KSZ9021GQ479.24 KB

KSZ9021GQ
Gigabit Ethernet Transceiver
with GMII / MII Support
General Description
Features
The KSZ9021GQ is a completely integrated triple speed
• Single-chip 10/100/1000 Mbps IEEE 802.3 compliant
(10Base-T/100Base-TX/1000Base-T) Ethernet Physical
Ethernet Transceiver
Layer Transceiver for transmission and reception of data
• GMII/MII standard compliant interface
on standard CAT-5 unshielded twisted pair (UTP) cable.
• Auto-negotiation to automatically select the highest link
The KSZ9021GQ provides the industry standard GMII/MII
up speed (10/100/100 Mbps) and duplex (half/full)
(Gigabit Media Independent Interface / Media Independent
• On-chip termination resistors for the differential pairs
Interface) for direct connection to GMII/MII MACs in
• On-chip LDO controller to support single 3.3V supply
Gigabit Ethernet Processors and Switches for data transfer
operation – requires only external FET to generate 1.2V
at 1000 Mbps or 10/100 Mbps speed.
for the core
The KSZ9021GQ reduces board cost and simplifies board
•
Jumbo frame support up to 16KB
layout by using on-chip termination resistors for the four
• 125MHz Reference Clock Output
differential pairs and by integrating a LDO controller to
drive a low cost MOSFET to supply the 1.2V core.
• Programmable LED outputs for link, activity and speed
The KSZ9021GQ provides diagnostic features to facilitate
• Baseline Wander Correction
®
system bring-up and debugging in production testing and
• LinkMD TDR-based cable diagnostics for identification
in product deployment. Parametric NAND tree support
of faulty copper cabling
enables fault detection between KSZ9021 I/Os and board.
®
• Parametric NAND Tree support for fault detection
Micrel LinkMD TDR-based cable diagnostics permit
between chip I/Os and board.
identification of faulty copper cabling. Remote and local
•
Loopback modes for diagnostics
loopback functions provide verification of analog and
digital data paths.
• Automatic MDI/MDI-X crossover for detection and
correction of pair swap at all speeds of operation
The KSZ9021GQ is available in a 128-pin, lead-free PQFP
package (See Ordering Information).
____________________________________________________________________________________________________________
RJ-45
CONNECTOR
MAGNETICS
ON-CHIP TERMINATION
RESISTORS
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
September 2010
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
More Features
Applications
• Automatic detection and correction of pair swaps, pair
skew and pair polarity
• MDC/MDIO Management Interface for PHY register
configuration
• Interrupt pin option
• Power down and power saving modes
• Operating Voltages
Core:
1.2V (external FET or regulator)
I/O:
3.3V or 2.5V
Transceiver:
3.3V
• Available in 128-pin PQFP (14mm x 20mm) package
•
•
•
•
•
•
•
•
•
•
•
Laser/Network Printer
Network Attached Storage (NAS)
Network Server
Gigabit LAN on Motherboard (GLOM)
Broadband Gateway
Gigabit SOHO/SMB Router
IPTV
IP Set-top Box
Game Console
Triple-play (data, voice, video) Media Center
Media Converter
Ordering Information
Part Number
KSZ9021GQ
KSZ9021GQI
(1)
Temp. Range
Package
Lead Finish
Description
0°C to 70°C
128-Pin PQFP
Pb-Free
GMII / MII, Commercial Temperature
-40°C to 85°C
128-Pin PQFP
Pb-Free
GMII / MII, Industrial Temperature
Note:
1.
Contact factory for lead time.
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KSZ9021GQ
Revision History
Revision
Date
Summary of Changes
1.0
1/16/09
Data sheet created
1.1
10/13/09
Updated current consumption in Electrical Characteristics section.
Corrected data sheet omission of register 1 bit 8 for 1000Base-T Extended Status information.
Added the following register bits to provide further power saving during software power down: Tristate all digital I/Os (reg. 258.7), LDO disable (reg. 263.15), Low frequency oscillator mode (reg. 263.8).
Corrected tsu minimum for 1000Base-T in GMII Receive Timing Parameters table.
1.2
9/10/10
Added support for 2.5V VDD I/O.
Added LED drive current.
Updated KSZ9021GQ pin outs throughout data sheet to reflect pin out changes for silicon revision A3.
Updated boilerplate.
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KSZ9021GQ
Contents
Pin Configuration .................................................................................................................................................................. 8
Pin Description ...................................................................................................................................................................... 9
Strapping Options ............................................................................................................................................................... 18
Functional Overview ........................................................................................................................................................... 19
Functional Description: 10Base-T/100Base-TX Transceiver ......................................................................................... 20
100Base-TX Transmit....................................................................................................................................................... 20
100Base-TX Receive........................................................................................................................................................ 20
Scrambler/De-scrambler (100Base-TX only).................................................................................................................... 20
10Base-T Transmit ........................................................................................................................................................... 20
10Base-T Receive ............................................................................................................................................................ 20
Functional Description: 1000Base-T Transceiver........................................................................................................... 21
Analog Echo Cancellation Circuit ..................................................................................................................................... 21
Automatic Gain Control (AGC) ......................................................................................................................................... 21
Analog-to-Digital Converter (ADC) ................................................................................................................................... 21
Timing Recovery Circuit.................................................................................................................................................... 22
Adaptive Equalizer ............................................................................................................................................................ 22
Trellis Encoder and Decoder ............................................................................................................................................ 22
Functional Description: Additional 10/100/1000 PHY Features..................................................................................... 22
Auto MDI/MDI-X................................................................................................................................................................ 22
Pair- Swap, Alignment, and Polarity Check...................................................................................................................... 23
Wave Shaping, Slew Rate Control and Partial Response................................................................................................ 23
PLL Clock Synthesizer...................................................................................................................................................... 23
Auto-Negotiation ................................................................................................................................................................. 23
GMII Interface....................................................................................................................................................................... 25
GMII Signal Definition ....................................................................................................................................................... 26
GMII Signal Diagram ........................................................................................................................................................ 26
MII Interface ......................................................................................................................................................................... 27
MII Signal Definition.......................................................................................................................................................... 28
MII Signal Diagram ........................................................................................................................................................... 28
MII Management (MIIM) Interface....................................................................................................................................... 29
Interrupt (INT_N).................................................................................................................................................................. 29
LED Mode............................................................................................................................................................................. 29
4-LED Configuration ......................................................................................................................................................... 30
5-LED Configuration ......................................................................................................................................................... 30
6-LED Configuration ......................................................................................................................................................... 31
NAND Tree Support ............................................................................................................................................................ 32
Power Management ............................................................................................................................................................ 33
Power Saving Mode.......................................................................................................................................................... 33
Software Power Down Mode ............................................................................................................................................ 33
Chip Power Down Mode ................................................................................................................................................... 33
Register Map........................................................................................................................................................................ 34
Register Description ........................................................................................................................................................... 35
IEEE Defined Registers .................................................................................................................................................... 35
Vendor Specific Registers ................................................................................................................................................ 41
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KSZ9021GQ
Extended Registers .......................................................................................................................................................... 44
(1)
Absolute Maximum Ratings ............................................................................................................................................ 46
(2)
Operating Ratings ............................................................................................................................................................ 46
(3)
Electrical Characteristics ................................................................................................................................................ 46
Timing Diagrams ................................................................................................................................................................. 49
GMII Transmit Timing ....................................................................................................................................................... 49
GMII Receive Timing ........................................................................................................................................................ 50
MII Transmit Timing .......................................................................................................................................................... 51
MII Receive Timing ........................................................................................................................................................... 52
Auto-Negotiation Timing ................................................................................................................................................... 53
MDC/MDIO Timing ........................................................................................................................................................... 54
Reset Timing..................................................................................................................................................................... 55
Reset Circuit ........................................................................................................................................................................ 55
Reference Circuits – LED Strap-in Pins............................................................................................................................ 56
Reference Clock – Connection & Selection ..................................................................................................................... 57
Magnetics Specification ..................................................................................................................................................... 57
Package Information ........................................................................................................................................................... 58
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KSZ9021GQ
List of Figures
Figure 1.
KSZ9021GQ Block Diagram............................................................................................................................... 19
Figure 2.
KSZ9021GQ 1000Base-T Block Diagram – Single Channel.............................................................................. 21
Figure 3.
Auto-Negotiation Flow Chart............................................................................................................................... 24
Figure 4.
KSZ9021GQ GMII Interface ............................................................................................................................... 26
Figure 5.
KSZ9021GQ MII Interface .................................................................................................................................. 28
Figure 6.
GMII Transmit Timing – Data Input to PHY ........................................................................................................ 49
Figure 7.
GMII Receive Timing – Data Input to MAC ........................................................................................................ 50
Figure 8.
MII Transmit Timing – Data Input to PHY ........................................................................................................... 51
Figure 9.
MII Receive Timing – Data Input to MAC ........................................................................................................... 52
Figure 10. Auto-Negotiation Fast Link Pulse (FLP) Timing ................................................................................................. 53
Figure 11. MDC/MDIO Timing.............................................................................................................................................. 54
Figure 12. Reset Timing....................................................................................................................................................... 55
Figure 13. Recommended Reset Circuit.............................................................................................................................. 55
Figure 14. Recommended Reset Circuit for Interfacing with CPU/FPGA Reset Output. .................................................... 56
Figure 15. Reference Circuits for LED Strapping Pins......................................................................................................... 56
Figure 16. 25MHz Crystal / Oscillator Reference Clock Connection ................................................................................... 57
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KSZ9021GQ
List of Tables
Table 1.
MDI / MDI-X Pin Mapping .................................................................................................................................... 22
Table 2.
Auto-Negotiation Timers ...................................................................................................................................... 25
Table 3.
GMII Signal Definition .......................................................................................................................................... 26
Table 4.
MII Signal Definition ............................................................................................................................................. 28
Table 5.
MII Management Frame Format – for KSZ9021GQ ............................................................................................ 29
Table 6.
4-LED Configuration – Pin Definition ................................................................................................................... 30
Table 7.
5-LED Configuration – Pin Definition ................................................................................................................... 30
Table 8.
6-LED Configuration – Pin Definition ................................................................................................................... 31
Table 9.
NAND Tree Test Pin Order – for KSZ9021GQ .................................................................................................... 32
Table 10. GMII Transmit Timing Parameters....................................................................................................................... 49
Table 11. GMII Receive Timing Parameters........................................................................................................................ 50
Table 12. MII Transmit Timing Parameters.......................................................................................................................... 51
Table 13. MII Receive Timing Parameters........................................................................................................................... 52
Table 14. Auto-Negotiation Fast Link Pulse (FLP) Timing Parameters ............................................................................... 53
Table 15. MDC/MDIO Timing Parameters ........................................................................................................................... 54
Table 16. Reset Timing Parameters .................................................................................................................................... 55
Table 17. Reference Crystal/Clock Selection Criteria.......................................................................................................... 57
Table 18. Magnetics Selection Criteria ................................................................................................................................ 57
Table 19. Qualified Single Port 10/100/1000 Magnetics...................................................................................................... 57
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KSZ9021GQ
Pin Configuration
128-Pin PQFP
(Top View)
September 2010
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Micrel, Inc.
KSZ9021GQ
Pin Description
Type
(1)
Pin Number
Pin Name
1
NC
-
No connect
2
NC
-
No connect
3
NC
-
No connect
4
NC
-
No connect
5
NC
-
No connect
No connect
6
NC
-
7
TXRXP_A
I/O
Pin Function
Media Dependent Interface[0], positive signal of differential pair
1000Base-T Mode:
TXRXP_A corresponds to BI_DA+ for MDI configuration and BI_DB+ for
MDI-X configuration, respectively.
