................................................................................................................................... 15
Carrier Sense/Receive Data Valid (CRS_DV) ................................................................................................................................. 15
Receive Data [1:0] (RXD[1:0]) ......................................................................................................................................................... 15
Transmit Enable (TX_EN) ............................................................................................................................................................... 15
Transmit Data [1:0] (TXD[1:0])......................................................................................................................................................... 15
Collision Detection........................................................................................................................................................................... 15
RX_ER ............................................................................................................................................................................................ 15
RMII AC Characteristics .................................................................................................................................................................. 16
RMII Transmit Timing ...................................................................................................................................................................... 16
RMII Receive Timing ....................................................................................................................................................................... 16
SMII Signal Definition........................................................................................................................................................................ 17
SMII Signals .................................................................................................................................................................................... 17
Receive Path ................................................................................................................................................................................... 17
Receive Sequence Diagram ............................................................................................................................................................ 17
Transmit Path .................................................................................................................................................................................. 18
Transmit Sequence Diagram ........................................................................................................................................................... 18
Collision Detection........................................................................................................................................................................... 19
DC Specification .............................................................................................................................................................................. 19
Timing Specification ........................................................................................................................................................................ 20
HP Auto Crossover (Auto MDI/MDI-X) ............................................................................................................................................. 21
Auto MDI/MDI-X Cross-Over Transformer Connection.................................................................................................................... 22
Power Management........................................................................................................................................................................... 22
100BT FX Mode.................................................................................................................................................................................. 22
Media converter operation................................................................................................................................................................ 22
LinkMD Cable Diagnostics................................................................................................................................................................ 23
Reference Clock Connection Options ............................................................................................................................................. 24
Register Map ...................................................................................................................................................................................... 25
Register 0h – Basic Control ............................................................................................................................................................. 25
Register 1h – Basic Status .............................................................................................................................................................. 26
Register 2h – PHY Identifier 1 ......................................................................................................................................................... 26
Register 3h – PHY Identifier 2 ......................................................................................................................................................... 26
Register 4h – Auto-Negotiation Advertisement................................................................................................................................ 26
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Register 5h – Auto-Negotiation Link Partner Ability......................................................................................................................... 27
Register 6h – Auto-Negotiation Expansion ...................................................................................................................................... 27
Register 7h – Auto-Negotiation Next Page ...................................................................................................................................... 28
Register 8h – Link Partner Next Page Ability................................................................................................................................... 28
Register 15h – RXER Counter......................................................................................................................................................... 28
Register 1bh – Interrupt Control/Status Register ............................................................................................................................. 29
Register 1dh – LinkMD Control/Status Register .............................................................................................................................. 29
Register 1eh – PHY Control ............................................................................................................................................................ 30
Register 1fh – 100BASE-TX PHY Controller ................................................................................................................................... 30
Absolute Maximum Rating (Note 1) ...................................................................................................................................................... 32
Operating Range (Note 2) ...................................................................................................................................................................... 32
Package Thermal Resistance (θJA)(Note 3) .......................................................................................................................................... 33
Electrical Characteristics (Note4) ........................................................................................................................................................ 33
Timing Diagrams ............................................................................................................................................................................... 35
Reset Timing Diagram....................................................................................................................................................................... 40
Reset Timing Parameters ................................................................................................................................................................ 40
Reset Circuit Diagram ....................................................................................................................................................................... 40
Reference Circuit for Strapping Option Configuration................................................................................................................... 42
Selection of Isolation Transformers ................................................................................................................................................ 43
Selection of Reference Crystal......................................................................................................................................................... 43
Package Information ......................................................................................................................................................................... 44
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Pin Description
Pin Number
1
Pin Name
MDIO
Type
I/O
2
MDC
I
3
RXD3/
PHYAD1
Ipd/O
4
RXD2/
PHYAD2
Ipd/O
5
RXD1/
RXD[1]/
PHYAD3
Ipd/O
6
RXD0/
RXD[0]/
RX
PHYAD4
Ipd/O
7
8
9
VDDIO
GND
RXDV/
CRSDV/
Pwr
Gnd
Ipd/O
PCS_LPBK
10
RXC/
Ipd/O
SMII_SELECT
11
RXER/
RX_ER/
ISO
Ipd/O
12
13
14
15
GND
VDDC
TXER
TXC/
REFCLK/
CLOCK
Gnd
Pwr
Ipd
I/O
16
17
TXEN
TXD0/
TXD[0]/
TX
Ipd
Ipd
(Note 1)
Pin Function
Management Interface (MII) Data I/O
This pin requires an external 10K pull-up resistor.
Management Interface (MII) Clock Input
This pin is synchronous to the MDIO data interface
MII Mode: Receive Data Output[3]2 /
Configuration Mode: The pull-up/pull-down value is latched as PHYADDR[1]
during reset. See “Strapping Options” section for details.
2
MII Mode: MII Receive Data Output[2] /
Configuration Mode: The pull-up/pull-down value is latched as PHYADDR[2]
during reset. See “Strapping Options” section for details.
MII Mode: Receive Data Output[1]2 /
RMII Mode: Receive Data Output[1]3 /
Configuration Mode: The pull-up/pull-down value is latched as PHYADDR[3]
during reset. See “Strapping Options” section for details.
MII Mode: Receive Data Output[0]2 /
RMII Mode: Receive Data Output[0]3 /
SMII Mode: Receive Data and Control4 /
Configuration Mode: The pull-up/pull-down value is latched as PHYADDR[4]
during reset. See “Strapping Options” section for details.
Digital IO 2.5 /3.3V tolerance power supply.
Ground
MII Mode: Receive Data Valid Output /
RMII Mode: Carrier Sense/Receive Data Valid /
Configuration Mode: The pull-up/pull-down value is latched as pcs_lpbk
during reset. See “Strapping Options” section for details.
MII Receive Clock Output
Operating at:
25 MHz = 100 Mbps
2.5 MHz = 10 Mbps
Configuration Mode: The pull-up/pull-down value is latched as SMII during
reset. See “Strapping Options” section for details.
MII Mode: Receive Error Output /
RMII Mode: Receive Error /
Configuration Mode: The pull-up/pull-down value is latched as ISOLATE
during reset. See “Strapping Options” section for details.
Ground
Digital core 1.8 V only power supply
MII Transmit Error Input
MII Mode: MII Transmit Clock Output /
RMII Mode: 50 MHz Reference Clock Input /
SMII Mode: 125 MHz Synchronization Clock Input
MII Transmit Enable Input
MII Mode: Transmit Data Input[0] /
RMII Mode: Transmit Data Input[0] /
SMII Mode: Transmit Data and Control
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KS8001
Pin Number
18
19
20
21
Micrel
Pin Name
TXD1/
TXD[1]/
SYNC
TXD2
TXD3
COL /
Type (Note 1)
Ipd
Ipd
Ipd
Ipd/O
RMII_SELECT
22
CRS/
RMII_BTB
Ipd/O
23
24
25
GND
VDDIO
INT#/
PHYAD0
Gnd
Pwr
Ipu/O
26
LED0/
TEST
Ipu/O
Pin Function
MII Mode: Transmit Data Input[1] /
RMII Mode: Transmit Data Input[1] /
SMII Mode: SYNC
MII Transmit Data Input[2]
MII Transmit Data Input[3]
MII Collision Detect Output
Configuration Mode: The pull-up/pull-down value is latched as RMII select
during reset. See “Strapping Options” section for details.
MII Carrier Sense Output
Configuration Mode: The pull-up/pull-down value is latched as RMII Loopback during reset when RMII mode is selected. See “Strapping Options
section” for details.
Ground
Digital IO 2.5 / 3.3V tolerance power supply
Management Interface (MII) Interrupt Out.
Configuration Mode: Latched as PHYAD[0] during power up / reset. See
“Strapping Options” section for details.
Programmable LED Output 0
Configuration Mode: The external pull down enable test mode and only used
for tfactory test. Active Low. The LED0 pin is also programmable via register
1eh.
LED mode = 00
Link/Act
Pin State
LED Definition
No Link
H
Off
Link
L
On
Activity
-
Toggle
Link
Pin State
LED Definition
No Link
H
Off
Link
L
On
10Mbps Link
Pin State
LED Definition
No Link
H
Off
LED mode = 01
LED mode = 10
27
LED1 /
SPD100/
noFEF
Ipu/O
Link
L
On
Programmable LED Output 1
Configuration Mode: Latched as SPEED (Register 0, bit 13) during power up
/ reset. See “Strapping Options” Section for details. Active Low. The LED1
pin is also programmable via register 1eh.
