ks8999 data sheet rev 1.14

KS8999
Micrel
KS8999
Integrated 9-Port 10/100 Switch with PHY and Frame Buffer
Rev. 1.14
KS8999 is designed to reside in an unmanaged design not
requiring processor intervention. This is achieved through
I/O strapping or EEPROM programming at system reset
time.On the media side, the KS8999 supports 10BaseT,
100BaseTX and 100BaseFX as specified by the IEEE 802.3
committee. Physical signal transmission and reception are
enhanced through use of analog circuitry that makes the
design more efficient and allows for lower power consumption and smaller chip die size.
Data sheets and support documentation can be found on
Micrel’s web site at www.micrel.com.
General Description
The KS8999 contains eight 10/100 physical layer transceivers, nine MAC (Media Access Control) units with an integrated layer 2 switch. The device runs in two modes. The first
mode is an eight port integrated switch and the second is as
a nine port switch with the ninth port available through an MII
(Media Independent Interface). Useful configurations include
a stand alone eight port switch as well as a eight port switch
with a routing element connected to the extra MII port. The
additional port is also useful for a public network interfacing.The
Functional Diagram
Look Up
Engine
(1K Entries)
Queue Priority
Management
SRAM
Buffers
Buffer
Management
FIFO, Flow Control, VLAN and Priority
M
A
C
M
A
C
M
A
C
1
2
3
P
H
Y
P
H
Y
P
H
Y
1
2
3
M
A
C
M
A
C
M
A
C
M
A
C
M
A
C
M
A
C
4
5
6
7
8
9
P
H
Y
P
H
Y
P
H
Y
P
H
Y
P
H
Y
4
5
6
7
8
M
I
I
MII /
SNI
(exclusive)
External
Interface
EEPROM /
Processor
Interface
SCL
SDA
LED
and
Programming
Interface
LED[1][3:0]
LED[2][3:0]
LED[3][3:0]
LED[4][3:0]
LED[5][3:0]
LED[6][3:0]
LED[7][3:0]
LED[8][3:0]
LED[9][3:0]
MRXD[3:0]
MRXDV
MCOL
MCRS
MTXD[3:0]
MTXEN
MTXER
MTXC
MRXC
MRXD[0]
MRXDV
MCOL
S
N
I
MTXD[0]
MTXEN
MTXC
MRXC
Micrel, Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
January 2005
1
KS8999
KS8999
Micrel
Features
Ordering Information
• 9 port (8+1) 10/100 integrated switch with eight physical
layer transceivers and one MII/SNI interface
• Advanced Ethernet Switch with internal frame buffer
– 128K Byte of SRAM on chip for frame buffering
– 2.0Gbps high performance memory bandwidth
– Wire speed reception and transmission
– Integrated address look-up engine, supports 1K
absolute MAC addresses
– Automatic address learning, address aging and
address migration
• Advanced Switch Features
– Supports 802.1p priority and port based priority
– Supports port based VLAN
– Supports 1536 byte frame for VLAN tag
– Supports DiffServ priority, 802.1p based priority or
port based priorityo broadcast storm protection
• Proven transceiver technology for UTP and fiber
operation
– 10BaseT, 100BaseTX and 100BaseFX modes of
operation
– Supports for UTP or fiber on all 8-ports
– Indicators for link, activity, full/half-duplex and speed
– Hardware based 10/100, full/half, flow control and
auto-negotiation
– Individual port forced modes (full duplex, 100BaseTX)
when auto-negotiation is disabled
– Full duplex IEEE 802.3x flow control
– Half-duplex back pressure flow control
• Supports MDI/MDI-X auto crossover
• External MAC interface (MII or 7-wire) for router
applications
• Unmanaged operation via strapping or EEPROM at
system reset time (see Reset Reference Circuit section)
• Comprehensive LED support
• Single 2.0V power supply with options for 2.5V and
3.3V I/O
• 900 mA (1.80W) including physical transmit drivers
• Supports both commercial and industry temperature
– Commercial temperature range: 0°C to +70°C
(KS8999)
– Industrial temperature range: –40°C to +85°C
(KS8999I)
• Supports lead free products:
– Commercial temperature range: 0°C to +70°C
(KSZ8999)
– Industrial temperature range: –40°C to +85°C
(KSZ8999I)
• Available in 208-pin PQFP package
KS8999
Part Number
2
Temperature Range
Package
KS8999
0°C to +70°C
208-Pin PQFP
KS8999I
–40°C to +85°C
208-Pin PQFP
KSZ8999
0°C to +70°C
208-Pin PQFP
KSZ8999I
–40°C to +85°C
208-Pin PQFP
January 2005
KS8999
Micrel
Revision History
Revision
Date
Summary of Changes
1.00
11/27/00
Preliminary Release
1.01
03/30/01
Update maximum frame size
Update EEPROM priority descriptions
Update I/O pin definitionUpdate I/O descriptions
Update Electrical Characteristics
1.02
04/20/01
Correct timing information
1.03
05/11/01
Add MDI/MDI-X description
1.04
06/22/01
Change electrical requirements
1.05
0/6/25/01
Correct I/O descriptions
1.06
07/25/01
Update PLL clock information
Update timing information
1.07
08/09/01
Correct LED[6][1:0] to float configuration
Add reverse and forward timing
Correct optional CPU timing
1.08
1/14/02
Update Optional CPU interface
Correct I/O description for MCOL and MCRS
Correct pin 174 and 175 description
1.09
6/18/02
Correct default to floating for pin 174
Change pin 87 TEST[3] to AUTOMDIX for enable/disable of auto MDI-MDIX function
1.10
2/27/03
Add KS8999I industrial temperature
Update non-periodic blinking in Mode 1 of LED[1:9][0]
Add MRXD[0] description
1.11
5/12/03
Changed Vcc from 2.00 to 2.10 (typical) Added FEF disable to T[4] pin #173
1.12
8/29/03
Convert to new format.