10Base-T / 100Base-TX Mode:
TXRXP_A is the positive transmit signal (TX+) for MDI configuration and
the positive receive signal (RX+) for MDI-X configuration, respectively.
8
TXRXM_A
I/O
Media Dependent Interface[0], negative signal of differential pair
1000Base-T Mode:
TXRXM_A corresponds to BI_DA- for MDI configuration and BI_DB- for
MDI-X configuration, respectively.
10Base-T / 100Base-TX Mode:
TXRXM_A is the negative transmit signal (TX-) for MDI configuration and
the negative receive signal (RX-) for MDI-X configuration, respectively.
9
AVDDH
P
3.3V analog VDD
10
AGNDH
Gnd
Analog ground
11
AGNDL_ADC_A
Gnd
Analog ground
12
AVDDL
P
1.2V analog VDD
13
AVDDL
P
14
AGNDL_ADC_B
Gnd
Analog ground
15
AGNDH
Gnd
Analog ground
16
AVDDH
P
17
TXRXP_B
I/O
1.2V analog VDD
3.3V analog VDD
Media Dependent Interface[1], positive signal of differential pair
1000Base-T Mode:
TXRXP_B corresponds to BI_DB+ for MDI configuration and BI_DA+ for
MDI-X configuration, respectively.
10Base-T / 100Base-TX Mode:
TXRXP_B is the positive receive signal (RX+) for MDI configuration and
the positive transmit signal (TX+) for MDI-X configuration, respectively.
18
TXRXM_B
I/O
Media Dependent Interface[1], negative signal of differential pair
1000Base-T Mode:
TXRXM_B corresponds to BI_DB- for MDI configuration and BI_DA- for
MDI-X configuration, respectively.
10Base-T / 100Base-TX Mode:
TXRXM_B is the negative receive signal (RX-) for MDI configuration and
the negative transmit signal (TX-) for MDI-X configuration, respectively.
19
September 2010
AGNDH
Gnd
Analog ground
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Micrel, Inc.
KSZ9021GQ
Pin Number
Pin Name
Type
20
TXRXP_C
I/O
(1)
Pin Function
Media Dependent Interface[2], positive signal of differential pair
1000Base-T Mode:
TXRXP_C corresponds to BI_DC+ for MDI configuration and BI_DD+ for
MDI-X configuration, respectively.
10Base-T / 100Base-TX Mode:
TXRXP_C is not used.
21
TXRXM_C
I/O
Media Dependent Interface[2], negative signal of differential pair
1000Base-T Mode:
TXRXM_C corresponds to BI_DC- for MDI configuration and BI_DD- for
MDI-X configuration, respectively.
10Base-T / 100Base-TX Mode:
TXRXM_C is not used.
22
AVDDH
P
3.3V analog VDD
23
AGNDH
Gnd
Analog ground
24
AGNDL_ADC_C
Gnd
Analog ground
25
AVDDL
P
1.2V analog VDD
26
AVDDL
P
1.2V analog VDD
27
AGNDL_ADC_D
Gnd
28
AGNDH
Gnd
29
AVDDH
P
30
TXRXP_D
I/O
Analog ground
Analog ground
3.3V analog VDD
Media Dependent Interface[3], positive signal of differential pair
1000Base-T Mode:
TXRXP_D corresponds to BI_DD+ for MDI configuration and BI_DC+ for
MDI-X configuration, respectively.
10Base-T / 100Base-TX Mode:
TXRXP_D is not used.
31
TXRXM_D
I/O
Media Dependent Interface[3], negative signal of differential pair
1000Base-T Mode:
TXRXM_D corresponds to BI_DD- for MDI configuration and BI_DC- for
MDI-X configuration, respectively.
10Base-T / 100Base-TX Mode:
TXRXM_D is not used.
32
AVDDH
P
3.3V analog VDD
33
NC
-
No connect
34
NC
-
No connect
35
NC
-
No connect
36
NC
-
No connect
37
NC
-
No connect
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Micrel, Inc.
KSZ9021GQ
Pin Number
Pin Name
38
LED6
Type
(1)
I/O
Pin Function
LED Output:
Programmable LED6 Output
The LED6 pin is programmed via register 11h bits [7:6], LED_SEL[1:0], and is
defined as followed:
LED_SEL[1:0] = (1,1)
// 6-LED Configuration (default)
LED_SEL[1:0] = (0,1)
// 5-LED Configuration
10Base-T Link
Pin State
LED Definition
Link off
H
OFF
Link on
L
ON
LED_SEL[1:0] = (1,0)
// 4-LED Configuration
10Base-T – Link / Activity
Pin State
LED Definition
Link off
H
OFF
Link on
L
ON
Activity (RX, TX)
Toggle
Blinking
LED_SEL[1:0] = (0,0)
// Reserved – not used
39
DVDDL
P
40
VSS
Gnd
Digital ground
41
VSS
Gnd
Digital ground
42
LED5 /
I/O
LED Output:
Programmable LED5 Output /
Configuration Mode:
The pull-up/pull-down value is latched as PHYADD[4]
during power-up / reset. See “Strapping Options”
section for details.
PHYAD4
1.2V digital VDD
The LED5 pin is programmed via register 11h bits [7:6], LED_SEL[1:0], and is
defined as followed:
LED_SEL[1:0] = (1,1)
// 6-LED Configuration (default)
LED_SEL[1:0] = (0,1)
// 5-LED Configuration
100Base-T Link
Pin State
LED Definition
Link off
H
OFF
Link on
L
ON
LED_SEL[1:0] = (1,0)
100Base-T – Link / Activity
Pin State
LED Definition
Link off
H
OFF
Link on
L
ON
Activity (RX, TX)
Toggle
Blinking
LED_SEL[1:0] = (0,0)
September 2010
// 4-LED Configuration
11
// Reserved – not used
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Pin Number
Pin Name
43
LED4 /
Type
I/O
PHYAD3
(1)
Pin Function
LED Output:
Programmable LED4 Output /
Configuration Mode:
The pull-up/pull-down value is latched as PHYADD[3]
during power-up / reset. See “Strapping Options”
section for details.
The LED4 pin is programmed via register 11h bits [7:6], LED_SEL[1:0], and is
defined as follows:
LED_SEL[1:0] = (1,1)
// 6-LED Configuration (default)
LED_SEL[1:0] = (0,1)
// 5-LED Configuration
1000Base-T Link
Pin State
LED Definition
Link off
H
OFF
Link on
L
ON
LED_SEL[1:0] = (1,0)
1000Base-T – Link / Activity
Pin State
LED Definition
Link off
H
OFF
Link on
L
ON
Activity (RX, TX)
Toggle
Blinking
LED_SEL[1:0] = (0,0)
44
LED3 /
PHYAD2
I/O
// 4-LED Configuration
// Reserved – not used
LED Output:
Programmable LED3 Output /
Configuration Mode:
The pull-up/pull-down value is latched as PHYADD[2]
during power-up / reset. See “Strapping Options”
section for details.
The LED3 pin is programmed via register 11h bits [7:6], LED_SEL[1:0], and is
defined as follows:
LED_SEL[1:0] = (1,1)
// 6-LED Configuration (default)
LED_SEL[1:0] = (0,1)
// 5-LED Configuration
LED_SEL[1:0] = (1,0)
// 4-LED Configuration
Duplex / Collision
Pin State
LED Definition
Half Duplex
H
OFF
Full Duplex
L
ON
Collision
Toggle
Blinking
LED_SEL[1:0] = (0,0)
September 2010
12
// Reserved – not used
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Pin Number
Pin Name
45
LED2 /
Type
(1)
I/O
PHYAD1
Pin Function
LED Output:
Programmable LED2 Output /
Configuration Mode:
The pull-up/pull-down value is latched as PHYADD[1]
during power-up / reset. See “Strapping Options”
section for details.
The LED2 pin is programmed via register 11h bits [7:6], LED_SEL[1:0], and is
defined as follows:
LED_SEL[1:0] = (1,1)
// 6-LED Configuration (default)
Receive Activity
Pin State
LED Definition
No Receive Activity
H
OFF
Receive Activity
L, Toggle
ON, Blinking
LED_SEL[1:0] = (0,1)
// Reserved – not used
LED2 pin is internally pulled high.
LED_SEL[1:0] = (1,0)
// Reserved – not used
LED2 pin is internally pulled high.
LED_SEL[1:0] = (0,0)
46
DVDDH
P
47
VSSPST
Gnd
LED1 /
I/O
48
PHYAD0
// Reserved – not used
3.3V or 2.5V digital VDD
Digital ground
LED Output:
Programmable LED1 Output /
Configuration Mode:
The pull-up/pull-down value is latched as PHYADD[0]
during power-up / reset. See “Strapping Options”
section for details.
The LED1 pin is programmed via register 11h bits [7:6], LED_SEL[1:0], and is
defined as follows:
LED_SEL[1:0] = (1,1)
// 6-LED Configuration (default)
Transmit Activity
Pin State
LED Definition
No Transmit Activity
H
OFF
Transmit Activity
L, Toggle
ON, Blinking
LED_SEL[1:0] = (0,1)
// 5-LED Configuration
Receive/Transmit Activity
Pin State
LED Definition
No Receive/Transmit Activity
H
OFF
Receive/Transmit Activity
L, Toggle
ON, Blinking
LED_SEL[1:0] = (1,0)
// Reserved – not used
LED1 pin is internally pulled high.
LED_SEL[1:0] = (0,0)
49
DVDDL
P
50
VSS
Gnd
September 2010
// Reserved – not used
1.2V digital VDD
Digital ground
13
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Pin Number
Pin Name
51
TXD0
I
52
TXD1
I
53
TXD2
Type
(1)
I
Pin Function
GMII Mode:
GMII TXD0 (Transmit Data 0) Input
MII Mode:
MII TXD0 (Transmit Data 0) Input
GMII Mode:
GMII TXD1 (Transmit Data 1) Input
MII Mode:
MII TXD1 (Transmit Data 1) Input
GMII Mode:
GMII TXD2 (Transmit Data 2) Input
MII Mode:
MII TXD2 (Transmit Data 2) Input
GMII Mode:
GMII TXD3 (Transmit Data 3) Input
MII Mode:
MII TXD3 (Transmit Data 3) Input
54
TXD3
I
55
VSS
Gnd
56
DVDDL
P
57
DVDDH
P
3.3V or 2.5V digital VDD
58
TXD4
I
GMII Mode:
GMII TXD4 (Transmit Data 4) Input
MII Mode:
This pin is not used and can be driven high or low
59
TXD5
I
60
TXD6
I
61
TXD7
I
Digital ground
1.2V digital VDD
GMII Mode:
GMII TXD5 (Transmit Data 5) Input
MII Mode:
This pin is not used and can be driven high or low
GMII Mode:
GMII TXD6 (Transmit Data 6) Input
MII Mode:
This pin is not used and can be driven high or low
GMII Mode:
GMII TXD7 (Transmit Data 7) Input
MII Mode:
This pin is not used and can be driven high or low
62
VSSPST
Gnd
63
DVDDH
P
3.3V or 2.5V digital VDD
Digital ground
64
TX_ER
I
GMII Mode:
GMII TX_ER (Transmit Error) Input
MII Mode:
MII TX_ER (Transmit Error) Input
If GMII / MII MAC does not provide the TX_ER output signal, this pin should be
tied low.