LED mode = 00
Speed
Pin State
LED Definition
10BT
H
Off
100BT
L
On
Speed
Pin State
LED Definition
10BT
H
Off
100BT
L
On
LED mode = 01
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KS8001
KS8001
Pin Number
28
Micrel
Pin Name
LED2/
DUPLEX
Type (Note 1)
Ipu/O
Pin Function
LED mode = 10
100Mbps Link
Pin State
LED Definition
No Link
H
Off
Link
L
On
Programmable LED Output 2
Configuration Mode: Latched as DUPLEX (register 0h, bit 8) during power up
/ reset. See “Strapping Options” Section for details. Active Low. The LED2
pin is also programmable via register 1eh.
LED mode = 00
Duplex
Pin State
LED Definition
Half
H
Off
Full
L
On
Full Duplex/Col
Pin State
LED Definition
Half
H
Off
Full
L
On
Collision
-
Toggle
Duplex
Pin State
LED Definition
Half
H
Off
LED mode = 01
LED mode = 10
29
LED3/
NWAYEN
Ipu/O
Full
L
On
Programmable LED Output 3
Configuration Mode: Latched as ANEG_EN (register 0h, bit 12) during power
up / reset. See “Strapping Options” Section for details. Active Low. The
LED3 pin is also programmable via register 1eh.
LED mode = 00
Collision
Pin State
LED Definition
No Collision
H
Off
Collision
L
On
Activity
Pin State
LED Definition
Activity
-
Toggle
Pin State
LED Definition
LED mode = 01
LED mode = 10
Activity
30
PD#
Ipu
31
32
VDDRX
RX-
Pwr
I
33
RX+
I
34
FXSD/
FXEN
Ipd/O
35
GND
Gnd
Activity
Toggle
Power Down.
1=Normal operation, 0=Power down, Active low
Analog 1.8 V power supply
Receive Input
Differential receive input pins for FX, 100BASE-TX or 10BASE-T
Receive Input
Differential receive input pin for FX, 100BASE-TX or 10BASE-T
Fiber Mode Enable / Signal Detect in Fiber Mode
If FXEN=0, FX mode is disable. The default is “0”.
See “100BT FX Mode” section for more details.
Ground
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Pin Number
36
37
38
Pin Name
GND
REXT
VDDRCV
Type (Note 1)
Gnd
I
Pwr
39
GND
Gnd
40
TX-
O
41
TX+
O
42
43
44
45
NC
NC
GND
XO
Gnd
O
46
XI
I
47
48
VDDPLL
RST#
Pwr
Ipu
Note 1:
Pwr = power supply;
Gnd = ground;
I = input;
O = output;
I/O = bi-directional
Ipu = input w/ internal pull up;
Ipd = input w/ internal pull down;
Note 2:
Pin Function
Ground
External resistor (6.65K Ω) connects to REXT and GNDRX
Analog 3.3 V power supply (See “Circuit design ref for power supply”
section for details)
Ground
Transmit Outputs
Differential transmit output for 100BASE-TX/FX or 10BASE-T
Transmit Outputs
Differential transmit output for FX, 100BASE-TX/FX or 10BASE-T
No Connect
No Connect
Ground
XTAL feedback
Used with XI for Xtal application.
Crystal Oscillator Input
Input for a crystal or an external 25 MHz clock
Analog PLL 1.8 V power supply
Chip Reset
Active low, minimum of 50 us pulse is required
Ipu/O = input w/ internal pull up during
reset, output pin otherwise;
Ipd/O = input w/ internal pull down during
reset, output pin otherwise;
PD = strap pull down;
PU = strap pull up;
MII Rx Mode: The RXD[3..0] bits are synchronous with RXCLK. When RXDV is asserted, RXD [3..0]
presents valid data to MAC through the MII. RXD [3..0] is invalid when RXDV is de-asserted.
Note 3:
RMII Rx Mode: The RXD[1..0] bits are synchronous with REF_CLK. For each clock period in which
CRS_DV is asserted, two bits of recovered data are sent from the PHY.
Note 4:
SMII Rx Mode: Receive data and control information are sent in 10 bit segments. In 100MBit mode, each
segment represents a new byte of data. In 10MBit mode, each segment is repeated ten times; therefore,
every ten segments represents a new byte of data. The MAC can sample any one of every 10 segments in
10MBit mode.
Note 5:
MII Tx Mode: The TXD[3..0] bits are synchronous with TXCLK. When TXEN is asserted, TXD [3..0]
presents valid data from the MAC through the MII. TXD [3..0] has no effect when TXEN is de-asserted.
Note 6:
RMII Tx Mode: The TXD[1..0] bits are synchronous with REF_CLK. For each clock period in which TX_EN
is asserted, two bits of recovered data are recovered by the PHY.
Note 7:
SMII Tx Mode: Transmit data and control information are received in 10 bit segments. In 100MBit mode,
each segment represents a new byte of data. In 10MBit mode, each segment is repeated ten times;
therefore, every ten segments represents a new byte of data. The PHY can sample any one of every 10
segments in 10MBit mode.
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Strapping Options
Pin Number
6,5,
4,3
Pin Name
PHYAD[4:1] /
RXD[0:3]
Type (Note 2)
Ipd/O
25
PHYAD0/
INT#
Ipu/O
9
PCS_LPBK/
RXDV
Ipd/O
10
SMII_SELECT
/ RXC
Description
PHY Address latched at power-up / reset. The default PHY
address is 00001.
Enables PCS_LPBK mode at power-up / reset.
PD (default) = Disable, PU = Enable
Ipd/O
Enables SMII mode at power-up / reset.
PD (default) = Disable, PU = Enable
11
ISO / RXER
Ipd/O
Enables ISOLATE mode at power-up /reset.
PD (default) = Disable, PU = Enable
21
Ipd/O
Enables RMII mode at power-up / reset.
RMII_SELECT
/ COL
PD (default) = Disable, PU = Enable
22
Ipd/O
Enable RMII_BTB mode at power-up / reset.
RMII_BTB/
CRS
PD (default) = Disable, PU = Enable
Ipu/O
Latched into Register 0h bit 13 during power-up / reset.
27
SPD100 /
PD = 10Mb/s, PU (default) = 100Mb/s.
No FEF /
LED1
If SPD100 is asserted during power-up / reset, this pin also
latched as the Speed Support in register 4h. (If FXEN is
pulled up, the latched value 0 means no Far _End _Fault.)
28
Ipu/O
Latched into Register 0h bit 8 during power-up / reset.
DUPLEX/
LED2
PD = Half Duplex, PU (default) = Full duplex.
If Duplex is pulled up during reset, this pin also latched as the
Duplex support in register 4h.
29
Ipu/O
Nway (auto-=Negotiation) Enable
NWAYEN/
LED3
Latched into Register 0h bit 12 during power-up / reset. PD =
Disable Auto-Negotiation, PU (default) = Enable AutoNegotiation
30
PD#
Ipu
Power Down Enable
PU (default) = Normal operation, PD = Power down mode
Note: Strap-in is latched during power up or reset. In some systems, the MAC RXD pins may drive high at all times causing the
PHY strap-in to be latched high during power up or system reset. In this case, it is recommended to use a strong pull down to GND
via 1kohm resistor on RXDV, RXC, and RXER pins. Otherwise, the PHY may stay in Isolate or loop back modes.
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KS8001
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GND
13
VDDC
14
TXER
15
TXC/REF_CLK
16
TXEN
17
18
REXT
37
GND
36
GND
35
FXSD/FXEN
34
RX+
33
TXD0
RX-
32
TXD1
VDDRX
31
19
TXD2
PD#
30
20
TXD3
LED3/NWAYEN
29
21
COL/RMII
LED2/DUPLEX
28
22
CRS/RMII_BTB
LED1/SPD100
27
23
GND
LED0/TEST
26
24
VDDIO
INT#/PHYAD0
25
RXD1/PHYAD3
6
RXD0/PHYAD4
7
VDDIO
8
GND
REXT 37
TX- 40
GND 39
NC 42
TX+ 41
NC 43
VDDRCV 38
RXD2/PHYAD2
5
RX+ 33
RX- 32
KS8001L
VDDRX 31
PD# 30
LED3/NWAYEN 29
9
RXDV/PCS_LPBK
LED2/DUPLEX 28
10
RXC
LED1/SPD100 27
11
RXER/ISO
12
GND
LED0/TEST 26
VDDIO
12
4
GND
38
24
39
VDDRCV
KS8001S
23
GND
RXER/ISO
GND 35
FXSD/FXEN 34
CRS/RMII_BTB
RXC
11
RXD3/PHYAD1
COL/RMII
10
3
22
40
GND 36
21
41
TX-
Top View
LQFP 48
TXD3
TX+
RXDV/PCS_LPBK
MDC
20
GND
9
MDIO
2
TXD2
8
1
19
42
GND 44
NC
TXD1
VDDIO
TXD0
43
7
18
NC
17
RXD0/PHYAD4
XI 46
44
6
XO 45
GND
TXEN
RXD1/PHYAD3
TXC/REF_CLK
45
5
16
XO
15
RXD2/PHYAD2
RST# 48
46
4
TXER
47
RXD3/PHYAD1
3
VDDC
48
XI
MDC
14
RST#
MDIO
2
13
Top View
SSOP 48
VDDPLL
1
VDDPLL 47
Pin Configuration
INT#/PHYAD0 25
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Functional Description
100BASE-TX Transmit
The 100BASE-TX transmit function performs parallel-to-serial conversion, NRZ to NRZI conversion, MLT-3 encoding and
transmission. The circuitry starts with a parallel-to-serial conversion, which converts the 25 MHz, 4-bit nibbles into a 125 MHz serial
bit stream. The incoming data is clocked in at the positive edge of the TXC signal. 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 1% 6.65 KΩ resistor for
the 1:1 transformer ratio. It has typical rise/fall times of 4 ns and complies with the ANSI TP-PMD standard regarding amplitude
balance, overshoot and timing jitter. The wave-shaped 10BASE-T output driver is also incorporated into the 100BASE-TX driver.