1.13
1/19/05
Correct pin type description. Correct selection of reference oscillator/crystal spec. Insert recommended
reset circuit.
1.14
1/31/05
Added lead free and Industrial temperature packages.
January 2005
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KS8999
KS8999
Micrel
Table of Contents
System Level Applications ......................................................................................................................................... 6
Pin Description ............................................................................................................................................................ 7
I/O Grouping ........................................................................................................................................................... 13
I/O Descriptions ......................................................................................................................................................... 13
Pin Configuration ...................................................................................................................................................... 19
Functional Overview: Physical Layer Transceiver ................................................................................................ 20
100BaseTX Transmit ........................................................................................................................................... 20
100BaseTX Receive ............................................................................................................................................ 20
PLL Clock Synthesizer ......................................................................................................................................... 20
Scrambler/De-scrambler (100BaseTX only) ........................................................................................................ 20
100BaseFX Operation ......................................................................................................................................... 20
100BaseFX Signal Detection ............................................................................................................................... 20
100BaseFX Far End Fault ................................................................................................................................... 20
10BaseT Transmit ............................................................................................................................................... 20
10BaseT Receive ................................................................................................................................................ 20
Power Management ............................................................................................................................................. 21
Power Save Mode ........................................................................................................................................ 21
MDI/MDI-X Auto Crossover ................................................................................................................................. 21
Auto-Negotiation .................................................................................................................................................. 21
Functional Overview: Switch Core .......................................................................................................................... 22
Address Look-Up ................................................................................................................................................. 22
Learning ........................................................................................................................................................... 22
Migration ........................................................................................................................................................... 22
Aging
........................................................................................................................................................... 22
Forwarding ........................................................................................................................................................... 22
Switching Engine ................................................................................................................................................. 22
MAC Operation .................................................................................................................................................... 22
Inter Packet Gap (IPG) ................................................................................................................................ 22
Backoff Algorithm ......................................................................................................................................... 23
Late Collision ............................................................................................................................................... 23
Illegal Frames .............................................................................................................................................. 23
Flow Control ................................................................................................................................................. 23
Half-Duplex Back Pressure .......................................................................................................................... 23
Broadcast Storm Protection ................................................................................................................................. 23
MII Interface Operation .............................................................................................................................................. 24
SNI Interface (7-wire) Operation ............................................................................................................................... 26
Prorammable Features .............................................................................................................................................. 26
Priority Schemes .................................................................................................................................................. 26
Per Port Method ................................................................................................................................................... 26
802.1p Method ..................................................................................................................................................... 26
IPv4 DSCP Method .............................................................................................................................................. 26
Other Priority Considerations ............................................................................................................................... 26
VLAN Operation ......................................................................................................................................................... 27
Station MAC Address ................................................................................................................................................ 27
EEPROM Operation ................................................................................................................................................... 28
Optional CPU Interface ............................................................................................................................................. 28
KS8999
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Micrel
EEPROM Memory Map .............................................................................................................................................. 29
General Conrol Register .............................................................................................................................. 29
Priority Classification Control: 802.1p Tag Field ......................................................................................... 29
Port 1 Control Register ................................................................................................................................ 29
Port 2 Control Register ................................................................................................................................ 30
Port 3 Control Register ................................................................................................................................ 30
Port 4 Control Register ................................................................................................................................ 30
Port 5 Control Register ................................................................................................................................ 31
Port 6 Control Register ................................................................................................................................ 31
Port 7 Control Register ................................................................................................................................ 32
Port 8 Control Register ................................................................................................................................ 32
Port 9 Control Register ................................................................................................................................ 32
Port 1 VLAN Mask Register ......................................................................................................................... 33
Port 2 VLAN Mask Register ......................................................................................................................... 33
Port 3 VLAN Mask Register ......................................................................................................................... 34
Port 4 VLAN Mask Register ......................................................................................................................... 34
Port 5 VLAN Mask Register ......................................................................................................................... 35
Port 6 VLAN Mask Register ......................................................................................................................... 35
Port 7 VLAN Mask Register ......................................................................................................................... 36
Port 8 VLAN Mask Register ......................................................................................................................... 36
Port 9 VLAN Mask Register ......................................................................................................................... 37
Port 1 VLAN Tag Insertion Value Registers ................................................................................................. 37
Port 2 VLAN Tag Insertion Value Registers ................................................................................................. 37
Port 3 VLAN Tag Insertion Value Registers ................................................................................................. 37
Port 4 VLAN Tag Insertion Value Registers ................................................................................................. 37
Port 5 VLAN Tag Insertion Value Registers ................................................................................................. 38
Port 6 VLAN Tag Insertion Value Registers ................................................................................................. 38
Port 7 VLAN Tag Insertion Value Registers ................................................................................................. 38
Port 8 VLAN Tag Insertion Value Registers ................................................................................................. 38
Port 9 VLAN Tag Insertion Value Registers ................................................................................................. 38
Diff Serve Code Point Registers .................................................................................................................. 38
Station MAC Address Registers .................................................................................................................. 38
Absolute Maximum Ratings ..................................................................................................................................... 39
Operating Ratings ..................................................................................................................................................... 39
Electrical Characteristics (KS8999) ......................................................................................................................... 39
Electrical Characteristics (KS8999I) ........................................................................................................................ 41
Timing Diagrams ....................................................................................................................................................... 42
Reference Circuit ....................................................................................................................................................... 47
4B/5B Coding ........................................................................................................................................................... 49
MLT Coding
........................................................................................................................................................... 50
MAC Frame
........................................................................................................................................................... 50
Selection of Isolation Transformers ........................................................................................................................ 51
Selection of Reference Oscillator/Crystal ............................................................................................................... 51
Qualified Magnetic Lists ........................................................................................................................................... 51
Package Information ................................................................................................................................................. 52
January 2005
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KS8999
KS8999
Micrel
purposes or public network access. The major benefits of
using the KS8999 are the lower power consumption,
unmanaged operation, flexible configuration, built in frame
buffering, VLAN abilities and traffic priority control. Two such
applications are depicted below.