65
GTX_CLK
I
66
VSSPST
Gnd
67
TX_EN
I
68
DVDDH
P
3.3V or 2.5V digital VDD
69
DVDDH
P
3.3V or 2.5V digital VDD
70
RXD7
O
GMII Mode:
GMII RXD7 (Receive Data 7) Output
MII Mode:
This pin is not used and is driven low.
71
VSS
Gnd
72
VSS
Gnd
73
RXD6
O
GMII Mode:
GMII GTX_CLK (Transmit Reference Clock) Input
Digital ground
GMII Mode:
GMII TX_EN (Transmit Enable) Input
MII Mode:
MII TX_EN (Transmit Enable) Input
Digital ground
Digital ground
GMII Mode:
GMII RXD6 (Receive Data 6) Output
MII Mode:
This pin is not used and is driven low.
74
DVDDL
P
1.2V digital VDD
75
DVDDL
P
1.2V digital VDD
76
RXD5
O
GMII Mode:
MII Mode:
This pin is not used and is driven low.
77
RXD4
O
GMII Mode:
GMII RXD4 (Receive Data 4) Output
MII Mode:
This pin is not used and is driven low.
September 2010
GMII RXD5 (Receive Data 5) Output
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Micrel, Inc.
KSZ9021GQ
Pin Number
Pin Name
78
RXD3 /
Type
(1)
I/O
MODE3
Pin Function
GMII Mode:
GMII RXD3 (Receive Data 3) Output
MII Mode:
MII RXD3 (Receive Data 3) Output /
Configuration Mode:
The pull-up/pull-down value is latched as MODE3
during power-up / reset. See “Strapping Options”
section for details.
79
VSSPST
Gnd
Digital ground
80
VSSPST
Gnd
Digital ground
81
DVDDH
P
3.3V or 2.5V digital VDD
82
DVDDH
P
3.3V or 2.5V digital VDD
83
RXD2 /
I/O
MODE2
84
GMII Mode:
GMII RXD2 (Receive Data 2) Output
MII Mode:
MII RXD2 (Receive Data 2) Output) /
Configuration Mode:
The pull-up/pull-down value is latched as MODE2
during power-up / reset. See “Strapping Options”
section for details.
VSS
Gnd
85
VSS
Gnd
86
DVDDL
P
1.2V digital VDD
87
DVDDL
P
1.2V digital VDD
88
RXD1 /
I/O
MODE1
89
RXD0 /
I/O
MODE0
90
RX_DV /
I/O
CLK125_EN
Digital ground
Digital ground
GMII Mode:
GMII RXD1 (Receive Data 1) Output
MII Mode:
MII RXD1 (Receive Data 1) Output /
Configuration Mode:
The pull-up/pull-down value is latched as MODE1
during power-up / reset. See “Strapping Options”
section for details.
GMII Mode:
GMII RXD0 (Receive Data 0) Output
MII Mode:
MII RXD0 (Receive Data 0) Output /
Configuration Mode:
The pull-up/pull-down value is latched as MODE0
during power-up / reset. See “Strapping Options”
section for details.
GMII Mode:
GMII RX_DV (Receive Data Valid) Output
MII Mode:
MII RX_DV (Receive Data Valid) Output /
Configuration Mode:
Latched as CLK125_NDO Output Enable during powerup / reset. See “Strapping Options” section for details.
91
VSSPST
Gnd
92
DVDDH
P
3.3V or 2.5V digital VDD
93
RX_ER
O
GMII Mode:
GMII RX_ER (Receive Error) Output
MII Mode:
MII RX_ER (Receive Error) Output
94
RX_CLK
O
GMII Mode:
GMII RX_CLK (Receive Reference Clock) Output
MII Mode:
MII RX_CLK (Receive Reference Clock) Output
95
VSSPST
Gnd
96
CRS
O
97
MDC
Ipu
Digital ground
Digital ground
GMII Mode:
GMII CRS (Carrier Sense) Output
MII Mode:
MII CRS (Carrier Sense) Output
Management Data Clock Input
This pin is the input reference clock for MDIO (pin 98).
98
MDIO
Ipu/O
Management Data Input / Output
This pin is synchronous to MDC (pin 97) and requires an external pull-up resistor
to DVDDH (digital VDD) in a range from 1.0KΩ to 4.7KΩ.
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Type
(1)
Pin Number
Pin Name
Pin Function
99
COL
O
100
DVDDH
P
3.3V or 2.5V digital VDD
101
INT_N
O
Interrupt Output
GMII Mode:
GMII COL (Collision Detected) Output
MII Mode:
MII COL (Collision Detected) Output
This pin provides a programmable interrupt output and requires an external pull-up
resistor to DVDDH (digital VDD) in a range from 1.0KΩ to 4.7KΩ when active low.
Register 1Bh is the Interrupt Control/Status Register for programming the interrupt
conditions and reading the interrupt status. Register 1Fh bit 14 sets the interrupt
output to active low (default) or active high.
102
VSS
Gnd
103
DVDDL
P
104
VSS
Gnd
105
DVDDL
P
Digital ground
1.2V digital VDD
Digital ground
1.2V digital VDD
106
DVDDH
P
3.3V or 2.5V digital VDD
107
CLK125_NDO
O
125MHz Clock Output
This pin provides a 125MHz reference clock output option for use by the MAC.
108
VSSPST
Gnd
Digital ground
109
VSSPST
Gnd
Digital ground
110
RESET_N
Ipu
Chip Reset (active low)
Hardware pin configurations are strapped-in at the de-assertion (rising edge) of
RESET_N. See “Strapping Options” section for more details.
111
NC
-
No connect
112
NC
-
No connect
113
VSS
Gnd
114
DVDDL
P
1.2V digital VDD
115
TX_CLK
O
MII Mode:
Factory test pin – float for normal operation
116
A1
I
117
AGNDH
Gnd
118
LDO_O
O
Digital ground
MII TX_CLK (Transmit Reference Clock) Output
Analog ground
On-chip 1.2V LDO Controller Output
This pin drives the input gate of a P-channel MOSFET to generate 1.2V for the
chip’s core voltages. If 1.2V is provided by the system and this pin is not used, it
can be left floating.
119
AGNDL_PLL
Gnd
120
AVDDL_PLL
P
Analog ground
1.2V analog VDD for PLL
121
AVDDL_PLL
P
1.2V analog VDD for VCO
122
AVDDH
P
3.3V analog VDD
123
XO
O
25MHz Crystal feedback
This pin is a no connect if oscillator or external clock source is used.
124
XI
I
Crystal / Oscillator / External Clock Input
25MHz +/-50ppm tolerance
125
AVDDH
P
126
ISET
I/O
3.3V analog VDD
Set transmit output level
Connect a 4.99KΩ 1% resistor to ground on this pin
127
AGNDH_BG
Gnd
128
AVDDH
P
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Analog ground
3.3V analog VDD
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Note:
1.
P = Power supply.
Gnd = Ground.
I = Input.
O = Output.
I/O = Bi-directional.
Ipu = Input with internal pull-up.
Ipu/O = Input with internal pull-up / Output.
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KSZ9021GQ
Strapping Options
(1)
Pin Function
Pin Number
Pin Name
Type
42
PHYAD4
I/O
43
PHYAD3
I/O
44
PHYAD2
I/O
Pull-up = 1
45
PHYAD1
I/O
Pull-down = 0
48
PHYAD0
I/O
78
MODE3
I/O
83
MODE2
I/O
88
MODE1
I/O
89
MODE0
I/O
90
CLK125_EN
I/O
The PHY Address, PHYAD[4:0], is latched at power-up / reset and is configurable to
any value from 1 to 31. Each PHY address bit is configured as follows:
The MODE[3:0] strap-in pins are latched at power-up / reset and are defined as
follows:
MODE[3:0]
Mode
0000
Reserved – not used
0001
GMII / MII Mode
0010
Reserved – not used
0011
Reserved – not used
0100
NAND Tree Mode
0101
Reserved – not used
0110
Reserved – not used
0111
Chip Power Down Mode
1000
Reserved – not used
1001
Reserved – not used
1010
Reserved – not used
1011
Reserved – not used
1100
Reserved – not used
1101
Reserved – not used
1110
Reserved – not used
1111
Reserved – not used
CLK125_EN is latched at power-up / reset and is defined as follows:
Pull-up = Enable 125MHz Clock Output
Pull-down = Disable 125MHz Clock Output
Pin 107 (CLK125_NDO) provides the 125MHz reference clock output option for use
by the MAC.
Notes:
1. I/O = Bi-directional.
2. Pin strap-ins are latched during power-up or reset. In some systems, the MAC receive input pins may be driven during power-up or reset,
and consequently cause the PHY strap-in pins on the GMII/MII signals to be latched to the incorrect configuration. In this case, it is
recommended to add external pull-ups/pull-downs on the PHY strap-in pins to ensure the PHY is configured to the correct pin strap-in mode.
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KSZ9021GQ
Functional Overview
The KSZ9021GQ is a completely integrated triple speed (10Base-T/100Base-TX/1000Base-T) Ethernet Physical Layer
Transceiver solution for transmission and reception of data over a standard CAT-5 unshielded twisted pair (UTP) cable.
Its on-chip proprietary 1000Base-T transceiver and Manchester/MLT-3 signaling-based 10Base-T/100Base-TX
transceivers are all IEEE 802.3 compliant.
The KSZ9021GQ reduces board cost and simplifies board layout by using on-chip termination resistors for the four
differential pairs and by integrating a LDO controller to drive a low cost MOSFET to supply the 1.2V core.
On the copper media interface, the KSZ9021GQ can automatically detect and correct for differential pair misplacements
and polarity reversals, and correct propagation delays and re-sync timing between the four differential pairs, as specified
in the IEEE 802.3 standard for 1000Base-T operation.
The KSZ9021GQ provides the GMII/MII interface for a direct and seamless connection to GMACs in Gigabit Ethernet
Processors and Switches for data transfer at 10/100/1000 Mbps speed.
The following figure shows a high-level block diagram of the KSZ9021GQ.
Figure 1. KSZ9021GQ Block Diagram
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Functional Description: 10Base-T/100Base-TX Transceiver
100Base-TX Transmit
The 100Base-TX transmit function performs parallel to serial conversion, 4B/5B coding, scrambling, NRZ-to-NRZI
conversion, and MLT-3 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, followed by a scrambler. The serialized data is
further converted from NRZ-to-NRZI format, and then transmitted in MLT-3 current output. The output current is set by an
external 4.99KΩ 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, MLT-3-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 MLT-3 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 GMII/MII format and provided as the input data to the MAC.
Scrambler/De-scrambler (100Base-TX only)
The purpose of the scrambler is to spread the power spectrum of the signal to reduce electromagnetic interference (EMI)
and baseline wander. Transmitted data is scrambled through the use of an 11-bit wide linear feedback shift register
(LFSR). The scrambler generates a 2047-bit non-repetitive sequence, and the receiver then de-scrambles the incoming
data stream using the same sequence as at the transmitter.
10Base-T Transmit
The output 10Base-T driver is incorporated into the 100Base-TX driver to allow transmission with the same magnetic.
They are internally wave-shaped and pre-emphasized into typical outputs of 2.5V amplitude. The harmonic contents are
at least 31 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 phase-locked loop (PLL) perform 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 receive inputs from falsely triggering the decoder. When the input exceeds the squelch limit, the PLL
locks onto the incoming signal and the KSZ9021GQ decodes a data frame. The receiver clock is maintained active during
idle periods in between receiving data frames.