100BASE-TX Receive
The 100BASE-TX receive function performs adaptive equalization, DC restoration, MLT-3 to NRZI conversion, data and clock
recovery, NRZI to NRZ conversion, 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 are a
function of the length of the cable, the equalizer has to adjust its characteristic to optimize performance. In this design, the variable
equalizer will make an initial estimation based upon comparisons of incoming signal strength against some known cable
characteristics, then tunes itself for optimization. This is an ongoing process and can self adjust against environmental changes
such as temperature variations.
The equalized signal then goes through a DC restoration and data conversion block. The DC restoration circuit is used to
compensate for the effects of base line 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 125 MHz clock from the edges of the NRZI signal. This recovered clock is then used to
convert the NRZI signal into the NRZ format. Finally, the NRZ serial data is converted to 4-bit parallel 4B nibbles. A synchronized
25 MHz RXC is generated so that the 4B nibbles is clocked out at the negative edge of RCK25 and is valid for the receiver at the
positive edge. When no valid data is present, the clock recovery circuit is locked to the 25 MΗz reference clock and both TXC and
RXC clocks continue to run.
PLL Clock Synthesizer
The KS8001 generates 125 MΗz, 25 MΗz and 20 MΗz clocks for system timing. An internal crystal oscillator circuit provides the
reference clock for the synthesizer.
Scrambler/De-scrambler (100BASE-TX only)
The purpose of the scrambler is to spread the power spectrum of the signal in order to reduce EMI and baseline wander.
10BASE-T Transmit
When TXEN (transmit enable) goes high, data encoding and transmission will begin. The KS8001 will continue to encode and
transmit data as long as TXEN remains high. The data transmission will end when TXEN goes low. The last transition occurs at the
boundary of the bit cell if the last bit is zero, or at the center of the bit cell if the last bit is one. The output driver is incorporated into
the 100BASE- driver to allow transmission with the same magnetics. They are internally wave-shaped and pre-emphasized into
outputs with a typical 2.5 V amplitude. The harmonic contents are at least 27 dB below the fundamental 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 300 mV or with short pulse widths in order to prevent noises at the RX+ or RX- input from
falsely trigger the decoder. When the input exceeds the squelch limit, the PLL locks onto the incoming signal and the KS8001
decodes a data frame. This activates the carrier sense (CRS) ad RXDV signals and makes the receive data (RXD) available. The
receive clock is maintained active during idle periods in between data reception.
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KS8001
KS8001
Micrel
SQE and Jabber Function (10BASE-T only)
In 10BASE-T operation, a short pulse will be put out on the COL pin after each packet is transmitted. This is required as a test of the
10BASE-T transmit/receive path and is called SQE test. The 10BASE-T transmitter will be disabled and COL will go high if TXEN is
High for more than 20 ms (Jabbering). If TXEN then goes low for more than 250 ms, the 10BASE-T transmitter will be re-enabled
and COL will go Low.
Auto-Negotiation
The KS8001 performs auto-negotiation by hardware strapping option (pin 29) or software (Register 0.12). It will automatically
choose its mode of operation by advertising its abilities and comparing them with those received from its link partner whenever autonegotiation is enabled. It can also be configured to advertise 100BASE-TX or 10BASE-T in either full- or half-duplex mode. Autonegotiation is disabled in FX mode.
During auto-negotiation, the contents of Register 4, coded in Fast Link Pulse (FLP), will be sent to its link partner under the
conditions of power-on, link-loss or re-start. At the same time, the KS8001 will monitor incoming data to determine its mode of
operation. Parallel detection circuit will be enabled as soon as either 10BASE-T NLP (Normal Link Pulse) or 100BASE-TX idle is
detected. The operation mode is configured based on the following 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
When the KS8001 receives a burst of FLP from its link partner with 3 identical link code words (ignoring acknowledge bit), it will store
these code words in Register 5 and wait for the next 3 identical code words. Once the KS8001 detects the second code words, it
then configures itself according to the above-mentioned priority. In addition, the KS8001 also checks for 100BASE-TX idle or
10BASE-T NLP symbols. If either is detected, the KS8001 automatically configures to match the detected operating speed.
MII Management Interface
The KS8001 supports the IEEE 802.3 MII Management Interface, also known as the Management Data Input / Output (MDIO)
Interface. This interface allows upper-layer devices to monitor and control the state of the KS8001. The MDIO interface consists of
the following:
•
•
•
A physical connection including a data line (MDIO), a clock line (MDC) and an optional interrupt line (INTRPT)
A specific protocol that runs across the above-mentioned physical connection and it also allows one controller to
communicate with multiple KS8001 devices. Each KS8001 is assigned an MII address between 0 and 31 by the PHYAD
inputs.
An internal addressable set of fourteen 16-bit MDIO registers. Register [0:6] are required and their functions are specified
by the IEEE 802.3 specifications. Additional registers are provided for expanded functionality.
The INTPRT pin functions as a management data interrupt in the MII. An active Low or High in this pin indicates a status change on
the KS8001 based upon 1fh.9 level control. Register bits at 1bh[15:8] are the interrupt enable bits. Register bits at 1bh[7:0] are the
interrupt condition bits. This interrupt is cleared by reading Register 1bh.
MII Data Interface
The data interface consists of separate channels for transmitting data from a 10/100 802.3 compliant Media Access Controller (MAC)
to the KS8001, and for receiving data from the line. Normal data transmission is implemented in 4B Nibble Mode (4-bit wide
nibbles).
Transmit Clock (TXC): The transmit clock is normally generated by the KS8001 from an external 25MHz reference source at the
X1 input. The transmit data and control signals must always be synchronized to the TXC by the MAC. The KS8001 normally
samples these signals on the rising edge of the TXC.
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KS8001
KS8001
Micrel
Receive Clock (RXC): For 100BASE-TX links, the receive clock is continuously recovered from the line. If the link goes down, and
auto-negotiation is disabled, the receive clock then operates off the master input clock (X1 or TXC). For 10BASE-T links, the receive
clock is recovered from the line while carrier is active, and operates from the master input clock when the line is idle. The KS8001
synchronizes the receive data and control signals on the falling edge of RXC in order to stabilize the signals at the rising edge of the
clock with 10ns setup and hold times.
Transmit Enable: The MAC must assert TXEN at the same time as the first nibble of the preamble, and de-assert TXEN after the
last bit of the packet.
Receive Data Valid: The KS8001 asserts RXDV when it receives a valid packet. Line operating speed and MII mode will determine
timing changes in the following way:
•
•
For 100BASE-TX link with the MII in 4B mode, RXDV is asserted from the first nibble of the preamble to the last nibble of
the data packet.
For 10BASE-T links, the entire preamble is truncated. RXDV is asserted with the first nibble of the SFD “ 5D” and remains
asserted until the end of the packet.
Error Signals: Whenever the KS8001 receives an error symbol from the network, it asserts RXER and drives “1110” (4B) on the
RXD pins. When the MAC asserts TXER, the KS8001 will drive “H” symbols (a Transmit Error define in the IEEE 802.3 4B/5B code
group) out on the line to force signaling errors.
Carrier Sense (CRS): For 100TX links, a start-of-stream delimiter, or /J/K symbol pair causes assertion of Carrier Sense (CRS).
An end-of-stream delimiter,or /T/R symbol pair causes de-assertion of CRS. The PMA layer will also de-assert CRS if IDLE symbols
are received without /T/R, yet in this case RXER will be asserted for one clock cycle when CRS is de-asserted. For 10T links, CRS
assertion is based on reception of valid preamble, and de-assertion on reception of an end-of-frame (EOF) marker.
Collision: Whenever the line state is half-duplex and the transmitter and receiver are active at the same time, then the KS8001
asserts its collision signal, which is asynchronous to any clock.