System Level Applications
The KS8999 can be configured to fit either in an eight port 10/
100 application or as a nine port 10/100 network interface
with an extra MII/7-wire port. This MII/7-wire port can be
connected to an external processor and used for routing
Public
Network
Access
Routing
Engine
MII or
SNI
KS8999
8-Port
Switch
with PHY
KS8999
9-Port
Switch
with PHY
8X
Transformer
or Fiber
Interface
8X
Transformer
or Fiber
Interface
8-Port Stand Alone
Or
9-Port with Public
Network Interface
Figure 1. System Applicastions
KS8999
6
January 2005
KS8999
Micrel
Pin Description
Pin Number
Pin Name
Type(Note 1)
1
VDD_RX
Pwr
2.0V for equalizer
2
GND_RX
GND
Ground for equalizer
3
GND_RX
GND
Ground for equalizer
4
VDD_RX
Pwr
2.0V for equalizer
5
RXP[3]
I
3
Physical receive signal + (differential)
6
RXM[3]
I
3
Physical receive signal - (differential)
7
AOUT2
O
Factory test output
8
DOUT2
O
Factory test output
9
TXP[3]
O
3
Physical transmit signal + (differential)
10
TXM[3]
O
3
Physical transmit signal - (differential)
11
QH[5]
Opd
Factory test pin – leave open for normal operation
12
QH[4]
Opd
Factory test pin – leave open for normal operation
13
QH[3]
Opd
Factory test pin – leave open for normal operation
14
QH[2]
Opd
Factory test pin – leave open for normal operation
15
GND_TX
GND
Ground for transmit circuitry
16
VDD_TX
Pwr
2.0V for transmit circuitry
17
VDD_TX
Pwr
2.0V for transmit circuitry
18
GND-ISO
GND
Analog ground
19
TXP[4]
O
4
Physical transmit signal + (differential)
20
TXM[4]
O
4
Physical transmit signal - (differential)
21
GND_TX
GND
22
RXP[4]
I
4
Physical receive signal + (differential)
23
RXM[4]
I
4
Physical receive signal - (differential)
24
GND_RX
GND
Ground for equalizer
25
VDD_RX
Pwr
2.0V for equalizer
26
ISET
27
GND-ISO
GND
Analog ground
28
VDD_RX
Pwr
2.0V for equalizer
29
GND_RX
GND
Ground for equalizer
30
RXP[5]
I
5
Physical receive signal + (differential)
31
RXM[5]
I
5
Physical receive signal - (differential)
32
GND_TX
GND
33
TXP[5]
O
5
Physical transmit signal + (differential)
34
TXM[5]
O
5
Physical transmit signal - (differential)
Note 1.