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KSZ9021GQ
Functional Description: 1000Base-T Transceiver
The 1000Base-T transceiver is based-on a mixed-signal / digital signal processing (DSP) architecture, which includes the
analog front-end, digital channel equalizers, trellis encoders/decoders, echo cancellers, cross-talk cancellers, precision
clock recovery scheme, and power efficient line drivers.
The following figure shows a high-level block diagram of a single channel of the 1000Base-T transceiver for one of the
four differential pairs.
XTAL
OTHER
CHANNELS
CLOCK
GENERATION
TX
SIGNAL
SIDE-STREAM
SCRAMBLER
&
SYMBOL ENCODER
TRANSMIT
BLOCK
PCS STATE
MACHINES
NEXT
CANCELLER
NEXT
Canceller
NEXT Canceller
ECHO
CANCELLER
ANALOG
HYBRID
BASELINE
WANDER
COMPENSATION
AGC
RXADC
+
LED DRIVER
PAIR SWAP
&
ALIGN UNIT DESCRAMBLER
+
DECODER
FFE
SLICER
RX
SIGNAL
CLOCK & PHASE
RECOVERY
AUTONEGOTIATION
MII
REGISTERS
DFE
MII
MANAGEMENT
CONTROL
PMA STATE
MACHINES
Figure 2. KSZ9021GQ 1000Base-T Block Diagram – Single Channel
Analog Echo Cancellation Circuit
In 1000Base-T mode, the analog echo cancellation circuit helps to reduce the near-end echo. This analog hybrid circuit
relieves the burden of the ADC and the adaptive equalizer.
This circuit is disabled in 10Base-T/100Base-TX mode.
Automatic Gain Control (AGC)
In 1000Base-T mode, the automatic gain control (AGC) circuit provides initial gain adjustment to boost up the signal level.
This pre-conditioning circuit is used to improve the signal-to-noise ratio of the receive signal.
Analog-to-Digital Converter (ADC)
In 1000Base-T mode, the analog-to-digital converter (ADC) digitizes the incoming signal. ADC performance is essential to
the overall performance of the transceiver.
This circuit is disabled in 10Base-T/100Base-TX mode.
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Timing Recovery Circuit
In 1000Base-T mode, the mixed-signal clock recovery circuit together with the digital phase locked loop is used to recover
and track the incoming timing information from the received data. The digital phase locked loop has very low long-term
jitter to maximize the signal-to-noise ratio of the receive signal.
The 1000Base-T slave PHY is required to transmit the exact receive clock frequency recovered from the received data
back to the 1000Base-T master PHY. Otherwise, the master and slave will not be synchronized after long transmission.
Additionally, this helps to facilitate echo cancellation and NEXT removal.
Adaptive Equalizer
In 1000Base-T mode, the adaptive equalizer provides the following functions:
•
Detection for partial response signaling
•
Removal of NEXT and ECHO noise
• Channel equalization
Signal quality is degraded by residual echo that is not removed by the analog hybrid and echo due to impedance
mismatch. The KSZ9021GQ employs a digital echo canceller to further reduce echo components on the receive signal.
In 1000Base-T mode, data transmission and reception occurs simultaneously on all four pairs of wires (four channels).
This results in high frequency cross-talk coming from adjacent wires. The KSZ9021GQ employs three NEXT cancellers on
each receive channel to minimize the cross-talk induced by the other three channels.
In 10Base-T/100Base-TX mode, the adaptive equalizer needs only to remove the inter-symbol interference and recover
the channel loss from the incoming data.
Trellis Encoder and Decoder
In 1000Base-T mode, the transmitted 8-bit data is scrambled into 9-bit symbols and further encoded into 4D-PAM5
symbols. The initial scrambler seed is determined by the specific PHY address to reduce EMI when more than one
KSZ9021GQ are used on the same board. On the receiving side, the idle stream is examined first. The scrambler seed,
pair skew, pair order and polarity have to be resolved through the logic. The incoming 4D-PAM5 data is then converted
into 9-bit symbols and then de-scrambled into 8-bit data.
Functional Description: Additional 10/100/1000 PHY Features
Auto MDI/MDI-X
The Automatic MDI/MDI-X feature eliminates the need to determine whether to use a straight cable or a crossover cable
between the KSZ9021GQ and its link partner. This auto-sense function detects the MDI/MDI-X pair mapping from the link
partner, and then assigns the MDI/MDI-X pair mapping of the KSZ9021GQ accordingly.
The following table shows the KSZ9021GQ 10/100/1000 pin-out assignments for MDI/MDI-X pin mapping.
Pin (RJ-45 pair)
MDI
MDI-X
1000Base-T
100Base-TX
10Base-T
1000Base-T
100Base-TX
10Base-T
TXRXP/M_A (1,2)
A+/-
TX+/-
TX+/-
B+/-
RX+/-
RX+/-
TXRXP/M_B (3,6)
B+/-
RX+/-
RX+/-
A+/-
TX+/-
TX+/-
TXRXP/M_C (4,5)
C+/-
Not used
Not used
D+/-
Not used
Not used
TXRXP/M_D (7,8)
D+/-
Not used
Not used
C+/-
Not used
Not used
Table 1. MDI / MDI-X Pin Mapping
Auto MDI/MDI-X is enabled by default. It is disabled by writing a one to register 28 (1Ch) bit 6. MDI and MDI-X mode is
set by register 28 (1Ch) bit 7 if auto MDI/MDI-X is disabled.
An isolation transformer with symmetrical transmit and receive data paths is recommended to support auto MDI/MDI-X.
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Pair- Swap, Alignment, and Polarity Check
In 1000Base-T mode, the KSZ9021GQ
•
detects incorrect channel order and automatically restore the pair order for the A, B, C, D pairs (four channels)
•
supports 50+/-10ns difference in propagation delay between pairs of channels in accordance with the IEEE 802.3
standard, and automatically corrects the data skew so the corrected 4-pairs of data symbols are synchronized
Incorrect pair polarities of the differential signals are automatically corrected for all speeds.
Wave Shaping, Slew Rate Control and Partial Response
In communication systems, signal transmission encoding methods are used to provide the noise-shaping feature and to
minimize distortion and error in the transmission channel.
•
For 1000Base-T, a special partial response signaling method is used to provide the band-limiting feature for the
transmission path.
•
For 100Base-TX, a simple slew rate control method is used to minimize EMI.
•
For 10Base-T, pre-emphasis is used to extend the signal quality through the cable.
PLL Clock Synthesizer
The KSZ9021GQ generates 125 MΗz, 25 MΗz and 10 MΗz clocks for system timing. Internal clocks are generated from
the external 25 MHz crystal or reference clock.
Auto-Negotiation
The KSZ9021GQ 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 1: 1000Base-T, full-duplex
•
Priority 2: 1000Base-T, half-duplex
•
Priority 3: 100Base-TX, full-duplex
•
Priority 4: 100Base-TX, half-duplex
•
Priority 5: 10Base-T, full-duplex
•
Priority 6: 10Base-T, half-duplex
If auto-negotiation is not supported or the KSZ9021GQ link partner is forced to bypass auto-negotiation for 10Base-T and
100Base-TX modes, then the KSZ9021GQ sets its operating mode by observing the input signal at its receiver. This is
known as parallel detection, and allows the KSZ9021GQ to establish link by listening for a fixed signal protocol in the
absence of auto-negotiation advertisement protocol.
The auto-negotiation link up process is shown in the following flow chart.
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Figure 3. Auto-Negotiation Flow Chart
For 1000Base-T mode, auto-negotiation is required and always used to establish a link. During 1000Base-T autonegotiation, the Master and Slave configuration is first resolved between link partners, and then the link is established with
the highest common capabilities between link partners.
Auto-negotiation is enabled by default at power-up or after hardware reset. Afterwards, auto-negotiation can be enabled
or disabled through register 0 bit 12. If auto-negotiation is disabled, the speed is set by register 0 bits 6 and 13, and the
duplex is set by register 0 bit 8.
If the speed is changed on the fly, the link goes down and either auto-negotiation or parallel detection will initiate until a
common speed between KSZ9021GQ and its link partner is re-established for a link.
If link is already established and there is no change of speed on the fly, then the changes will not take effect unless either
auto-negotiation is restarted through register 0 bit 9, or a link down to link up transition occurs (i.e., disconnecting and
reconnecting the cable).
After auto-negotiation is completed, the link status is updated in register 1 and the link partner capabilities are updated in
registers 5, 6, and 10.
The auto-negotiation finite state machines employ interval timers to manage the auto-negotiation process. The duration of
these timers under normal operating conditions are summarized in the following table.
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KSZ9021GQ
Auto-Negotiation Interval Timers
Time Duration
Transmit Burst interval
16 ms
Transmit Pulse interval
68 us
FLP detect minimum time
17.2 us
FLP detect maximum time
185 us
Receive minimum Burst interval
6.8 ms
Receive maximum Burst interval
112 ms
Data detect minimum interval
35.4 us
Data detect maximum interval
95 us
NLP test minimum interval
4.5 ms
NLP test maximum interval
30 ms
Link Loss time
52 ms
Break Link time
1480 ms
Parallel Detection wait time
830 ms
Link Enable wait time
1000 ms
Table 2. Auto-Negotiation Timers
GMII Interface
The Gigabit Media Independent Interface (GMII) is compliant to the IEEE 802.3 Specification. It provides a common
interface between GMII PHYs and MACs, and has the following key characteristics:
•
Pin count is 24 pins (11 pins for data transmission, 11 pins for data reception, and 2 pins for carrier and collision
indication).
•
1000Mbps is 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 8-bit wide, a byte.
In GMII operation, the GMII pins function as follow:
•
The MAC sources the transmit reference clock, GTX_CLK, at 125MHz for 1000Mbps.
•
The PHY recovers and sources the receive reference clock, RX_CLK, at 125MHz for 1000Mbps.
•
TX_EN, TXD[7:0] and TX_ER are sampled by the KSZ9021GQ on the rising edge of GTX_CLK.
•
RX_DV, RXD[7:0], and RX_ER are sampled by the MAC on the rising edge of RX_CLK.
•
CRS and COL are driven by the KSZ9021GQ and are not required to transition synchronously with respect to
either GTX_CLK or RX_CLK.
The KSZ9021GQ combines GMII mode with MII mode to form GMII/MII mode to support data transfer at 10/100/1000
Mbps speed. After power-up or reset, the KSZ9021GQ is configured to GMII/MII mode if the MODE[3:0] strap-in pins are
set to 0001. See Strapping Options section.
The KSZ9021GQ has the option to output a low jitter 125MHz reference clock on CLK125_NDO (pin 107). This clock
provides a lower cost reference clock alternative for GMII/MII MACs that require a 125MHz crystal or oscillator. The
125MHz clock output is enabled after power-up or reset if the CLK125_EN strap-in pin is pulled high.
The KSZ9021GQ provides a dedicated transmit clock input pin for GMII mode, defined as follow:
•
GTX_CLK (input, pin 65):
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KSZ9021GQ
GMII Signal Definition
The following table describes the GMII signals. Refer to Clause 35 of the IEEE 802.3 Specification for more detailed
information.