RMII (Reduced MII) Data Interface
RMII interface specifies a low pin count (Reduced) Media Independent Interface (RMII) intended for use between Ethernet PHYs and
Switch or Repeater ASICs. It is fully compliant with IEEE 802.3u [2].
This interface has the following characteristics:
•
•
•
•
It is capable of supporting 10Mb/s and 100Mb/s data rates
A single clock reference is sourced from the MAC to PHY (or from an external source)
It provides independent 2 bit wide (di-bit) transmit and receive data paths
It uses TTL signal levels, compatible with common digital CMOS ASIC processes
RMII Signal Definition
Signal Name
Direction
(with respect to
the PHY)
Direction
(with respect to
the MAC)
REF_CLK
Input
Input or Output
CRS_DV
RXD[1:0]
TX_EN
TXD[1:0]
Output
Output
Input
Input
Use
Synchronous clock reference for receive, transmit and control
interface
Carrier Sense/Receive Data Valid
Receive Data
Transit Enable
Transit Data
Input
Input
Output
Output
Input
Receive Error
RX_ER
Output
(Not Required)
Note: Unused MII signals, TXD[3:2], TXER need to be tied to GND when RMII is used
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KS8001
KS8001
Micrel
Reference Clock (REF_CLK)
REF_CLK is a continuous 50 MHz clock that provides the timing reference for CRS_DV, RXD[1:0], TX_EN, TXD[1:0], and RX_ER.
REF_CLK is sourced by the MAC or an external source. Switch implementations may choose to provide REF_CLK as an input or an
output depending on whether they provide a REF_CLK output or rely on an external clock distribution device. Each PHY device shall
have an input corresponding to this clock but may use a single clock input for multiple PHYs implemented on a single IC.
Carrier Sense/Receive Data Valid (CRS_DV)
CRS_DV is asserted asynchronously on detection of carrier due to the criteria relevant to the operating mode. That is, in 10BASE-T
mode, when squelch is passed or in 100BASE-X mode when 2 non-contiguous zeroes in 10 bits are detected carrier is said to be
detected.
Loss of carrier shall result in the de-assertion of CRS_DV synchronous to REF_CLK. So long as carrier criteria are being met,
CRS_DV shall remain asserted continuously from the first recovered di-bit of the frame through the final recovered di-bit and shall be
negated prior to the first REF_CLK that follows the final di-bit.
The data on RXD[1:0] is considered valid once CRS_DV is asserted. However, since the assertion of CRS_DV is asynchronous
relative to REF_CLK, the data on RXD[1:0] shall be "00" until proper receive signal decoding takes place (see definition of RXD[1:0]
behavior).
Receive Data [1:0] (RXD[1:0])
RXD[1:0] shall transition synchronously to REF_CLK. For each clock period in which CRS_DV is asserted, RXD[1:0] transfers two
bits of recovered data from the PHY. In some cases (e.g. before data recovery or during error conditions) a pre-determined value for
RXD[1:0] is transferred instead of recovered data. RXD[1:0] shall be "00" to indicate idle when CRS_DV is de-asserted. Values of
RXD[1:0] other than "00" when CRS_DV is de-asserted are reserved for out-of-band signaling (to be defined). Values other than "00"
on RXD[1:0] while CRS_DV is de-asserted shall be ignored by the MAC/repeater. Upon assertion of CRS_DV, the PHY shall ensure
that RXD[1:0]=00 until proper receive decoding takes place.
Transmit Enable (TX_EN)
Transmit Enable TX_EN indicates that the MAC is presenting di-bits on TXD[1:0] on the RMII for trans-mission. TX_EN shall be
asserted synchronously with the first nibble of the preamble and shall remain asserted while all di-bits to be transmitted are
presented to the RMII. TX_EN shall be negated prior to the first REF_CLK following the final di-bit of a frame. TX_EN shall transition
synchronously with respect to REF_CLK.
Transmit Data [1:0] (TXD[1:0])
Transmit Data TXD[1:0] shall transition synchronously with respect to REF_CLK. When TX_EN is asserted, TXD[1:0] are accepted
for transmission by the PHY. TXD[1:0] shall be "00" to indicate idle when TX_EN is de-asserted. Values of TXD[1:0] other than "00"
when TX_EN is de-asserted are reserved for out-of-band signaling (to be defined). Values other than "00" on TXD[1:0] while TX_EN
is disserted shall be ignored by the PHY.
Collision Detection
Since the definition of CRS_DV and TX_EN both contain an accurate indication of the start of frame, the MAC can reliably
regenerate the COL signal of the MII by Ending TX_EN and CRS_DV.
During the IPG time following the successful transmission of a frame, the COL signal is asserted by some transceivers as a self-test.
The Signal Quality Error (SQE) function will not be supported by the reduced MII due to the lack of the COL signal. Historically, SQE
was present to indicate that a transceiver located physically remote from the MAC was functioning. Since the reduced MII only
supports chip-to-chip connections on a PCB, SQE functionality is not required.
RX_ER
The PHY shall provide RX_ER as an output according to the rules specified in IEEE 802.3u [2] (see Clause 24, Figure 24-11 Receive State Diagram). RX_ER shall be asserted for one or more REF_CLK periods to indicate that an error (e.g. a coding error or
any error that a PHY is capable of detecting, and that may otherwise be undetectable by the MAC sublayer) was detected
somewhere in the frame presently being transferred from the PHY. RX_ER shall transition synchronously with respect to REF_CLK.
While CRS_DV is de-asserted, RX_ER shall have no effect on the MAC.
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KS8001
KS8001
Micrel
RMII AC Characteristics
RMII Transmit Timing
20ns
REF_CLK
t1
t2
TXD[1:0]
TXEN
TXER
Parameter
REF_CLK Frequency
TXEN, TXD[1:0], TX_EN, Data Setup to REF_CLK
rising edge
TXEN, TXD[1:0], TX_EN, Data hold from REF_CLK
rising edge
Min
Typ
50
Max
Units
MHz
4
ns
2
ns
RMII Receive Timing
20ns
REF_CLK
RXD[1:0]
RXDV
RXER
tod
Parameter
REF_CLK Frequency
RXD[1:0], CRS_DV, RX_ER Output delay from
REF_CLK rising edge
Min
2.8
Typ
50
Max
Units
MHz
10
ns
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KS8001
KS8001
Micrel
SMII Signal Definition
SMII is composed of two signals per port, a global synchronization signal, and a global 125MHz reference clock. All signals are
synchronous to the clock. All SMII I/F uses a common 125MHz reference clock and SYNC signals that are synchronous to the
reference clock. There are two signals in SMII from MAC-to-PHY for each port (TXD and TxSYNC), and one signal per port from
PHY-to-MAC (RXD).
The Serial Media Independent Interface (SMII) is designed to satisfy the following requirements:
•
Convey complete MII information between a 10/100 PHY and MAC with two pins per port.
•
Allow a multi-port MAC/PHY communication with one system clock.
•
Operate in both half and full duplex.
•
Per packet switching between 10Mbit and 100Mbit data rates.
•
Allow direct MAC to MAC communication.
SMII Signals
Signal Name
RX
TX
SYNC
Clock
From
PHY
MAC
MAC
System
To
MAC
PHY
PHY
MAC&PHY
Use
Receive Data and Control
Transmit Data and Control
Synchronization
Synchronization
Receive Path
Receive data and control information are signaled in ten bit segments. In 100Mbit mode, each segment represents a new byte of
data. In 10Mbit mode, each segment is repeated ten times; therefore, every ten segments represent a new byte of data. The MAC
can simply any one of every 10 segment ion 10Mbit mode.
Segment boundaries are delimited by SYNC. The MAC continuously generates a pulse on SYNC every 10 clocks.
Receive Sequence Diagram
R X_C LK
R X_SYN C
RX
CRS
RX_DV
RXD0
RXD1
RXD2
RXD3
RXD4
RXD5
RXD6
RXD7
RX contains all of the information found on the receive path of the standard MII.
Bits
Purpose
CRS
Carrier Sense – identical to MII, except that it is not an asynchronous signal
RX_DV
Receive Data Valid – identical to MII
RXD7-0
Encoded Data, see the RXD0-7 Encoding table
RX – Bit Description
RXD7-0 are used to convey packet data, RX_ER, and PHY status. The MAC can infer the meaning of RXD on a segment-by-basis
by encoding the two control bits.