Port
Pin Function
Ground for transmit circuitry
Set physical transmit output current
Ground for transmit circuitry
Pwr = power supply
GND = ground
I = input
O = output
I/O = bi-directional
Ipu = input w/ internal pull-up
Ipd = input w/ internal pull-down
Opu = output w/ internal pull-up
Opd = output w/ internal pull-down
Ipd/O = input w/ internal pull-down during reset, output pin otherwise
Ipu/O = input w/ internal pull-up during reset, output pin otherwise
January 2005
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KS8999
KS8999
Micrel
Pin Number
Pin Name
Type(Note 1)
35
GND-ISO
GND
Analog ground
36
VDD_TX
Pwr
2.0V for transmit circuitry
37
VDD_TX
Pwr
2.0V for transmit circuitry
38
GND_TX
GND
Ground for transmit circuitry
39
QL[2]
Opd
Factory test pin – leave open for normal operation
40
QL[3]
Opd
Factory test pin – leave open for normal operation
41
QL[4]
Opd
Factory test pin – leave open for normal operation
42
QL[5]
Opd
Factory test pin – leave open for normal operation
43
TXP[6]
O
6
Physical transmit signal + (differential)
44
TXM[6]
O
6
Physical transmit signal - (differential)
45
DOUT
O
Factory test output – leave open for normal operation
46
AOUT
O
Factory test output – leave open for normal operation
47
RXP[6]
I
6
Physical receive signal + (differential)
48
RXM[6]
I
6
Physical receive signal - (differential)
49
VDD_RX
Pwr
2.0V for equalizer
50
GND_RX
GND
Ground for equalizer
51
GND_RX
GND
Ground for equalizer
52
VDD_RX
Pwr
2.0V for equalizer
53
GND-ISO
GND
Analog ground
54
RXP[7]
I
7
Physical receive signal + (differential)
55
RXM[7]
I
7
Physical receive signal - (differential)
56
GND_TX
GND
57
TXP[7]
O
7
Physical transmit signal + (differential)
58
TXM[7]
O
7
Physical transmit signal - (differential)
59
VDD_TX
Pwr
2.0V for transmit circuitry
60
VDD_TX
Pwr
2.0V for transmit circuitry
61
TXP[8]
O
8
Physical transmit signal + (differential)
62
TXM[8]
O
8
Physical transmit signal - (differential)
63
GND_TX
GND
64
RXP[8]
I
8
Physical receive signal + (differential)
65
RXM[8]
I
8
Physical receive signal - (differential)
66
GND_RX
GND
Ground for equalizer
67
VDD_RX
Pwr
2.0V for equalizer
68
FXSD[5]
Ipd
5
Fiber signal detect
69
FXSD[6]
Ipd
6
Fiber signal detect
Note 1.
Port
Pin Function
Ground for transmit circuitry
Ground for transmit circuitry
Pwr = power supply
GND = ground
I = input
O = output
I/O = bi-directional
Ipu = input w/ internal pull-up
Ipd = input w/ internal pull-down
Opu = output w/ internal pull-up
Opd = output w/ internal pull-down
Ipd/O = input w/ internal pull-down during reset, output pin otherwise
Ipu/O = input w/ internal pull-up during reset, output pin otherwise
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January 2005
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Micrel
Pin Number
Pin Name
Type(Note 1)
Port
70
FXSD[7]
Ipd
7
Fiber signal detect
71
FXSD[8]
Ipd
8
Fiber signal detect
72
GND_RCV
GND
Ground for clock recovery circuit
73
GND_RCV
GND
Ground for clock recovery circuit
74
VDD_RCV
Pwr
2.0V for clock recovery circuit
75
VDD_RCV
Pwr
2.0V for clock recovery circuit
76
GND_RCV
GND
Ground for clock recovery circuit
77
GND_RCV
GND
Ground for clock recovery circuit
78
VDD_RCV
Pwr
2.0V for clock recovery circuit
79
VDD_RCV
Pwr
2.0V for clock recovery circuit
80
BTOUT2
O
Factory test pin – leave open for normal operation
81
CTOUT2
O
Factory test pin – leave open for normal operation
82
RLPBK
I
Enable loop back for testing – pull-down/float for normal operation
83
MUX[1]
I
Factory test pin – float for normal operation
84
MUX[2]
I
Factory test pin – float for normal operation
85
TEST[1]
I
Factory test pin – float for normal operation
86
TEST[2]
I
Factory test pin – float for normal operation
87
AUTOMDIX
I
Auto MDI/MDIX enable and disable – pull-up/float enable; pull-down
disable
88
T[1]
Ipu
Factory test pin – float for normal operation
89
T[2]
Ipd
Factory test pin – float for normal operation
90
T[3]
Ipd
Factory test pin – float for normal operation
91
EN1P
Ipd
Enable 802.1p for all ports
92
SDA
Ipd/O
Serial data from EEPROM or processor
93
SCL
Ipd/O
Clock for EEPROM or from processor
94
VDD
Pwr
2.0V for core digital circuitry
95
GND
GND
Ground for digital circuitry
96
MTXEN
Ipd
9
MII transmit enable
97
MTXD[3]
Ipd
9
MII transmit bit 3
98
MTXD[2]
Ipd
9
MII transmit bit 2
99
MTXD[1]
Ipd
9
MII transmit bit 1
100
MTXD[0]
Ipd
9
MII transmit bit 0
101
MTXER
Ipd
9
MII transmit error
102
MTXC
Ipd/O
9
MII transmit clock
103
MCOL
Ipd/O
9
MII collision detected
104
MCRS
Ipd/O
9
MII carrier sense
Note 1.