GMII
Signal Name
GMII
Signal Name
(per spec)
(per KSZ9021GQ)
Pin Type
(with respect
to PHY)
Pin Type
(with respect
to MAC)
GTX_CLK
GTX_CLK
Input
Output
Transmit Reference Clock
(125MHz for 1000Mbps)
TX_EN
TX_EN
Input
Output
Transmit Enable
TXD[7:0]
TXD[7:0]
Input
Output
Transmit Data [7:0]
TX_ER
TX_ER
Input
Output
Transmit Error
RX_CLK
RX_CLK
Output
Input
Description
Receive Reference Clock
(125MHz for 1000Mbps)
RX_DV
RX_DV
Output
Input
Receive Data Valid
RXD[7:0]
RXD[7:0]
Output
Input
Receive Data [7:0]
RX_ER
RX_ER
Output
Input
Receive Error
CRS
CRS
Output
Input
Carrier Sense
COL
COL
Output
Input
Collision Detected
Table 3. GMII Signal Definition
GMII Signal Diagram
The KSZ9021GQ GMII pin connections to the MAC are shown in the following figure.
Figure 4. KSZ9021GQ GMII Interface
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KSZ9021GQ
MII 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 16 pins (7 pins for data transmission, 7 pins for data reception, and 2 pins for carrier and collision
indication).
•
10Mbps and 100Mbps 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.
In MII operation, the MII pins function as follow:
•
The PHY sources the transmit reference clock, TX_CLK, at 25MHz for 100Mbps and 2.5MHz for 10Mbps.
•
The PHY recovers and sources the receive reference clock, RX_CLK, at 25MHz for 100Mbps and 2.5MHz for
10Mbps.
•
TX_EN, TXD[3:0] and TX_ER are driven by the MAC and shall transition synchronously with respect to TX_CLK.
•
RX_DV, RXD[3:0], and RX_ER are driven by the KSZ9021GQ and shall transition synchronously with respect to
RX_CLK.
•
CRS and COL are driven by the KSZ9021GQ and are not required to transition synchronously with respect to
either TX_CLK or RX_CLK.
The KSZ9021GQ combines GMII mode with MII mode to form GMII/MII mode to support data transfer at 10/100/1000
Mbps speed. After the power-up or reset, the KSZ9021GQ is then configured to GMII/MII mode if the MODE[3:0] strap-in
pins are set to 0001. See Strapping Options section.
The KSZ9021GQ has the option to output a low jitter 125MHz reference clock on CLK125_NDO (pin 107). This clock
provides a lower cost reference clock alternative for GMII/MII MACs that require a 125MHz crystal or oscillator. The
125MHz clock output is enabled after power-up or reset if the CLK125_EN strap-in pin is pulled high.
The KSZ9021GQ provides a dedicated transmit clock output pin for MII mode, defined as follow:
•
TX_CLK (output, pin 115)
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KSZ9021GQ
MII Signal Definition
The following table describes the MII signals. Refer to Clause 22 of the IEEE 802.3 Specification for detailed information.
MII
Signal Name
MII
Signal Name
(per spec)
(per KSZ9021GQ)
Pin Type
(with respect
to PHY)
Pin Type
(with respect
to MAC)
TX_CLK
TX_CLK
Output
Input
Transmit Reference Clock
(25MHz for 100Mbps, 2.5MHz for
10Mbps)
TX_EN
TX_EN
Input
Output
Transmit Enable
TXD[3:0]
TXD[3:0]
Input
Output
Transmit Data [3:0]
TX_ER
TX_ER
Input
Output
Transmit Error
RX_CLK
RX_CLK
Output
Input
Receive Reference Clock
Description
(25MHz for 100Mbps, 2.5MHz for
10Mbps)
RX_DV
RX_DV
Output
Input
Receive Data Valid
RXD[3:0]
RXD[3:0]
Output
Input
Receive Data [3:0]
RX_ER
RX_ER
Output
Input
Receive Error
CRS
CRS
Output
Input
Carrier Sense
COL
COL
Output
Input
Collision Detected
Table 4. MII Signal Definition
MII Signal Diagram
The KSZ9021GQ MII pin connections to the MAC are shown in the following figure.
Figure 5. KSZ9021GQ MII Interface
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KSZ9021GQ
MII Management (MIIM) Interface
The KSZ9021GQ 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 KSZ9021GQ. An
external device with MIIM capability is used to read the PHY status and/or configure the PHY settings. Further detail on
the MIIM interface can be found in Clause 22.2.4.5 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 an external controller
to communicate with one or more KSZ9021GQ device. Each KSZ9021GQ device is assigned a PHY address
between 1 and 31 by the PHYAD[4:0] strapping pins.
•
A 32 register address space to access the KSZ9021GQ IEEE Defined Registers, Vendor Specific Registers and
Extended Registers. See Register Map section.
The following table shows the MII Management frame format for the KSZ9021GQ.
Preamble
Start of
Frame
Read/Write
PHY
REG
OP Code
Address
Address
TA
Data
Idle
Bits [15:0]
Bits [4:0]
Bits [4:0]
Read
32 1’s
01
10
AAAAA
RRRRR
Z0
DDDDDDDD_DDDDDDDD
Z
Write
32 1’s
01
01
AAAAA
RRRRR
10
DDDDDDDD_DDDDDDDD
Z
Table 5. MII Management Frame Format – for KSZ9021GQ
Interrupt (INT_N)
INT_N (pin 101) is an optional interrupt signal that is used to inform the external controller that there has been a status
update in the KSZ9021GQ PHY register. Bits [15:8] of register 27 (1Bh) are the interrupt control bits to enable and disable
the conditions for asserting the INT_N signal. Bits [7:0] of register 27 (1Bh) are the interrupt status bits to indicate which
interrupt conditions have occurred. The interrupt status bits are cleared after reading register 27 (1Bh).
Bit 14 of register 31 (1Fh) 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 KSZ9021GQ control and status
registers. Additionally, an interrupt pin eliminates the need for the processor to poll the PHY for status change.
LED Mode
The KSZ9021GQ provides six programmable LED output pins (LED1 thru LED6) that are configurable to support three
LED modes. Bits [7:6] of register 17 (11h) are the LED Mode Select [1:0] bits, and are defined as follow:
•
00 = Reserved – not used
•
10 = 4-LED Configuration
•
01 = 5-LED Configuration
•
11 = 6-LED Configuration (default setting after power-up / reset)
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4-LED Configuration
In this LED mode, the link and activity are combined into one LED for each speed. The unused pins LED2 and LED1 are
internally pulled high.
LED pin
Pin State
LED
Definition
Description
LED6
H
OFF
10Base-T, Link off
LED5
LED4
LED3
L
ON
10Base-T, Link on
Toggle
Blinking
10Base-T, Activity
H
OFF
100Base-TX, Link off
L
ON
100Base-TX, Link on
Toggle
Blinking
100Base-TX, Activity
H
OFF
1000Base-T, Link off
L
ON
1000Base-T, Link on
Toggle
Blinking
1000Base-T, Activity
H
OFF
Half-duplex
L
ON
Full-duplex
Toggle
Blinking
Collision
Table 6. 4-LED Configuration – Pin Definition
5-LED Configuration
In this LED mode, the transmit and receive activities are combined into pin LED1. The unused pin LED2 is internally
pulled high.
LED pin
Pin State
LED
Definition
Description
LED6
H
OFF
10Base-T, Link off
L
ON
10Base-T, Link on
H
OFF
100Base-TX, Link off
L
ON
100Base-TX, Link on
H
OFF
1000Base-T, Link off
L
ON
1000Base-T, Link on
LED5
LED4
LED3
LED1
H
OFF
Half-duplex
L
ON
Full-duplex
Toggle
Blinking
Collision
H
OFF
No Activity
L
ON
Toggle
Blinking
Transmit or Receive Activity
Table 7. 5-LED Configuration – Pin Definition
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6-LED Configuration
In this LED mode, all six LED pins are used. Pins LED2 and LED1 are dedicated for receive activity and transmit activity,
respectively, for all speeds.
LED pin
Pin State
LED
Definition
Description
LED6
H
OFF
10Base-T, Link off
L
ON
10Base-T, Link on
H
OFF
100Base-TX, Link off
L
ON
100Base-TX, Link on
LED5
LED4
LED3
LED2
LED1
H
OFF
1000Base-T, Link off
L
ON
1000Base-T, Link on
H
OFF
Half-duplex
L
ON
Full-duplex
Toggle
Blinking
Collision
H
OFF
No Receive Activity
L
ON
Toggle
Blinking
H
OFF
L
ON
Toggle
Blinking
Receive Activity
No Transmit Activity
Transmit Activity
Table 8. 6-LED Configuration – Pin Definition
Each LED output pin can directly drive a LED with a series resistor (typically 220Ω to 470Ω).
For activity indication, the LED output toggles at approximately 12.5Hz (80ms) to ensure visibility to the human eye.
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KSZ9021GQ
NAND Tree Support
The KSZ9021GQ provides parametric NAND tree support for fault detection between chip I/Os and board. The NAND tree
mode is enabled at power-up / reset with the MODE[3:0] strap-in pins set to 0100.
The following table lists the NAND tree pin order.
Pin
Description
LED6
Input
LED5
Input
LED4
Input
LED3
Input
LED2
Input
LED1
Input
TXD0
Input
TXD1
Input
TXD2
Input
TXD3
Input
TXD4
Input
TXD5
Input
TXD6
Input
TXD7
Input
TX_ER
Input
GTX_CLK
Input
TX_EN
Input
RXD7
Input
RXD6
Input
RXD5
Input
RXD4
Input
RX_DV
Input
RX_ER
Input
RX_CLK
Input
CRS
Input
COL
Input
INT_N
Input
MDC
Input
A1
Input
MDIO
Input
CLK125_NDO
Output
Table 9. NAND Tree Test Pin Order – for KSZ9021GQ
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Power Management
The KSZ9021GQ offers the following power management modes:
Power Saving Mode
This mode is a KSZ9021GQ green feature to reduce power consumption when the cable is unplugged. It is in effect when
auto-negotiation mode is enabled and the cable is disconnected (no link).
Software Power Down Mode
This mode is used to power down the KSZ9021GQ device when it is not in use after power-up. Power down mode is
enabled by writing a one to register 0h bit 11. In the power down state, the KSZ9021GQ disables all internal functions,
except for the MII management interface. The KSZ9021GQ exits power down mode after writing a zero to register 0h bit
11.
Chip Power Down Mode
This mode provides the lowest power state for the KSZ9021GQ when it is not in use and is mounted on the board. Chip
power down mode is enabled at power-up / reset with the MODE[3:0] strap-in pins set to 0111. The KSZ9021GQ exits
chip power down mode when a hardware reset is applied to RESET_N (pin 110) with the MODE[3:0] strap-in pins set to
an operating mode other than chip power down mode.
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Register Map
The IEEE 802.3 Specification provides a 32 register address space for the PHY. Registers 0 thru 15 are standard PHY
registers, defined per the specification. Registers 16 thru 31 are vendor specific registers.