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KS8001
KS8001
Micrel
CRS
RX_DV
RXD0
RXD1
RXD2
RXD3
RXD4
RXD5
RXD6
RXD7
X
0
RX_ER
from
previous
frame
Speed
0=10Mbit
1=100Mbit
Duplex
0=Half
1=Full
Link
0=Down
1=Up
Jabber
0=OK
1=Error
Upper
Nibble
0=invalid
1=valid
False
Carrier
Detected
1
X
1
One Data Byte (Two MII Data Nibble)
TXD7 – 0 Encoding
Inter-frame status bit RXD5 conveys the validity of the upper nibble of the byte of the previous frame. Inter-frame status bit RXD0
indicates whether or not the PHY detected an error somewhere on the previous frame. Both of these bits should be valid in the
segment immediately following a frame, and should stay valid until the first data segment of the next frame begins.
When asserted, inter-frame status bit RXD6 indicates that the PHY has detected a false carrier event.
In order to send receive data to the MAC synchronous to the reference clock, the PHY must pass the data through an elasticity FIFO
to handle any difference between the reference clock rate and the clock at the packet source. The Ethernet specification calls for
packet data to be referenced to a clock with a frequency tolerance of 100ppm (0.01%); however, it is not uncommon to encounter
Ethernet stations with clocks that have frequency errors up to 0.1%. Therefore, the elasticity FIFO should be at least 27 bits * long,
filling to the half-way point before beginning valid data transfer via RX. RX_ER should be asserted if, during the reception of a frame,
this fifo overflows or underflows.
Only RXD and RX_DV should be passed through the elasticity FIFO. CRS should not be passed through the elasticity FIFO. Instead,
CRS should be asserted for the time the ‘wire’ is busy receiving a frame.
Transmit Path
Transmit data and control information are signaled in ten bit segments, just like the receive path. In 100Mbit mode, each segment
represents anew byte of data. In 10Mbit mode each segment is repeated ten times; therefore, every ten segments represents a new
byte of data. The PHY can sample any one of every 10 segments in 10Mbit mode.
Segment boundaries are delimited by SYNC. The MAC continuously generates a pulse on SYNC every 10 clocks.
Transmit Sequence Diagram
TX_CLK
TX_SYNC
TX
TX_ER
Bits
TX_EN
TX_ER
TXD7-0
TX- Bit Description
TX_EN
TXD0
TXD1
TXD2
TXD3
TXD4
TXD5
TXD6
TXD7
Purpose
Transmit Enable – identical to MII
Transmit Error – identical to MII
Encoded Data – see TXD7-0 Encoding Table
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KS8001
KS8001
Micrel
As far as the PHY is concerned, TXD7-0 are used to convey only packet data. To allow for a direct MAC to MAC connection, the
MAC uses TXD7-0 to signal ‘status’ in between frames.
TX_ER
x
TX_EN
0
x
TXD7 – 0 Encoding
TXD0
Use to force
an error in a
direct MAC to
MAC
connection
1
TXD1
1
100MBit
TXD2
1
Full Duplex
TXD3
1
Link Up
TXD4
0
No Jabber
TXD7-5
1
One Data Byte (Two MII Data Nibbles)
Collision Detection
Collisions occur when CRS and TX_EN are simultaneously asserted. For this to work, the PHY must ensure that CRS is not affected
by its transmit path.
DC Specification
Parameter
Input High Voltage
Input Low Voltage
Input High Current
Input Low Current
Symbol
Vih
Vil
Iih
Iil
Min
2.0
-10
-10
Max
0.8
10
10
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Units
Volts
Volts
uA
uA
KS8001
KS8001
Micrel
Timing Specification
Parameter
Input Setup
Input Hold
Output Delay
Min
1.5
1
1.5
Max
5
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20
Units
ns
ns
ns
KS8001
KS8001
Micrel
HP Auto Crossover (Auto MDI/MDI-X)
Automatic MDI/MDI-X configuration is intended to eliminate the need for crossover cables between similar devices. The assignment
of pin-outs for a 10/100 BASE-T crossover function cable is shown below.
This feature can eliminate the confusion in real applications by allowing both straight cable and crossover cables. This feature is
controlled by register 1f:13, see “Register 1fh” section for details.
S tr a ig h t T h r o u g h C a b le
1 0 /1 0 0 B a s e -T
M e d ia D e p e n d e n t I n t e r f a c e
1 0 /1 0 0 B a s e -T
M e d ia D e p e n d e n t I n t e r f a c e
1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
T r a n s m it P a ir
R e c e iv e P a ir
R e c e iv e P a ir
T r a n s m it P a ir
M o d u la r C o n n e c t o r
(R J 4 5 )
M o d u la r C o n n e c t o r
(R J 4 5 )
N IC
HUB
( R e p e a t e r o r S w it c h )
C r o s s o v e r C a b le
1 0 /1 0 0 B A S E -T
M e d ia D e p e n d e n t I n t e r f a c e
1 0 /1 0 0 B a s e -T
M e d ia D e p e n d e n t I n t e r f a c e
1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
R e c e iv e P a ir
R e c e iv e P a ir
T r a n s m it P a ir
T r a n s m it P a ir
M o d u la r C o n n e c t o r ( R J 4 5 )
M o d u la r C o n n e c t o r ( R J 4 5 )
HUB
( R e p e a t e r o r S w it c h )
HUB
( R e p e a t e r o r S w it c h )
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KS8001
KS8001
Micrel
Auto MDI/MDI-X Cross-Over Transformer Connection
KS8001 features HP Auto MDI/MDI-X crossover and requires symmetric transformers that support Auto MDI/MDI-X. See Selection
of Isolation Transformers on p. 43 for a list of transformers that support Auto MDI/MDI-X.
Power Management
The KS8001 offers the following modes for power management:
•
•
Power Down Mode: This mode can be achieved by writing to Register 0.11 or pulling pin 30 PD# Low. In the power down
state, the KS8061 disables all internal functions and drives output pins to logic zero, except for the MII serial management
interface.
Power Saving Mode: writing to register 1fh.10 can disable this mode. The KS8001 will then turn off everything except for
the Energy Detect and PLL circuits when the cable is not installed. In other words, the KS8001 will shutdown most of the
internal circuits to save power if there is no link. Power Saving mode will be in this most effective state when AutoNegotiation Mode is enabled.
100BT FX Mode
100BT FX mode is activated when FXSD/FXEN is higher than 0.6V (This pin has a default pull down). Under this mode, the autonegotiation and auto-MDIX features are disabled.
In fiber operation FXSD pin should connect to the SD (signal detect) output of the fiber module. The internal threshold of FXSD is
around ⅔ Vdd +/- 50 mV (2.2V +/- 0.05V at 3.3V). Above this level, it is considered Fiber signal detected, and the operation is
summarized in the following table:
FXSD/FXEN
Less than 0.6V
Less than 2.15V,
but greater than 0.6V
Condition
100TX mode
FX mode
No signal detected
FEF generated
FX mode
Signal detected
Greater than 2.25V
To ensure proper operation, the swing of fiber module SD should cover the threshold variation. A resistive voltage divider is
recommended to adjust the SD voltage range.
FEF (Far End Fault), repetition of a special pattern, which consists of 84-ones and 1-zero, is generated under “FX mode with no
signal detected”. The purpose of FEF is to notify the sender of a faulty link. When receiving a FEF, the LINK will go down to indicate
a fault, even with fiber signal detected. The transmitter is not affected by receiving a FEF and still sends out its normal transmit
pattern from MAC. FEF can be disabled by strapping pin27 low, please refer to “Strapping Options” section.
Media converter operation
The KS8001 is capable of performing media conversion with 2 parts in a back-to-back RMII mode as indicated in the diagram. Both
parts are in RMII mode and with RMII_BTB asserted (pin21 & 22 strapped high). One part is operating at TX mode and the other in
FX mode. Both parts can share a common 50MHz oscillator.
Under this operation, auto-Negotiation on the TX side will prohibit 10BASE-T link up. Additional options can be implemented under
this operation. Disable the transmitter and set it at tri-state by controlling the high TXD2 pin. In order to do this, RXD2 and TXD2 pins
need to be connected via an inverter. When TXD2 pin is high in both the copper and fiber operation, it disables transmit. Meanwhile,
the RXD2 pin on the copper side serves as the energy detect and can indicate if a line signal is detected. TXD3 should be tied low
and RXD3 let float. Please contact your local Micrel FAE for a Media Converter reference design.
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22
KS8001
KS8001
Micrel
Vcc
21 22
Pin
Rx +/-
KS8001
RxD
TxD
Tx +/TxC/
Ref_CLK
OSC
TxC/
Ref_CLK
FTx
KS8001
FRx
50 MHz
(Fiber Mode)
Pin
34
TxD
RxD
Pin
21 22
Vcc
To the SD pin of the
Fiber Module
LinkMD Cable Diagnostics
The KS8001 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 and MDIX pairs and analyzing the shape of the reflected signal. Timing the duration gives an indication of the distance to the
cabling fault with maximum distance of 200 m and accuracy of +/- 2 m. Cable diagnostics are only valid for copper connections and
do not support fiber optic operation.