Pin Function
Pwr = power supply
GND = ground
I = input
O = output
I/O = bi-directional
Ipu = input w/ internal pull-up
Ipd = input w/ internal pull-down
Opu = output w/ internal pull-up
Opd = output w/ internal pull-down
Ipd/O = input w/ internal pull-down during reset, output pin otherwise
Ipu/O = input w/ internal pull-up during reset, output pin otherwise
January 2005
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KS8999
KS8999
Micrel
Pin Number
Pin Name
Type(Note 1)
105
VDD-IO
Pwr
2.0V, 2.5V or 3.3V for I/O circuitry
106
GND
GND
Ground for digital circuitry
107
GND
GND
Ground for digital circuitry
108
VDD
Pwr
2.0V for core digital circuitry
109
BIST
Ipd
Built in self test – tie low for normal operation
110
RST#
I
111
LED[1][3]
Ipu/O
1
LED indicator 3
112
LED[1][2]
Ipu/O
1
LED indicator 2
113
LED[1][1]
Ipu/O
1
LED indicator 1
114
LED[1][0]
Ipu/O
1
LED indicator 0
115
LED[2][3]
Ipu/O
2
LED indicator 3
116
LED[2][2]
Ipu/O
2
LED indicator 2
117
LED[2][1]
Ipu/O
2
LED indicator 1
118
LED[2][0]
Ipu/O
2
LED indicator 0
119
MRXDV
Opd
9
MII receive data valid
120
MRXD[3]
Opu
9
MII receive bit 3
121
MRXD[2]
Opu
9
MII receive bit 2
122
MRXD[1]
Opu
9
MII receive bit 1
123
MRXD[0]
Opu
9
MII receive bit 0
124
MRXC
Ipu/O
9
MII receive clock
125
VDD-IO
Pwr
2.0V, 2.5V or 3.3V for I/O circuitry
126
GND
GND
Ground for digital circuitry
127
LED[3][3]
Ipu/O
3
LED indicator 3
128
LED[3][2]
Ipu/O
3
LED indicator 2
129
LED[3][1]
Ipu/O
3
LED indicator 1
130
LED[3][0]
Ipu/O
3
LED indicator 0
131
LED[4][3]
Ipu/O
4
LED indicator 3
132
LED[4][2]
Ipu/O
4
LED indicator 2
133
LED[4][1]
Ipu/O
4
LED indicator 1
134
LED[4][0]
Ipu/O
4
LED indicator 0
135
VDD
Pwr
2.0V for core digital circuitry
136
GND
GND
Ground for digital circuitry
137
LED[5][3]
Ipu/O
5
LED indicator 3
138
LED[5][2]
Ipu/O
5
LED indicator 2
139
LED[5][1]
Ipu/O
5
LED indicator 1
Note 1.
Port
Pin Function
Reset – active low
Pwr = power supply
GND = ground
I = input
O = output
I/O = bi-directional
Ipu = input w/ internal pull-up
Ipd = input w/ internal pull-down
Opu = output w/ internal pull-up
Opd = output w/ internal pull-down
Ipd/O = input w/ internal pull-down during reset, output pin otherwise
Ipu/O = input w/ internal pull-up during reset, output pin otherwise
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January 2005
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Micrel
Pin Number
Pin Name
Type(Note 1)
Port
140
LED[5][0]
Ipu/O
5
LED indicator 0
141
LED[6][3]
Ipu/O
6
LED indicator 3
142
LED[6][2]
Ipu/O
6
LED indicator 2
143
LED[6][1]
Ipu/O
6
LED indicator 1
144
LED[6][0]
Ipu/O
6
LED indicator 0
145
LED[7][3]
Ipu/O
7
LED indicator 3
146
LED[7][2]
Ipu/O
7
LED indicator 2
147
LED[7][1]
Ipu/O
7
LED indicator 1
148
VDD-IO
Pwr
149
LED[7][0]
Ipu/O
7
LED indicator 0
150
LED[8][3]
Ipu/O
8
LED indicator 3
151
LED[8][2]
Ipu/O
8
LED indicator 2
152
LED[8][1]
Ipu/O
8
LED indicator 1
153
LED[8][0]
Ipu/O
8
LED indicator 0
154
GND
GND
Ground for digital circuitry
155
GND
GND
Ground for digital circuitry
156
IO_SWM
Ipu
Factory test pin – tie high for normal operation
157
VDD
Pwr
2.0V for core digital circuitry
158
LED[9][3]
Ipu/O
9
LED indicator 3
159
LED[9][2]
Ipu/O
9
LED indicator 2
160
LED[9][1]
Ipu/O
9
LED indicator 1
161
LED[9][0]
Ipu/O
9
LED indicator 0
162
MIIS[1]
Ipd
9
MII mode select bit 1
163
MIIS[0]
Ipd
9
MII mode select bit 0
164
MODESEL[3]
Ipd
Selects LED and test modes
165
MODESEL[2]
Ipd
Selects LED and test modes
166
MODESEL[1]
Ipd
Selects LED and test modes
167
MODESEL[0]
Ipd
Selects LED and test modes
168
TESTEN
Ipd
Factory test pin – tie low for normal operation
169
SCANEN
Ipd
Factory test pin – tie low for normal operation
170
PRSV
Ipd
Reserve 6KB buffer for priority frames
171
CFGMODE
Ipu
Configures programming interface for EEPROM or processor
172
T[5]
I
173
T[4]
Ipdthevillage
174
Reserve
I
Note 1.