The KSZ9021GQ uses the IEEE provided register space for IEEE Defined Registers and Vendor Specific Registers, and
uses the following registers to access Extended Registers:
•
Register 11 (Bh) for Extended Register – Control
•
Register 12 (Ch) for Extended Register – Data Write
•
Register 13 (Dh) for Extended Register – Data Read
Examples:
•
Extended Register Read
1. Write register 11 (Bh) with 0103h
2. Read register 13 (Dh)
// Read from Operation Mode Strap Status Register
// Set register 259 (103h) for read
// Read register value
•
Extended Register Write
1. Write register 11 (Bh) with 8102h
2. Write register 12 (Ch) with 0010h
// Write to Operation Mode Strap Override Register
// Set register 258 (102h) for write
// Write 0010h value to register to set NAND Tree mode
Register Number (Hex)
Description
IEEE Defined Registers
0 (0h)
Basic Control
1 (1h)
Basic Status
2 (2h)
PHY Identifier 1
3 (3h)
PHY Identifier 2
4 (4h)
Auto-Negotiation Advertisement
5 (5h)
Auto-Negotiation Link Partner Ability
6 (6h)
Auto-Negotiation Expansion
7 (7h)
Auto-Negotiation Next Page
8 (8h)
Auto-Negotiation Link Partner Next Page Ability
9 (9h)
1000Base-T Control
10 (Ah)
1000Base-T Status
11 (Bh)
Extended Register – Control
12 (Ch)
Extended Register – Data Write
13 (Dh)
Extended Register – Data Read
14 (Eh)
Reserved
15 (Fh)
Extended – MII Status
Vendor Specific Registers
16 (10h)
Reserved
17 (11h)
Remote Loopback, LED Mode
18 (12h)
LinkMD – Cable Diagnostic
19 (13h)
Digital PMA/PCS Status
20 (14h)
Reserved
21 (15h)
RXER Counter
22 (16h) – 26 (1Ah)
Reserved
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Register Number (Hex)
Description
27 (1Bh)
Interrupt Control/Status
28 (1Ch)
Digital Debug Control 1
29 (1Dh) – 30 (1Eh)
Reserved
31 (1Fh)
PHY Control
Extended Registers
257 (101h)
Strap Status
258 (102h)
Operation Mode Strap Override
259 (103h)
Operation Mode Strap Status
263 (107h)
Analog Test Register
Register Description
IEEE Defined Registers
Address
Name
(1)
Description
Mode
Default
1 = Software PHY reset
RW/SC
0
RW
0
RW
Hardware Setting
RW
1
RW
0
RW
0
RW/SC
0
RW
Hardware Setting
RW
0
Register 0 (0h) – Basic Control
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
0.13
Speed Select
(LSB)
[0.6, 0.13]
[1,1] = Reserved
[1,0] = 1000Mbps
[0,1] = 100Mbps
[0,0] = 10Mbps
This bit is ignored if auto-negotiation is enabled
(register 0.12 = 1)
0.12
0.11
AutoNegotiation
Enable
Power Down
1 = Enable auto-negotiation process
0 = Disable auto-negotiation process
If enabled, auto-negotiation result overrides
settings in register 0.13, 0.8 and 0.6
1 = Power down mode
0 = Normal operation
0.10
Isolate
1 = Electrical isolation of PHY from GMII/MII
0 = Normal operation
0.9
Restart AutoNegotiation
1 = Restart auto-negotiation process
0 = Normal operation
This bit is self-cleared after a ‘1’ is written to it
0.8
Duplex Mode
1 = Full-duplex
0 = Half-duplex
0.7
Collision Test
1 = Enable COL test
0 = Disable COL test
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(1)
Default
Address
Name
Description
Mode
0.6
Speed Select
(MSB)
[0.6, 0.13]
[1,1] = Reserved
[1,0] = 1000Mbps
[0,1] = 100Mbps
[0,0] = 10Mbps
This bit is ignored if auto-negotiation is enabled
(register 0.12 = 1)
RW
0
0.5:0
Reserved
RO
00_0000
RO
0
RO
1
RO
1
RO
1
RO
1
RO
00
RO
1
RO
0
RO
1
RO
0
RO/LH
0
RO
1
RO/LL
0
RO/LH
0
RO
1
RO
0022h
Register 1 (1h) – Basic Status
1.15
100Base-T4
1 = T4 capable
1.14
100Base-TX
Full Duplex
1 = Capable of 100Mbps full-duplex
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
0 = Not T4 capable
1.13
1.10:9
Reserved
1.8
Extended
Status
1.7
Reserved
1.6
No Preamble
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 = Extended Status Information in Reg. 15
0 = No Extended Status Information in Reg. 15
1 = Preamble suppression
0 = Normal preamble
1.5
1.4
AutoNegotiation
Complete
1 = Auto-negotiation process completed
Remote Fault
1 = Remote fault
0 = Auto-negotiation process not completed
0 = No remote fault
1.3
1.2
AutoNegotiation
Ability
Link Status
1 = Capable to perform auto-negotiation
0 = Not capable to perform auto-negotiation
1 = Link is up
0 = Link is down
1.1
Jabber Detect
1.0
Extended
Capability
1 = Jabber detected
0 = Jabber not detected (default is low)
1 = Supports extended capabilities registers
Register 2 (2h) – PHY Identifier 1
2.15:0
PHY ID
Number
Assigned to the 3rd through 18th bits of the
Organizationally Unique Identifier (OUI)
Kendin Communication’s OUI is 0010A1 (hex)
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Address
KSZ9021GQ
Name
Description
Mode
(1)
Default
Register 3 (3h) – PHY Identifier 2
3.15:10
PHY ID
Number
th
Assigned to the 19th through 24 bits of the
Organizationally Unique Identifier (OUI)
RO
0001_01
Kendin Communication’s OUI is 0010A1 (hex)
3.9:4
Model Number
Six bit manufacturer’s model number
RO
10_0001
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
RW
1
RW
1
RW
1
RW
1
RW
0_0001
RO
0
RO
0
RO
0
RO
0
Register 4 (4h) – Auto-Negotiation Advertisement
4.15
Next Page
1 = Next page capable
0 = No next page capability
4.14
Reserved
4.13
Remote Fault
1 = Remote fault supported
0 = No remote fault
4.12
Reserved
4.11:10
Pause
[4.11, 4.10]
[0,0] = No PAUSE
[1,0] = Asymmetric PAUSE (link partner)
[0,1] = Symmetric PAUSE
[1,1] = Symmetric & Asymmetric PAUSE
(local device)
4.9
100Base-T4
1 = T4 capable
0 = No T4 capability
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
10Base-T
Half-Duplex
1 = 10Mbps half-duplex capable
Selector Field
[00001] = IEEE 802.3
4.5
4.4:0
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 5 (5h) – Auto-Negotiation Link Partner Ability
5.15
Next Page
1 = Next page capable
0 = No next page capability
5.14
Acknowledge
1 = Link code word received from partner
0 = Link code word not yet received
5.13
Remote Fault
1 = Remote fault detected
0 = No remote fault
5.12
Reserved
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(1)
Default
Address
Name
Description
Mode
5.11:10
Pause
[5.11, 5.10]
RW
00
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0_0000
RO
0000_0000_000
RO/LH
0
RO
0
RO
1
RO/LH
0
RO
0
RW
0
RO
0
RW
1
RW
0
RO
0
RW
000_0000_0001
[0,0] = No PAUSE
[1,0] = Asymmetric PAUSE (link partner)
[0,1] = Symmetric PAUSE
[1,1] = Symmetric & Asymmetric PAUSE
(local device)
5.9
100Base-T4
1 = T4 capable
5.8
100Base-TX
Full-Duplex
1 = 100Mbps full-duplex capable
100Base-TX
Half-Duplex
1 = 100Mbps half-duplex capable
10Base-T
Full-Duplex
1 = 10Mbps full-duplex capable
10Base-T
Half-Duplex
1 = 10Mbps half-duplex capable
Selector Field
[00001] = IEEE 802.3
0 = No T4 capability
5.7
5.6
5.5
5.4:0
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 6 (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
Next Page
Able
1 = Local device has next page capability
6.3
6.2
6.1
Page Received
0 = No fault detected by parallel detection
0 = Link partner does not have next page
capability
0 = Local device does not have next page
capability
1 = New page received
0 = New page not received yet
6.0
Link Partner
AutoNegotiation
Able
1 = Link partner has auto-negotiation capability
0 = Link partner does not have auto-negotiation
capability
Register 7 (7h) – Auto-Negotiation Next Page
7.15
Next Page
1 = Additional next page(s) will follow
0 = Last page
7.14
Reserved
7.13
Message Page
1 = Message page
0 = Unformatted page
7.12
Acknowledge2
1 = Will comply with message
0 = Cannot comply with message
7.11
Toggle
1 = Previous value of the transmitted link code
word equaled logic one
0 = Logic zero
7.10:0
Message Field
September 2010
11-bit wide field to encode 2048 messages
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Address
KSZ9021GQ
Name
Description
Mode
(1)
Default
Register 8 (8h) – Auto-Negotiation Link Partner Next Page Ability
8.15
Next Page
1 = Additional Next Page(s) will follow
8.14
Acknowledge
1 = Successful receipt of link word
RO
0
RO
0
RO
0
RO
0
RO
0
RO
000_0000_0000
RW
000
RW
0
RW
0
0 = Last page
0 = No successful receipt of link word
8.13
Message Page
1 = Message page
0 = Unformatted page
8.12
Acknowledge2
1 = Able to act on the information
8.11
Toggle
1 = Previous value of transmitted link code
word equal to logic zero
0 = Not able to act on the information
0 = Previous value of transmitted link code
word equal to logic one
8.10:0
Message Field
Register 9 (9h) – 1000Base-T Control
9:15:13
Test Mode Bits
Transmitter test mode operations
[9.15:13]
9.12
9.11
Mode
[000]
Normal Operation
[001]
Test mode 1 –Transmit waveform
test
[010]
Test mode 2 –Transmit jitter test
in Master mode
[011]
Test mode 3 –Transmit jitter test
in Slave mode
[100]
Test mode 4 –Transmitter
distortion test
[101]
Reserved, operations not
identified
[110]
Reserved, operations not
identified
[111]
Reserved, operations not
identified
MASTERSLAVE
1 = Enable MASTER-SLAVE Manual
configuration value
Manual
Configuration
Enable
0 = Disable MASTER-SLAVE Manual
configuration value
MASTERSLAVE
1 = Configure PHY as MASTER during
MASTER-SLAVE negotiation
Manual
Configuration
Value
0 = Configure PHY as SLAVE during MASTERSLAVE negotiation
September 2010
This bit is ignored if MASTER-SLAVE Manual
Configuration is disabled (register 9.12 = 0)
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(1)
Default
Address
Name
Description
Mode
9.10
Port Type
1 = Indicate the preference to operate as
multiport device (MASTER)
RW
0
RW
1
RW
Hardware Setting
0 = Indicate the preference to operate as singleport device (SLAVE)
This bit is valid only if the MASTER-SLAVE
Manual Config Enable bit is disabled (register
9.12 = 0)
9.9
1000Base-T
Full-Duplex
1 = Advertise PHY is 1000Base-T full-duplex
capable
0 = Advertise PHY is not 1000Base-T fullduplex capable
9.8
1000Base-T
Half-Duplex
1 = Advertise PHY is 1000Base-T half-duplex
capable
0 = Advertise PHY is not 1000Base-T halfduplex capable
9.7:0
Reserved
Write as 0, ignore on read
RO
Register 10 (Ah) – 1000Base-T Status
10.15
10.14
10.13
10.12
10.11
MASTERSLAVE
1 = MASTER-SLAVE configuration fault
detected
configuration
fault
0 = No MASTER-SLAVE configuration fault
detected
MASTERSLAVE
1 = Local PHY configuration resolved to
MASTER
configuration
resolution
0 = Local PHY configuration resolved to
SLAVE
Local
Receiver
Status
1 = Local Receiver OK (loc_rcvr_status = 1)
Remote
Receiver
Status
1 = Remote Receiver OK (rem_rcvr_status = 1)
LP 1000T FD
1 = Link Partner is capable of 1000Base-T fullduplex
RO/LH/SC
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
00
RO/SC
0000_0000
RW
0
0 = Local Receiver not OK (loc_rcvr_status = 0)
0 = Remote Receiver not OK (rem_rcvr_status
= 0)
0 = Link Partner is not capable of 1000Base-T
full-duplex
10.10
LP 1000T HD
1 = Link Partner is capable of 1000Base-T halfduplex
0 = Link Partner is not capable of 1000Base-T
half-duplex
10.9:8
Reserved
10.7:0
Idle Error
Count
Cumulative count of errors detected when
receiver is receiving idles and
PMA_TXMODE.indicate = SEND_N
The counter is incremented every symbol
period that rxerror_status = ERROR
Register 11 (Bh) – Extended Register – Control
11.15
Extended
Register –
read/write
select
September 2010
1 = Write Extended Register
0 = Read Extended Register
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KSZ9021GQ
Address
Name
11.14:9
Reserved
11.8
Extended
Register –
page
11.7:0
Extended
Register –
address
Description
Mode
(1)
Default
RW
000_000
Select page for Extended Register
RW
0
Select Extended Register Address
RW
0000_0000
RW
0000_0000_0000_0000
RO
0000_0000_0000_0000
RO
0
RO
0
RO
1
RO
1
Ignore when read
RO
-
Description
Mode
Register 12 (Ch) – Extended Register – Data Write
12.15:0
Extended
Register –
write
16-bit value to write to Extend Register Address
in register 11 (Bh) bits [7:0]
Register 13 (Dh) – Extended Register – Data Read
13.15:0
Extended
Register –
read
16-bit value read from Extend Register Address
in register 11 (Bh) bits [7:0]
Register 15 (Fh) – Extended – MII Status
15.15
1000Base-X
Full-duplex
1 = PHY able to perform 1000Base-X
full-duplex
0 = PHY not able to perform 1000Base-X
full-duplex
15.14
1000Base-X
Half-duplex
1 = PHY able to perform 1000Base-X
half-duplex
0 = PHY not able to perform 1000Base-X
half-duplex
15.13
1000Base-T
Full-duplex
1 = PHY able to perform 1000Base-T
full-duplex 1000BASE-X
0 = PHY not able to perform 1000Base-T
full-duplex
15.12
1000Base-T
Half-duplex
1 = PHY able to perform 1000Base-T
half-duplex
0 = PHY not able to perform 1000Base-T
half-duplex
15.11:0
Reserved
Note:
1.