LinkMD is used by accessing register 1dh, the LinkMD Control/Status register in conjunction with register 1fh, the 100BASE-TX PHY
Controller register. To use LinkMD, HP Auto-MDIX is disabled by writing a ‘1’ to 1f:13 to enable manual control over which pair is
used to transmit the LinkMD pulse. The self-clearing Cable diagnostic test enable bit, 1d.15 is set to ‘1’ to start the test on this pair.
When 1d.15 returns to ‘0’, the test is complete. The test result is returned in 1d.14:13 and the distance is returned in 1d.8:0. The
cable diagnostic test results are as follows:
•
•
•
•
00 = Valid test, normal condition
01 = Valid test, open circuit in cable
10 = Valid test, short circuit in cable
11 = Invalid test, LinkMD failed
The ‘11’ case, Invalid test, occurs when it is not possible for the KS8001 to shut down the link partner. In this case, the test is not
run, since it would not be possible for the KS8001 to determine if the detected signal is a reflection of the signal generated or a
signal from another source.
Cable length can be determined by multiplying the contents of 1d.8:0 by 0.39. This constant may be calibrated for different cabling
conditions, including cables with a velocity of propagation that varies significantly from the norm.
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23
KS8001
KS8001
Micrel
Reference Clock Connection Options
KS8001 is capable of performing three different kinds of clock speed options for connecting the external reference clock depends
upon the different interface of using MII/RMII/SMII. The figures below illustrate the recommended connection for using the different
interface options. Please see the selection of reference crystal table for specifications.
XI
25MHz Osc
100ppm
XO
NC
NC
25MHz Oscillator Reference Clock Connection Diagram
22pF
22pF
XI
22pF
22pF
25MHz Xtal
100ppm
XO
25MHz Crystal Reference Clock Connection Diagram
VCC
10K
50/125MHz Osc
100ppm
NC
NC
XI
XO
REF_CLK
50/125MHz Oscillator Reference Clock Connection for RMII/SMII Mode Diagram
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24
KS8001
KS8001
Micrel
Register Map
Register No.
0h
1h
2h
3h
4h
5h
6h
7h
8h
9h-14h
15h
16h – 1ah
1bh
1ch
1dh
1eh
1fh
Address
Description
Basic Control Register
Basic Status Register
PHY Identifier I
PHY Identifier II
Auto-Negotiation Advertisement Register
Auto-Negotiation Link Partner Ability Register
Auto-Negotiation Expansion Register
Auto-Negotiation Next Page Register
Link Partner Next Page Ability
Reserved
RXER Counter Register
Reserved
Interrupt Control/Status Register
Reserved
LinkMD Control/Status Register
PHY Control Register
100BASE-TX PHY Control Register
Name
Description
Mode
Default
RW/
SC
RW
0
0
RW
Set by SPD100
RW
Set by NWAYEN
RW
0
RW
Set by ISO
RW/
SC
RW
0
RW
0
RO
R/W
0
0
Register 0h – Basic Control
0.15
Reset
1 = software reset. Bit is self-clearing
0.14
Loop-back
0.13
Speed Select
(LSB)
0.12
AutoNegotiation
Enable
0.11
Power Down
1 = loop-back mode
0 = normal operation
1 = 100Mb/s
0 = 10Mb/s
Ignored if Auto-Negotiation is enabled
(0.12 = 1)
1 = enable auto-negotiation process (override
0.13 and 0.8)
0 = disable auto-negotiation process
1 = power down mode
0 = normal operation
0.10
Isolate
0.9
Restart AutoNegotiation
0.8
Duplex Mode
0.7
Collision Test
0.6:1
0.0
Reserved
Disable
Transmitter
1 = electrical isolation of PHY from MII and
TX+/TX0 = normal operation
1 = restart auto-negotiation process
0 = normal operation. Bit is self-clearing
1 = full duplex
0 = half duplex
1 = enable COL test
0 = disable COL test
0 = enable transmitter
1 = disable transmitter
Set by DUPLEX
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25
KS8001
KS8001
Address
Micrel
Name
Description
Mode
Default
RO
0
RO
1
RO
1
RO
1
RO
1
RO
RO
0
1
RO
0
1 = remote fault
0 = no remote fault
1 = capable to perform auto-negotiation
0 = unable to perform auto-negotiation
RO/LH
0
RO
1
1 = link is up
0 = link is down
1 = jabber detected
0 = jabber not detected. Default is Low
1 = supports extended capabilities registers
RO/LL
0
RO/LH
0
RO
1
RO
0022h
RO
000101
RO
RO
100001
1010
RW
0
RO
RW
0
0
RO
0
Register 1h – Basic Status
1.15
100BASE-T4
1.14
100BASE-TX
Full Duplex
1.13
100BASE-TX
Half Duplex
1.12
10BASE-T Full
Duplex
1.11
10BASE-T Half
Duplex
1.10:7
1.6
Reserved
No Preamble
1.5
AutoNegotiation
Complete
1.4
Remote Fault
1.3
1.2
AutoNegotiation
Ability
Link Status
1.1
Jabber Detect
1.0
Extended
Capability
1 = T4 capable
0 = not T4 capable
1 = capable of 100BASE-X full duplex
0 = not capable of 100BASE-X full duplex
1 = capable of 100BASE-X half duplex
0 = not capable of 100BASE-X half duplex
1 = 10Mbps with full duplex
0 = no 10Mbps with full duplex capability
1 = 10Mbps with half duplex
0 = no 10Mbps with half duplex capability
1 = preamble suppression
0 = normal preamble
1 = auto-negotiation process completed
0 = auto-negotiation process not completed
Register 2h – PHY Identifier 1
2.15:0
rd
th
Assigned to the 3 through 18 bits of the
Organizationally Unique Identifier (OUI).
Kendin Communication’s OUI is 0010A1 (hex)
PHY ID
Number
Register 3h – PHY Identifier 2
3.15:10
PHY ID
Number
3.9:4
3.3:0
Model Number
Revision
Number
th
th
Assigned to the 19 through 24 bits of the
Organizationally Unique Identifier (OUI).
Kendin Communication’s OUI is 0010A1 (hex)
Six bit manufacturer’s model number
Four bit manufacturer’s model number
Register 4h – Auto-Negotiation Advertisement
4.15
Next Page
4.14
4.13
Reserved
Remote Fault
4.12 : 11
Reserved
1 = next page capable
0 = no next page capability.
1 = remote fault supported
0 = no remote fault
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26
KS8001
KS8001
Micrel
Address
4.10
Name
Pause
4.9
100BASE-T4
4.8
100BASE-TX
Full Duplex
4.7
100BASE-TX
4.6
10BASE-T Full
Duplex
4.5
10BASE-T
4.4:0
Selector Field
Description
1 = pause function supported
0 = no pause function
1 = T4 capable
0 = no T4 capability
1 = TX with full duplex
0 = no TX full duplex capability
1 = TX capable
0 = no TX capability
1 = 10Mbps with full duplex
0 = no 10Mbps full duplex capability
1 = 10Mbps capable
0 = no 10Mbps capability
[00001] = IEEE 802.3
Mode
RW
Default
0
RO
0
RW
Set by SPD100 & DUPLEX
RW
Set by SPD100
RW
RW
Set by
DUPLEX
1
RW
00001
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
00001
RO
0
Register 5h – Auto-Negotiation Link Partner Ability
5.15
Next Page
5.14
Acknowledge
5.13
Remote Fault
5.12
Reserved
5.11:10
Pause
5.9
100 BASE-T4
5.8
100BASE-TX
Full Duplex
5.7
100BASE-TX
5.6
10BASE-T Full
Duplex
5.5
10BASE-T
5.4:0
Selector Field
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
5.10 5 .11
0
No PAUSE
1
Asymmetric PAUSE (link partner)
0
Symmetric PAUSE
1
Symmetric & Asymmetric PAUSE (local
device)
1 = T4 capable
0 = no T4 capability
1 = TX with full duplex
0 = no TX full duplex capability
1 = TX capable
0 = no TX capability
1 = 10Mbps with full duplex
0 = no 10Mbps full duplex capability
1 = 10Mbps capable
0 = no 10Mbps capability
[00001] = IEEE 802.3
Register 6h – Auto-Negotiation Expansion
6.15:5
Reserved
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27
KS8001
KS8001
Micrel
Address
6.4
Name
Parallel
Detection Fault
6.3
Link Partner
Next Page
Able
6.2
Next Page
Able
6.1
Page Received
6.0
Link Partner
AutoNegotiation
Able
Description
1 = fault detected by parallel detection
0 = no fault detected by parallel detection.