Pin Function
2.0V, 2.5V or 3.3V for I/O circuitry
Factory test pin – float for normal operation
F/D = normal operation (default)
U = disable FEF
Reserved – floating for normal operation
Pwr = power supply
GND = ground
I = input
O = output
I/O = bi-directional
Ipu = input w/ internal pull-up
Ipd = input w/ internal pull-down
Opu = output w/ internal pull-up
Opd = output w/ internal pull-down
Ipd/O = input w/ internal pull-down during reset, output pin otherwise
Ipu/O = input w/ internal pull-up during reset, output pin otherwise
January 2005
11
KS8999
KS8999
Micrel
Pin Number
Pin Name
Type(Note 1)
175
Reserve
I
Reserved - floating for normal operation
176
X1
I
Crystal or clock input
177
X2
O
Connect to crystal
178
VDD_PLLTX
Pwr
2.0 V for phase locked loop circuit
179
GND_PLLTX
GND
Ground for phase locked loop circuit
180
CTOUT
O
Factory test pin – leave open for normal operation
181
BTOUT
O
Factory test pin – leave open for normal operation
182
VDD_RCV
Pwr
2.0V for clock recovery circuit
183
VDD_RCV
Pwr
2.0V for clock recovery circuit
184
GND_RCV
GND
Ground for clock recovery circuit
185
GND_RCV
GND
Ground for clock recovery circuit
186
VDD_RCV
Pwr
2.0V for clock recovery circuit
187
VDD_RCV
Pwr
2.0V for clock recovery circuit
188
GND_RCV
GND
Ground for clock recovery circuit
189
GND_RCV
GND
Ground for clock recovery circuit
190
FXSD[1]
Ipd
1
Fiber signal detect
191
FXSD[2]
Ipd
2
Fiber signal detect
192
FXSD[3]
Ipd
3
Fiber signal detect
193
FXSD[4]
Ipd
4
Fiber signal detect
194
VDD_RX
Pwr
2.0V for equalizer
195
GND_RX
GND
Ground for equalizer
196
RXP[1]
I
1
Physical receive signal + (differential)
197
RXM[1]
I
1
Physical receive signal - (differential)
198
GND_TX
GND
199
TXP[1]
O
1
Physical transmit signal + (differential)
200
TXM[1]
O
1
Physical transmit signal - (differential)
201
VDD_TX
Pwr
2.0V for transmit circuitry
202
VDD_TX
Pwr
2.0V for transmit circuitry
203
TXP[2]
O
2
Physical transmit signal + (differential)
204
TXM[2]
O
2
Physical transmit signal - (differential)
205
GND_TX
GND
206
RXP[2]
I
2
Physical receive signal + (differential)
207
RXM[2]
I
2
Physical receive signal - (differential)
208
GND-ISO
GND
Note 1.
KS8999
Port
Pin Function
Ground for transmit circuitry
Ground for transmit circuitry
Analog ground
Pwr = power supply
GND = ground
I = input
O = output
I/O = bi-directional
Ipu = input w/ internal pull-up
Ipd = input w/ internal pull-down
Opu = output w/ internal pull-up
Opd = output w/ internal pull-down
Ipd/O = input w/ internal pull-down during reset, output pin otherwise
Ipu/O = input w/ internal pull-up during reset, output pin otherwise
12
January 2005
KS8999
Micrel
I/O Grouping
Group Name
PHY
Description
Physical Interface
MII
Media Independent Interface
SNI
Serial Network Interface
IND
LED Indicators
UP
Unmanaged Programmable
CTRL
Control and Miscellaneous
TEST
Test (Factory)
PWR
Power and Ground
I/O Descriptions
Group
I/O Names
Active Status
PHY
RXP[1:8]
RXM[1:8]
Analog
Differential inputs (receive) for connection to media (transformer or fiber module)
TXP[1:8]
TXM[1:8]
Analog
Differential outputs (transmit) for connection to media (transformer or fiber module)
FXSD[1:8]
H
ISET
Analog
MRXD[0:3]
H
Four bit wide data bus for receiving MAC frames
MRXDV
H
Receive data valid
MCOL
H
Receive collision detection
MCRS
H
Carrier sense
MTXD[0:3]
H
Four bit wide data bus for transmitting MAC frames
MTXEN
H
Transmit enable
MTXER
H
Transmit error
MRXC
Clock
MII receive clock
MTXC
Clock
MII transmit clock
MTXD[0]
H
Serial transmit data
MTXEN
H
Transmit enable
MRXD[0]
H
Serial receive data
MRXDV
H
Receive carrier sense/data valid
MCOL
H
Collision detection
MRXC
Clock
SNI receive clock
MTXC
Clock
SNI transmit clock
LED[1:9][0]
L
MII
SNI
IND
January 2005
Description
Fiber signal detect – connect to fiber signal detect output on fiber module with
appropriate voltage divider if needed. Tie low for copper mode.
Transmit Current Set. Connecting an external reference resistor to set transmitter
output current. This pin connects to a 3KΩ 1% resistor to ground if a transformer with
1:1 turn ratio is used.