RW = Read/Write.
RO = Read only.
SC = Self-cleared.
LH = Latch high.
LL = Latch low.
Vendor Specific Registers
Address
Name
(1)
Default
Register 17 (11h) – Remote Loopback, LED Mode
17.15:9
Reserved
September 2010
RW
41
0000_001
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
(1)
Default
Address
Name
Description
Mode
17.8
Remote
Loopback
1 = Enable Remote Loopback
RW
0
LED Mode
Select
[17.7, 17.6]
RW
11
RW
11
RW
0
17.7:6
0 = Disable Remote Loopback
[0,0] = Reserved – not used
[1,0] = 4-LED Configuration
[0,1] = 5-LED Configuration
[1,1] = 6-LED Configuration
17.5:4
Reserved
17.3
LED Test
Enable
1 = Enable LED test mode
0 = Disable LED test mode
17.2:1
Reserved
RW
00
17.0
Reserved
RO
0
Reserved
RW/SC
0
18.14:8
Reserved
RW
000_0000
18.7:0
Reserved
RO
0000_0000
RO/LH
0000_0000_0000_0
RO
0
RO
0
RO
0
RO/RC
0000_0000_0000_0000
RW
0
RW
0
RW
0
RW
0
RW
0
®
Register 18 (12h) – LinkMD – Cable Diagnostic
18.15
Register 19 (13h) – Digital PMA/PCS Status
19.15:3
Reserved
19.2
1000Base-T
Link Status
1000 Base-T Link Status
1 = Link status is OK
0 = Link status is not OK
19.1
100Base-TX
Link Status
100 Base-TX Link Status
1 = Link status is OK
0 = Link status is not OK
19.0
Reserved
Register 21 (15h) – RXER Counter
21.15:0
RXER Counter
Receive error counter for Symbol Error frames
Register 27 (1Bh) – Interrupt Control/Status
27.15
27.14
27.13
27.12
27.11
Jabber
Interrupt
Enable
1 = Enable Jabber Interrupt
Receive Error
Interrupt
Enable
1 = Enable Receive Error Interrupt
Page Received
Interrupt
Enable
1 = Enable Page Received Interrupt
Parallel Detect
Fault Interrupt
Enable
1 = Enable Parallel Detect Fault Interrupt
Link Partner
Acknowledge
Interrupt
Enable
1 = Enable Link Partner Acknowledge Interrupt
September 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
42
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
(1)
Default
Address
Name
Description
Mode
27.10
Link Down
Interrupt
Enable
1 = Enable Link Down Interrupt
RW
0
Remote Fault
Interrupt
Enable
1 = Enable Remote Fault Interrupt
RW
0
Link Up
Interrupt
Enable
1 = Enable Link Up Interrupt
RW
0
Jabber
Interrupt
1 = Jabber occurred
RO/RC
0
Receive Error
Interrupt
1 = Receive Error occurred
RO/RC
0
27.5
Page Receive
Interrupt
1 = Page Receive occurred
RO/RC
0
27.4
Parallel Detect
Fault Interrupt
1 = Parallel Detect Fault occurred
RO/RC
0
Link Partner
Acknowledge
Interrupt
1 = Link Partner Acknowledge occurred
RO/RC
0
Link Down
Interrupt
1 = Link Down occurred
RO/RC
0
Remote Fault
Interrupt
1 = Remote Fault occurred
RO/RC
0
Link Up
Interrupt
1 = Link Up occurred
RO/RC
0
RW
0000_0000
RW
0
RW
0
RW
00_000
RW
0
RW
0
RW
0
27.9
27.8
27.7
27.6
27.3
27.2
27.1
27.0
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
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
Register 28 (1Ch) – Digital Debug Control 1
28.15:8
Reserved
28.7
mdi_set
mdi_set has no function when swapoff (reg28.6)
is de-asserted
1 = When swapoff is asserted, if mdi_set is
asserted, chip will operate at MDI mode
0 = When swapoff is asserted, if mdi_set is deasserted, chip will operate at MDI-X mode
28.6
swapoff
1 = Disable auto crossover function
0 = Enable auto crossover function
28.5:1
Reserved
28.0
PCS Loopback
1 = Enable 10Base-T and 100Base-TX
Loopback for register 0h bit 14
0 = normal function
Register 31 (1Fh) – PHY Control
31.15
Reserved
31.14
Interrupt Level
1 = Interrupt pin active high
0 = Interrupt pin active low
31.13:12
Reserved
RW
00
31.11:10
Reserved
RO/LH/RC
00
September 2010
43
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Address
Name
Description
Mode
31.9
Enable Jabber
1 = Enable jabber counter
RW
(1)
Default
1
0 = Disable jabber counter
31.8:7
Reserved
RW
00
31.6
Speed status
1000Base-T
1 = Indicate chip final speed status at
1000Base-T
RO
0
31.5
Speed status
100Base-TX
1 = Indicate chip final speed status at
100Base-TX
RO
0
31.4
Speed status
10Base-T
1 = Indicate chip final speed status at
10Base-T
RO
0
31.3
Duplex status
Indicate chip duplex status
RO
0
RO
0
RW
0
RO
0
1 = Full-duplex
0 = Half-duplex
31.2
1000Base-T
Mater/Slave
status
1 = Indicate 1000Base-T Master mode
31.1
Software
Reset
1 = Reset chip, except all registers
31.0
Link Status
Check Fail
1 = Fail
0 = Indicate 1000Base-T Slave mode
0 = Disable reset
0 = Not Failing
Note:
1.
RW = Read/Write.
RC = Read-cleared
RO = Read only.
SC = Self-cleared.
LH = Latch high.
Extended Registers
Address
Name
Description
Mode
(1)
Default
Register 257 (101h) – Strap Status
257.15:6
Reserved
257.5
CLK125_EN
status
1 = CLK125_EN strap-in is enabled
PHYAD[4:0]
status
Strapped-in value for PHY Address
257.4:0
RO
RO
0 = CLK125_EN strap-in is disabled
RO
Register 258 (102h) – Operation Mode Strap Override
258.15:8
Reserved
258.7
Tri-state all
digital I/Os
258.6:5
Reserved
258.4
NAND Tree
override
258.3:2
Reserved
258.1
GMII / MII
override
258.0
Reserved
September 2010
RW
1 = Tri-state all digital I/Os for further power
saving during software power down
RW
0
RW
1 = Override strap-in for NAND Tree mode
RW
RW
1 = Override strap-in for GMII / MII mode
RW
RW
44
M9999-091010-1.2
Micrel, Inc.
Address
KSZ9021GQ
Name
Description
Mode
(1)
Default
Register 259 (103h) – Operation Mode Strap Status
259.15:5
Reserved
259.4
NAND Tree
strap-in status
259.3:2
Reserved
259.1
GMII / MII
strap-in status
259.0
Reserved
RO
1 = Strap to NAND tree mode
RO
RO
1 = Strap to GMII / MII mode
RO
RO
Register 263 (107h) – Analog Test Register
LDO disable
263.15
1 = LDO controller disable
RW
0
RW
000_000
RW
0
RW
0000_0000
0 = LDO controller enable
263.14:9
Reserved
263.8
Low frequency
oscillator mode
1 = Low frequency oscillator mode enable
0 = Low frequency oscillator mode disable
Use for further power saving during software
power down
263.7:0
Reserved
Note:
1.
RW = Read/Write.
RO = Read only.
September 2010
45
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Absolute Maximum Ratings(1)
Operating Ratings(2)
Supply Voltage
(DVDDL, AVDDL, AVDDL_PLL).......-0.5V to Vdd+10%
(AVDDH) ...........................................-0.5V to Vdd+10%
(DVDDH)...........................................-0.5V to Vdd+10%
Input Voltage (all inputs) .........................-0.5V to Vdd+10%
Output Voltage (all outputs) ....................-0.5V to Vdd+10%
Lead Temperature (soldering, 10sec.) ....................... 260°C
Storage Temperature (Ts) ..........................-55°C to +150°C
Supply Voltage
(DVDDL, AVDDL, AVDDL_PLL).... +1.140V to +1.260V
(AVDDH)........................................ +3.135V to +3.465V
(DVDDH @ 3.3V) .......................... +3.135V to +3.465V
(DVDDH @ 2.5V) .......................... +2.375V to +2.625V
Ambient Temperature
(TA Commercial: KSZ9021GQ)................ 0°C to +70°C
(TA Industrial: KSZ9021GQI) ................-40°C to +85°C
Maximum Junction Temperature (TJ Max) ................. 125°C
Thermal Resistance (θJA) ....................................41.54°C/W
Thermal Resistance (θJC) ....................................19.78°C/W
Electrical Characteristics(3)
Symbol
Parameter
Condition
Min
Typ
Max
Units
Supply Current – Core / Digital I/Os
ICORE
IDVDDH_2.5
1.2V total of:
1000Base-T Link-up (no traffic)
522
mA
DVDDL (1.2V digital core) +
1000Base-T Full-duplex @ 100% utilization
555
mA
AVDDL (1.2V analog core) +
100Base-TX Link-up (no traffic)
159
mA
AVDDL_PLL (1.2V for PLL)
100Base-TX Full-duplex @ 100% utilization
160
mA
2.5V for digital I/Os
(GMII / MII operating @ 2.5V)
IDVDDH_3.3
3.3V for digital I/Os
(GMII / MII operating @ 3.3V)
September 2010
10Base-T Link-up (no traffic)
7
mA
10Base-T Full-duplex @ 100% utilization
7
mA
Power-saving Mode (cable un-plugged)
15
mA
Software Power Down Mode (register 0.11 =1)
1.3
mA
Chip Power Down Mode
(strap-in pins MODE[3:0] = 0111)
1.2
mA
1000Base-T Link-up (no traffic)
22
mA
1000Base-T Full-duplex @ 100% utilization
39
mA
100Base-TX Link-up (no traffic)
15
mA
100Base-TX Full-duplex @ 100% utilization
19
mA
10Base-T Link-up (no traffic)
10
mA
10Base-T Full-duplex @ 100% utilization
11
mA
Power-saving Mode (cable un-plugged)
14
mA
Software Power Down Mode (register 0.11 =1)
8
mA
Chip Power Down Mode
(strap-in pins MODE[3:0] = 0111)
1
mA
1000Base-T Link-up (no traffic)
32
mA
1000Base-T Full-duplex @ 100% utilization
57
mA
100Base-TX Link-up (no traffic)
19
mA
100Base-TX Full-duplex @ 100% utilization
25
mA
10Base-T Link-up (no traffic)
13
mA
10Base-T Full-duplex @ 100% utilization
17
mA
Power-saving Mode (cable un-plugged)
23
mA
Software Power Down Mode (register 0.11 =1)
16
mA
Chip Power Down Mode
(strap-in pins MODE[3:0] = 0111)
1
mA
46
M9999-091010-1.2
Micrel, Inc.