1 = link partner has next page capability
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 yet received
1 = link partner has auto-negotiation capability
0 = link partner does not have auto-negotiation
capability
Mode
RO/
LH
RO
Default
0
RO
1
RO/
LH
RO
0
0
RW
0
RO
0
RW
1
RW
0
RO
0
RW
001
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
RO
0
RO
0
RO
0
RO
0
1 = previous value of transmitted Link Code
Word equal
to logic zero
0 = previous value of transmitted Link Code
Word equal to logic one
RO
0
RO
0
RO
0000
0
Register 7h – Auto-Negotiation Next Page
7.15
Next Page
7.14
Reserved
7.13
Message Page
7.12
Acknowledge2
7.11
Toggle
7.10:0
Message Field
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
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
Register 15h – RXER Counter
15.15:0
RXER Counter
RX Error counter for the RX_ER in each
package
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28
KS8001
KS8001
Address
Micrel
Name
Description
Mode
Default
1=Enable Jabber Interrupt
0=Disable Jabber Interrupt
RW
0
1=Enable Receive Error Interrupt
0=Disable Receive Error Interrupt
RW
0
1=Enable Page Received Interrupt
0=Disable Page Received Interrupt
RW
0
1= Enable Parallel Detect Fault Interrupt
0= Disable Parallel Detect Fault Interrupt
RW
0
1= Enable Link Partner Acknowledge Interrupt
0= Disable Link Partner Acknowledge Interrupt
RW
0
1= Enable Link Down Interrupt
0= Disable Link Down Interrupt
RW
0
1= Enable Remote Fault Interrupt
0= Disable Remote Fault Interrupt
RW
0
1= Enable Link Up Interrupt
0= Disable Link Up Interrupt
RW
0
1= Jabber Interrupt Occurred
0= Jabber Interrupt Does Not Occurred
1= Receive Error Occurred
0= Receive Error Does Not Occurred
1= Page Receive Occurred
0= Page Receive Does Not Occurred
1= Parallel Detect Fault Occurred
0= Parallel Detect Fault Does Not Occurred
1= Link Partner Acknowledge Occurred
0= Link Partner Acknowledge Does Not
Occurred
1= Link Down Occurred
0= Link Down Does Not Occurred
1= Remote Fault Occurred
0= Remote Fault Does Not Occurred
1= Link Up Interrupt Occurred
0= Link Up Interrupt Does Not Occurred
RO/SC
0
RO/SC
0
RO/SC
0
RO/SC
0
RO/SC
0
RO/SC
0
RO/SC
0
RO/SC
0
RW
SC
0
Register 1bh – Interrupt Control/Status Register
1b.15
1b.14
1b.13
1b.12
1b.11
1b.10
1b.9
1b.8
1b.7
Jabber
Interrupt
Enable
Receive Error
Interrupt
Enable
Page Received
Interrupt
Enable
Parallel Detect
Fault Interrupt
Enable
Link Partner
Acknowledge
Interrupt
Enable
Link Down
Interrupt
Enable
Remote Fault
Interrupt
Enable
Link Up
Interrupt
Enable
Jabber
Interrupt
1b.6
Receive Error
Interrupt
1b.5
Page Receive
Interrupt
1b.4
Parallel Detect
Fault Interrupt
1b.3
Link Partner
Acknowledge
Interrupt
1b.2
Link Down
Interrupt
1b.1
Remote Fault
Interrupt
1b.0
Link Up
Interrupt
Register 1dh – LinkMD Control/Status Register
1d.15
Cable
diagnostic test
enable
0 = Indicates cable diagnostic test has
completed and the status information is valid
for read.
1 = the cable diagnostic test is activated. This
bit is self-clearing.
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29
KS8001
KS8001
Micrel
Address
1d.14:13
Name
Cable
diagnostic test
result
1d.12:9
Reserved
1d.8:0
Cable fault
counter
Description
[00] = normal condition
[01] = open condition has been detected in
cable
[10] = short condition has been detected in
cable
[11] = cable diagnostic test failed
Mode
RO
Default
0
Distance to fault, approximately
0.39m*cabfaultcnt value
RO
0
RW
0
Register 1eh – PHY Control
1e:15:14
LED mode
[00] =
LED3 <- collision
LED2 <- full duplex
LED1 <- speed
LED0 <- link/activity
[01] =
LED3 <- activity
LED2 <- full duplex/collision
LED1 <- speed
LED0 <- link
[10] =
LED3 <- activity
LED2 <- full duplex
LED1 <- 100Mbps link
LED0 <- 10Mbps link
1e.13
Polarity
1e.12
Far end fault
detect
1e.11
MDIX/MDI
state
1e:10:8
Reserved
1e:7
Remote
loopback
1e:6:0
Reserved
[11] = reserved
0 = Polarity is not reversed
1 = Polarity is reversed
0 = Far end fault detected
1 = Far end fault not detected
0 = MDIX
1 = MDI
0: normal mode
1: remote (analog) loop back is enable
RO
RO
RO
RW
0
Register 1fh – 100BASE-TX PHY Controller
1f:15
Reserved
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30
KS8001
KS8001
Micrel
Address
1f:14
Name
Mdi/mdix
select when
auto mdi/mdix
is disable
1f:13
Pairswap
disable
1f.12
Energy detect
1f.11
Force link
1f.10
Power Saving
1f.9
Interrupt Level
1f.8
Enable Jabber
1f.7
AutoNegotiation
Complete
Enable Pause
(Flow-Control
Result)
PHY Isolate
1f.6
1f.5
1f.4:2
Operation
Mode
Indication
1f.1
Enable SQE
test
1f.0
Disable Data
Scrambling
Description
0 = transmit on pair A (TPFINn/TPFIPn) and
receive on pair B (TPFONn/TPFOPn).
1 = transmit on pair B (TPFONn/TPFOPn) and
receive on pair A (TPFINn/TPFIPn).
1 = disable MDI/MDIX
0 = enable MDI/MDIX
1 = presence of signal on RX+/- analog wire
pair
0 = no signal detected on RX+/1 = force link pass
0 = normal link operation
This bit bypasses the control logic and allow
transmitter to send pattern even if there is no
link.
1 = enable power saving
0 = disable
1 = interrupt pin active high
0 = active low
1 = enable jabber counter
0 = disable
1 = auto-negotiation complete
0 = not complete
Mode
R/W
Default
R/W
0
RO
0
R/W
0
RW
1
RW
0
RW
1
RW
0
1 = flow control capable
0 = no flow control
RO
0
1 = PHY in isolate mode
0 = not isolated
[000] = still in auto-negotiation
[001] = 10BASE-T half duplex
[010] = 100BASE-TX half duplex
[011] = default
[101] = 10BASE-T full duplex
[110] = 100BASE-TX full duplex
[111] = PHY/MII isolate
1 = enable SQE test
0 = disable
1 = disable scrambler
0 = enable
RO
0
RO
0
RW
0
RW
0
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31
KS8001
KS8001
Micrel
Absolute Maximum Rating (Note 1)
Operating Range (Note 2)
Storage Temperature (TS) ……………… -55°C to
+150°C
Supply Referenced to GND…… ………-0.5V to +4.0
All pins …………………………………....-0.5V to +4.0
Supply Voltage
(VDD_PLL, VDD_TX, VDD_RXC, VDDC)…………1.8V ± 5%
(VDD_RCV, VDDIO)……………………………3.3V ± 5%
Ambient Temperature Commercial (TA)...…0°C to
+70°C
Ambient Temperature Industrial (TA)….…-40°C to
+85°C
Important: Please read the Notes at the bottom of the
page.