Output (after reset)
Mode 0: Speed (on = 100/off = 10)
Mode 1: 10/100 + link + activity
10Mb link activity = slow blink (non-periodic blinking)
100Mb link activity = fast blink (non-periodic blinking)
Mode 2: Collision (on = collision/off = no collision)
Mode 3: Speed (on = 100/off = 10)
13
KS8999
KS8999
Micrel
Group
Description(Note 1)
I/O Names
Active Status
LED[1:9][1]
L
Output (after reset)
Mode 0: Full Duplex (on = full/off = half)
Mode 1: Full Duplex (on = full/off = half)
Mode 2: Full Duplex (on = full/off = half)
Mode 3: Reserved
LED[1:9][2]
L
Output (after reset)
Mode 0: Collision (on = collision/off = no collision)
Mode 1: Transmit Activity (on during transmission)
Mode 2: Link activity (10Mb mode)
Mode 3: Full Duplex + Collision
(constant on = full duplex; intermittent on = collision; off = half-duplex with no collision)
LED[1:9][3]
L
Output (after reset)
Mode 0: Link + Activity
When LED is solid “on”, it indicates the link is on for both 10 or 100BaseTX, but no
data is transmitting or receiving.
When LED is solid “off”, it indicates the link is off.
When LED is blinking, it indicates data is transmitting or receiving for either 10 or 100
BaseTX
Mode 1: Receive Activity (on = receiving/off = not receiving)
Mode 2: Link activity (100Mb mode)
Mode 3: Link + Activity (see description above)
Note: Mode is set by MODESEL[3:0] ; please see description in UP (unmanaged
programming) section.
UP
MODESEL[3:0]
H
Mode select at reset time. LED mode is selected by using the table below. Note that
under normal operation MODESEL[3:2] must be tied low.
MODESEL
Note 1.
KS8999
3
2
1
0
Operation
0
0
0
0
LED mode 0
0
0
0
1
LED mode 1
0
0
1
0
LED mode 2
0
0
1
1
LED mode 3
0
1
0
0
Used for factory testing
0
1
0
1
Used for factory testing
0
1
1
0
Used for factory testing
0
1
1
1
Used for factory testing
1
0
0
0
Used for factory testing
1
0
0
1
Used for factory testing
1
0
1
0
Used for factory testing
1
0
1
1
Used for factory testing
1
1
0
0
Used for factory testing
1
1
0
1
Used for factory testing
1
1
1
0
Used for factory testing
1
1
1
1
Used for factory testing
LED[1][3]
Programs auto-negotiation on port 1
D = Disable auto-negotiation, F/U = Enable auto-negotiation (default)
LED[1][2]
Programs auto-negotiation on port 2
D = Disable auto-negotiation, F/U = Enable auto-negotiation (default)
LED[1][1]
Programs auto-negotiation on port 3
D = Disable auto-negotiation, F/U = Enable auto-negotiation (default)
All unmanaged programming takes place at reset time only. For unmanaged programming: F = Float, D = Pull-down, U = Pull-up.
See “Reference Circuits” section.
14
January 2005
KS8999
Group
Micrel
I/O Names
Active Status
Description(Note 1)
LED[1][0]
Programs auto-negotiation on port 4
D = Disable auto-negotiation, F/U = Enable auto-negotiation (default)
LED[2][3]
Programs auto-negotiation on port 5
D = Disable auto-negotiation, F/U = Enable auto-negotiation (default)
LED[2][2]
Programs auto-negotiation on port 6
D = Disable auto-negotiation, F/U = Enable auto-negotiation (default)
LED[2][1]
Programs auto-negotiation on port 7
D = Disable auto-negotiation, F/U = Enable auto-negotiation (default)
LED[2][0]
Programs auto-negotiation on port 8
D = Disable auto-negotiation, F/U = Enable auto-negotiation (default)
LED[3][3]
Programs port speed on port 1. This is only effective if auto-negotiation is disabled.
D = 10Mbps, F/U = 100Mbps (default)
LED[3][2]
Programs port speed on port 2. This is only effective if auto-negotiation is disabled.
D = 10Mbps, F/U = 100Mbps (default)
LED[3][1]
Programs port speed on port 3. This is only effective if auto-negotiation is disabled.
D = 10Mbps, F/U = 100Mbps (default)
Note 1.
LED[3][0]
Programs port speed on port 4. This is only effective if auto-negotiation is disabled.
D = 10Mbps, F/U = 100Mbps (default)
LED[4][3]
Programs port speed on port 5. This is only effective if auto-negotiation is disabled.
D = 10Mbps, F/U = 100Mbps (default)
LED[4][2]
Programs port speed on port 6. This is only effective if auto-negotiation is disabled.
D = 10Mbps, F/U = 100Mbps (default)
LED[4][1]
Programs port speed on port 7. This is only effective if auto-negotiation is disabled.
D = 10Mbps, F/U = 100Mbps (default)
LED[4][0]
Programs port speed on port 8. This is only effective if auto-negotiation is disabled.
D = 10Mbps, F/U = 100Mbps (default)
LED[5][3]
Programs port duplex (full/ half) on port 1. This is only effective if auto-negotiation is
disabled or if this end has auto- negotiation enabled and the far end has auto
negotiation disabled.
D = Full-duplex, F/U = Half-duplex (default)
LED[5][2]
Programs port duplex (full/ half) on port 2. This is only effective if auto-negotiation is
disabled or if this end has auto-negotiation enabled and the far end has autonegotiation disabled.
D = Full-duplex, F/U = Half-duplex (default)
LED[5][1]
Programs port duplex (full/ half) on port 3. This is only effective if auto-negotiation is
disabled or if this end has auto-negotiation enabled and the far end has autonegotiation disabled.