Symbol
KSZ9021GQ
Parameter
Condition
Min
Typ
Max
Units
Supply Current – Transceiver (equivalent to current draw through external transformer center taps for PHY transceivers
with current-mode transmit drivers)
IAVDDH
3.3V for transceiver
1000Base-T Link-up (no traffic)
74
mA
1000Base-T Full-duplex @ 100% utilization
73
mA
100Base-TX Link-up (no traffic)
28
mA
100Base-TX Full-duplex @ 100% utilization
28
mA
10Base-T Link-up (no traffic)
35
mA
10Base-T Full-duplex @ 100% utilization
43
mA
Power-saving Mode (cable un-plugged)
35
mA
Software Power Down Mode (register 0.11 =1)
2
mA
Chip Power Down Mode
(strap-in pins MODE[3:0] = 0111)
1
mA
CMOS Inputs
VIH
VIL
IIN
Input High Voltage
Input Low Voltage
Input Current
DVDDH = 3.3V
2.0
V
DVDDH = 2.5V
1.8
V
DVDDH = 3.3V
0.8
V
DVDDH = 2.5V
0.7
V
10
µA
VIN = GND ~ VDDIO
-10
CMOS Outputs
VOH
Output High Voltage
VOL
Output Low Voltage
|Ioz|
DVDDH = 3.3V
2.4
DVDDH = 2.5V
2.0
V
V
DVDDH = 3.3V
0.4
V
DVDDH = 2.5V
0.4
V
10
µA
Output Tri-State Leakage
LED Outputs
ILED
Output Drive Current
Each LED pin
8
mA
(LED1, LED2, LED3, LED4, LED5, LED6)
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
V
2
%
Rise/Fall Time
3
5
ns
Rise/Fall Time Imbalance
0
0.5
ns
± 0.25
ns
5
%
Duty Cycle Distortion
Overshoot
VSET
1.05
Reference Voltage of ISET
R(ISET) = 4.99K
Output Jitter
Peak-to-peak
0.535
0.7
V
1.4
ns
2.8
V
10Base-T Transmit (measured differentially after 1:1 transformer)
VP
Peak Differential Output Voltage
100Ω termination across differential output
Jitter Added
Peak-to-peak
Harmonic Rejection
Transmit all-one signal sequence
September 2010
2.2
3.5
47
-31
ns
dB
M9999-091010-1.2
Micrel, Inc.
Symbol
KSZ9021GQ
Parameter
Condition
Min
Typ
5MHz square wave
300
400
Max
Units
10Base-T Receive
VSQ
Squelch Threshold
mV
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.
September 2010
48
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Timing Diagrams
GMII Transmit Timing
Figure 6. GMII Transmit Timing – Data Input to PHY
Timing Parameter
Description
Min
Typ
Max
Unit
tcyc
GTX_CLK period
7.5
8.0
8.5
ns
tsu
TX_EN, TXD[7:0], TX_ER setup time to
rising edge of GTX_CLK
2.0
ns
thd
TX_EN, TXD[7:0], TX_ER hold time from
rising edge of GTX_CLK
0
ns
thi
GTX_CLK high pulse width
2.5
ns
tlo
GTX_CLK low pulse width
2.5
ns
tr
GTX_CLK rise time
1.0
ns
tf
GTX_CLK fall time
1.0
ns
1000Base-T
Table 10. GMII Transmit Timing Parameters
September 2010
49
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
GMII Receive Timing
Figure 7. GMII Receive Timing – Data Input to MAC
Timing Parameter
Description
Min
Typ
Max
Unit
tcyc
RX_CLK period
7.5
8.0
8.5
ns
tsu
RX_DV, RXD[7:0], RX_ER setup time to
rising edge of RX_CLK
2.5
ns
thd
RX_DV, RXD[7:0], RX_ER hold time from
rising edge of RX_CLK
0.5
ns
thi
RX_CLK high pulse width
2.5
ns
tlo
RX_CLK low pulse width
2.5
ns
tr
RX_CLK rise time
1.0
ns
tf
RX_CLK fall time
1.0
ns
1000Base-T
Table 11. GMII Receive Timing Parameters
September 2010
50
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
MII Transmit Timing
Figure 8. MII Transmit Timing – Data Input to PHY
Timing Parameter
Description
Min
Typ
Max
Unit
10Base-T
tcyc
TX_CLK period
400
ns
tsu
TX_EN, TXD[3:0], TX_ER setup time to
rising edge of TX_CLK
15
ns
thd
TX_EN, TXD[3:0], TX_ER hold time from
rising edge of TX_CLK
0
ns
thi
TX_CLK high pulse width
140
260
ns
tlo
TX_CLK low pulse width
140
260
ns
100Base-TX
tcyc
TX_CLK period
tsu
TX_EN, TXD[3:0], TX_ER setup time to
rising edge of TX_CLK
15
40
ns
ns
thd
TX_EN, TXD[3:0], TX_ER hold time from
rising edge of TX_CLK
0
ns
thi
TX_CLK high pulse width
14
26
ns
tlo
TX_CLK low pulse width
14
26
ns
Table 12. MII Transmit Timing Parameters
September 2010
51
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
MII Receive Timing
Figure 9. MII Receive Timing – Data Input to MAC
Timing Parameter
Description
Min
Typ
Max
Unit
10Base-T
tcyc
RX_CLK period
400
ns
tsu
RX_DV, RXD[3:0], RX_ER setup time to
rising edge of RX_CLK
10
ns
thd
RX_DV, RXD[3:0], RX_ER hold time from
rising edge of RX_CLK
10
ns
thi
RX_CLK high pulse width
140
260
ns
tlo
RX_CLK low pulse width
140
260
ns
100Base-TX
tcyc
RX_CLK period
tsu
RX_DV, RXD[3:0], RX_ER setup time to
rising edge of RX_CLK
10
40
ns
ns
thd
RX_DV, RXD[3:0], RX_ER hold time from
rising edge of RX_CLK
10
ns
thi
RX_CLK high pulse width
14
26
ns
tlo
RX_CLK low pulse width
14
26
ns
Table 13. MII Receive Timing Parameters
September 2010
52
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Auto-Negotiation Timing
A U TO -N E G O T IA T IO N
FA S T L IN K P U L S E (F L P ) T IM IN G
FLP
BURST
FLP
BURST
T X + /T X -
t F LP W
tB T B
CLOCK
PULSE
T X + /T X -
DATA
PULSE
tP W
CLO CK
PULSE
DATA
PULSE
tP W
tC T D
tC T C
Figure 10. Auto-Negotiation Fast Link Pulse (FLP) Timing
Timing Parameter
Description
Min
Typ
Max
Units
tBTB
FLP Burst to FLP Burst
8
16
24
ms
tFLPW
FLP Burst width
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 14. Auto-Negotiation Fast Link Pulse (FLP) Timing Parameters
September 2010
53
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
MDC/MDIO Timing
Figure 11. MDC/MDIO Timing
Timing Parameter
Description
Min
Typ
tP
MDC period
t1MD1
MDIO (PHY input) setup to rising edge of MDC
10
ns
tMD2
MDIO (PHY input) hold from rising edge of MDC
10
ns
tMD3
MDIO (PHY output) delay from rising edge of MDC
0
ns
400
Max
Unit
ns
Table 15. MDC/MDIO Timing Parameters
September 2010
54
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Reset Timing
The recommended KSZ9021GQ power-up reset timing is summarized in the following figure and table.
Figure 12. Reset Timing
Parameter
Description
Min
tsr
Stable supply voltage to reset high
10
Max
Units
ms
Table 16. 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.
Reset Circuit
The following reset circuit is recommended for powering up the KSZ9021GQ if reset is triggered by the power supply.
Figure 13. Recommended Reset Circuit
September 2010
55
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
The following reset circuit is 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 KSZ9021GQ device. The RST_OUT_N
from CPU/FPGA provides the warm reset after power up.
Figure 14. Recommended Reset Circuit for Interfacing with CPU/FPGA Reset Output
Reference Circuits – LED Strap-in Pins
The pull-up and pull-down reference circuits for the LED5/PHYAD4, LED4/PHYAD3, LED3/PHYAD2, LED2/PHYAD1 and
LED1/PHYAD0 strapping pins are shown in the following figure.
Figure 15. Reference Circuits for LED Strapping Pins
September 2010
56
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Reference Clock – Connection & Selection
A crystal or external clock source, such as an oscillator, is used to provide the reference clock for the KSZ9021GQ. The
reference clock is 25 MHz for all operating modes of the KSZ9021GQ.
The following figure and table shows the reference clock connection to XI (pin 124) and XO (pin 123) of the KSZ9021GQ,
and the reference clock selection criteria.
22pF
22pF
XI
22pF
22pF
XI
25MHz OSC
+/-50ppm
XO
NC
XO
NC
25MHz XTAL
+/-50ppm
Figure 16. 25MHz Crystal / Oscillator Reference Clock Connection
Characteristics
Value
Units
Frequency
25
MHz
Frequency tolerance (max)
±50
ppm
Table 17. Reference Crystal/Clock Selection Criteria
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.
The following tables provide recommended magnetic characteristics and a list of qualified magnetics for the KSZ9021GQ.
Parameter
Value
Test Condition
Turns ratio
1 CT : 1 CT
Open-circuit inductance (min.)
350μH
100mV, 100kHz, 8mA
Insertion loss (max.)
1.0dB
0MHz – 100MHz
HIPOT (min.)
1500Vrms
Table 18. Magnetics Selection Criteria
Magnetic Manufacturer
Part Number
Auto MDI-X
Number of Port
Pulse
H5007NL
Yes
1
TDK
TLA-7T101LF
Yes
1
Table 19. Qualified Single Port 10/100/1000 Magnetics
September 2010
57
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
Package Information
128-Pin (14mm x 20mm) PQFP (Q)
September 2010
58
M9999-091010-1.2
Micrel, Inc.
KSZ9021GQ
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
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September 2010
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M9999-091010-1.2