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32
KS8001
KS8001
Micrel
Package Thermal Resistance (θJA)(Note 3)
θJA
θJA
Thermal Resistance
θJA
θJC
Airflow Velocity (m/s)
0
1
2
0
LQFP
83.56
77.08
72.36
46.93
SSOP
75.19
68.20
66.20
TBD
Electrical Characteristics (Note4)
VDD=3.3V ±10%
Symbol
Parameter
Condition
Total Supply Current (including TX output drive current)
IDD1
IDD2
IDD3
IDD4
IDD5
Normal 100BASE-TX
Normal 10BASE-T
Power Saving Mode 1
Power Down Mode
(software power down)
Min
Typ
Max
Units
(Note 5)
Including 40mA output current
mA
Including 90mA output current,
indepdendent of utilization
mA
Auto-negotiation is Enabled
mA
mA
Power down pin (PD#)
TTL Inputs
VIH
Input High Voltage
VIL
Input Low Voltage
IIN
Input Current
½ VDD (I/O)
+ 0.2
VIN = GND – VDD
V
-10
0.8
V
10
µA
TTL Outputs
VOH
Output High Voltage
IOH = -4mA
½ VDD (I/O)
+ 0.6
V
VOL
Output Low Voltage
0.4
V
I IOZ I
Output Tri-State Leakage
10
µA
100BASE-TX Transmit (measured differentially after 1:1 transformer)
Peak Differential Ouput
Voltage
50Ω from each output to VDD
VIMB
Output Voltage Imbalance
50Ω from each output to VDD
tr, tt
Rise/Fall Time
Rise/Fall Time Imbalance
VO
0.95
1.05
2
%
3
0
5
0.5
ns
ns
±0.5
ns
Duty Cycle Distortion
Overshoot
VSET
V
%
Refernce Voltage of ISET
0.75
Propagation Delay
45
60
ns
V
Jitter
0.7
1.4
ns(pk-pk)
10BASE-T Transmit (measured differentially after 1:1 transformer)
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33
KS8001
KS8001
Micrel
VP
Peak Differential Ouput
Voltage
50Ω from each output to VDD
VIMB
Output Voltage Imbalance
50Ω from each output to VDD
tr, tt
Rise/Fall Time
2.2
2.8
±3.5
25
V
ns
ns
Clock Outputs
X1, X2
Crystal Oscillator
25
MHz
RXC100
Receive Clock, 100TX
25
MHz
RXC10
Receive Clock, 10T
2.5
MHz
Receive Clock Jitter
3.0
ns(pk-pk)
TXC100
Transmit Clock, 100TX
25
MHz
TXC10
Transmit Clock, 10T
2.5
MHz
Transmit Clock Jitter
1.8
ns(pk-pk)
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
Exceeding the absolute rating(s) may cause permanent damage to the device. Operating at maximum conditions for extended
periods may affect device reliability.
This device is not guaranteed to operate beyond its specified operating rating. Unused inputs must always be tied to an
appropriate logic voltage level (Ground to VDD).
No HS (heat spreader) in package.
Specification for packaged product only.
100% data transmission in full-duplex mode and minimum IPG with 130-meter cable.
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34
KS8001
KS8001
Micrel
Timing Diagrams
1 0 B a seT M II T ra n sm it T im in g
tH D 2
TXC
TXEN
T X D [3 :0 ]
CRS
T X P /T X M
tSU 2
tH D 1
tSU 1
tC R S1
t LA T
tC R S2
V a lid
D a ta
S Q E T im in g
TXC
TXEN
COL
tSQ E
tSQ E P
m in.
t SU 1
t SU 2
tH D 1
tH D 2
t C R S1
t C R S2
tLA T
t SQ E
t SQ E P
T X D [3 :0 ] S etup to T X C H igh
T X E N S etup to T X C H igh
T X D [3 :0 ] H o ld after T X C H igh
T X E N H o ld after T X C H igh
T X E N H igh to C R S asserted latency
T X E N L o w to C R S d e-asserted latency
T X E N H igh to T X P /T X M o utp ut (T X latency)
C O L (S Q E ) D elay after T X E N d e-asserted
C O L (S Q E ) P ulse D uratio n
typ .
m ax.
1 0 ns
1 0 ns
0 ns
0 ns
4BT
8BT
4BT
2 .5 us
1 .0 us
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35
KS8001
KS8001
Micrel
100BaseTX MII Transmit Timing
TXC
tSU2
TXEN
tSU1
TXD[3:0],
TXER
tHD2
tHD1
Data
In
tCRS2
tCRS1
CRS
tLAT
TX+/TX-
Symbol
Out
min.
tSU1
tSU2
tHD1
tHD2
tHD3
tCRS1
tCRS2
tLAT
TXD[3:0] Setup to TXC High
TX_ER Setup to TXC High
TXD[3:0] Hold after TXC High
TXER Hold after TXC High
TXEN Hold after TXC High
TXEN High to CRS asserted latency
TXEN Low to CRS de-asserted latency
TXEN High to TX+/TX- output (TX latency)
typ.
max.
10ns
10ns
0ns
0ns
0ns
4BT
4BT
7BT
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36
KS8001
KS8001
Micrel
100BaseTX MII Receive Timing
RX+/RX-
Start of
Stream
End of
Stream
tCRS1
CRS
tCRS2
tRLAT
RXDV
RXD[3:0]
RXER
tSU
tHD
RXC
tWL
tWH
tP
min.
tP
tWL
tWH
tSU
tHD
tRLAT
tCRS1
tCRS2
RXC period
RXC pulse width
RXC pulse width
RXD[3:0], RXER, RXDV setup to rising edge of RXC
RXD[3:0], RXER, RXDV hold from rising edge of RXC
CRS to RXD latency, 4B or 5B aligned
"Start of Stream" to CRS asserted
"End of Stream" to CRS de-asserted
typ.
max.
40ns
20ns
20ns
1BT
20ns
20ns
2BT
140ns
170ns
3BT
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37
KS8001
KS8001
Micrel
Auto Negotiation / Fast Link Pulse Timing
FLP
Burst
FLP
Burst
TX+/TX-
tFLPW
tBTB
TX+/TX-
Clock
Pulse
Data
Pulse
tPW
tPW
Data
Pulse
Clock
Pulse
tCTD
tCTC
tBTB
tFLPW
tPW
tCTD
tCTC
FLP burst to FLP burst
FLP burst width
Clock/Data pulse width
Clock pulse to data pulse
Clock pulse to clock pulse
Number of Clock/Data pulses per burst
min.
typ.
max.
8ms
16ms
2ms
100ns
69us
136us
24ms
17
33
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38
KS8001
KS8001
Micrel
Serial Management Interface Timing
tP
MDC
tMD1
MDIO
(Into Chip)
tMD2
Valid
Data
Valid
Data
tMD3
MDIO
(Out of Chip)
Valid
Data
min.
tP
tMD1
tMD2
tMD3
MDC period
MDIO Setup to MDC (MDIO as input)
MDIO Hold after MDC (MDIO as input)
MDC to MDIO Valid (MDIO as output)
typ.
max.
400 ns
10ns
10ns
222ns
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39
KS8001
KS8001
Micrel
Reset Timing Diagram
Supply
Voltage
tsr
RST_N
Strap-In
Value
Reset Timing Parameters
Parameter
tsr
Description
Stable supply voltages to reset high
Min
50
Max
Units
us
Reset Circuit Diagram
Micrel recommends the following discrete reset circuit as shown in Figure 1 when powering up the KS8001 device. For the
application where the reset circuit signal comes from another device (e.g., CPU, FPGA, etc), we recommend the reset circuit as
shown in Figure 2.
VCC
KS8001
D1
R 10K
CPU/FPGA
RST
RST_OUT_n
C 10uF
D2
D1, D2: 1N4148
Recommended Reset Circuit
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40
KS8001
KS8001
Micrel
VCC
D1: 1N4148
KS8001
D1
R 10K
RST
C 10uF
Recommended Circuit for Interfacing with CPU/FPGA Reset
At power-on-reset, R, C, and D1 provide the necessary ramp rise time to reset the Micrel device. The reset out
from CPU/FPGA provides warm reset after power up. It is also recommend to power up VDD core voltage earlier
than VDDIO voltage. At worst case, the both VDD core and VDDIO voltages should come up at the same time.
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41
KS8001
KS8001
Micrel
Reference Circuit for Strapping Option Configuration
The Figure shows the reference circuit for strapping option pins
3.3 V
220Ω
Pull Up
10ΚΩ
LED pin
KS8001
3.3 V
Pull Down
220Ω
LED pin
KS8001
1Κ Ω
Reference circuits for unm anaged program m ing through LED ports
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42
KS8001
KS8001
Micrel
Selection of Isolation Transformers
A 1:1 isolation transformer is required at the line interface. An isolation transformer with integrated common-mode choke is
recommended for exceeding FCC requirements. The following table gives recommended transformer characteristics.
Parameter
Turns Ratio
Open-Circuit Inductance (min.)
Leakage Inductance (max.)
Inter-Winding Capacitance (max.)
D.C. Resistance (max.)
Insertion Loss (max.)
HIPOT (min.)
Transformer Selection Criteria
Value
1 CT : 1 CT
350 uH
0.4 uH
12 pF
0.9 Ohms
1.0 dB
1500 Vrms
Test Condition
100 mV, 100 kHz, 8 mA
1 MHz (min.)
0-65 MHz
Magnetic Vendor Selection Lists
Single Port
Magnetic manufacturer
Pulse
Bel Fuse
Bel Fuse
Bel Fuse
YCL
Transpower
Delta
LanKom
Part number
H1102
S558-5999-U7
SI-46001
SI-50170
PT163020
HB726
LF8505
LF-H41S
AUTO MDIX
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Number of port
1
1
1
1
1
1
1
1
Selection of Reference Crystal
An oscillator or crystal with the following typical characteristics is recommended.
Charateristics
Frequency
Frequency Tolerance(max)
Load Capacitance (max)
Series Resistance
Value
25.00000
± 50
20
40
Units
MHz
ppm
pF
Ω
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43
KS8001
KS8001
Micrel
Package Information
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44
KS8001