D = Full-duplex, F/U = Half-duplex (default)
LED[5][0]
Programs port duplex (full/ half) on port 4. This is only effective if auto-negotiation is
disabled or if this end has auto-negotiation enabled and the far end has autonegotiation disabled.
D = Full-duplex, F/U = Half-duplex (default)
LED[9][3]
Programs port duplex (full/ half) on port 5. This is only effective if auto-negotiation is
disabled or if this end has auto-negotiation enabled and the far end has auto
negotiation disabled.
D = Full-duplex, F/U = Half-duplex (default)
LED[9][2]
Programs port duplex (full/ half) on port 6. This is only effective if auto-negotiation is
disabled or if this end has auto-negotiation enabled and the far end has autonegotiation disabled.
D = Full-duplex, F/U = Half-duplex (default)
All unmanaged programming takes place at reset time only. For unmanaged programming: F = Float, D = Pull-down, U = Pull-up.
See “Reference Circuits” section.
January 2005
15
KS8999
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Micrel
Group
I/O Names
Active Status
LED[9][1]
Programs port duplex (full / half) on port 7. This is only effective if auto-negotiation is
disabled or if this end has auto-negotiation enabled and the far end has autonegotiation disabled.
D = Full-duplex, F/U = Half-duplex (default)
LED[9][0]
Programs port duplex (full / half) on port 8. This is only effective if auto-negotiation is
disabled or if this end has auto-negotiation enabled and the far end has autonegotiation disabled.
D = Full-duplex, F/U = Half-duplex (default)
LED[6][3]
Programs back-off aggressiveness for half-duplex mode
D = Less aggressive back-off, F/U = More aggressive back-off (default)
LED[6][2]
Programs retries for frames that encounter collisions.
D = Drop frame after 16 collisions, F/U = Continue sending frame regardless of the
number of collisions (default)
LED[6][1:0]
CTRL
Description(Note 1)
Reserved – use float configuration
LED[7][3]
Programs flow control
D = No flow control, F/U = Flow control enabled (default)
LED[7][2]
Programs broadcast storm protection.
D = 5% broadcast frames allowed, F/U = Unlimited broadcast frames (default)
LED[7][1]
Programs buffer sharing feature.
D = Equal amount of buffers per port (113 buffers), F/U = Share buffers up to 512
buffers on a single port (default)
LED[7][0]
Reserved – use float configuration
LED[8][3]
Programs address aging.
D = Aging disabled, F/U = Enable 5 minute aging (default)
LED[8][2]
Programs frame length enforcement.
D = Max length for VLAN is 1522 bytes and without VLAN is 1518 bytes
F/U = Max length is 1536 bytes (default)
LED[8][1]
Reserved
LED[8][0]
Programs half-duplex back pressure.
D = No half-duplex back pressure, F/U = Half-duplex back pressure enabled (default)
MRXD[3]
Programs port 9 speed
D = 10Mbps, F/U = 100Mbps (default)
MRXD[2]
Programs port 9 duplex
D = Half-duplex, F/U = Full duplex (default)
MRXD[1]
Programs port 9 flow control
D = Flow control, F/U = No flow control (default)
MRXD[0]
D = reserved, F/U = normal operation (default)
EN1P
H
Enable 802.1p for all ports – this enables QoS based on the priority field in the layer
2 header.
0 = 802.1p selected by port in EEPROM
1 = Use 802.1p priority field unless disabled in EEPROM
Note: This is also controlled by the EEPROM registers (registers 4-12 bit 4). The values
in the EEPROM supercede this pin. Also, if the priority selection is unaltered in the
EEPROM registers (register 3 bits 0-7) then values above 3 are considered high priorty
and less than 4 are low priority.
MIIS[1:0]
Note 1.
KS8999
H
MII mode selection – allows the MII to run in the following modes
MIIS
1 0
Operating mode
0
0
1
1
Disable MII interface
Reverse MII
Forward MII
7 wire mode (SNI)
0
1
0
1
All unmanaged programming takes place at reset time only. For unmanaged programming: F = Float, D = Pull-down, U = Pull-up.
See “Reference Circuits” section.
16
January 2005
KS8999
Micrel
Group
I/O Names
Active Status
PRSV
H
Description(Note 1)
Priority buffer reserve – reserves 6KB of buffer space for the priority traffic if enabled.
0 = No priority reserve
1 = Reserve 6KB for priority traffic
Note: This is also controlled by the EEPROM registers (register 2 bit 1). The value in
the EEPROM supercedes this pin.
CFGMODE
H
X1
Clock
External crystal or clock input
X2
Clock
Used when other polarity of crystal is needed. This is unused for a normal clock input.
SCL
Clock
Clock for EEPROM
SDA
I/O
RST#
L
System reset
TESTEN
H
Factory test input – tie low for normal operation
SCANEN
H
Factory test input – tie low for normal operation
MUX[1:2]
H
Factory test input – leave open for normal operation
AOUT
H
Factory test output – leave open for normal operation
DOUT
H
Factory test output – leave open for normal operation
AOUT2
H
Factory test output – leave open for normal operation
DOUT2
H
Factory test output – leave open for normal operation
BTOUT
H
Factory test output – leave open for normal operation
CTOUT
H
Factory test output – leave open for normal operation
BTOUT2
H
Factory test output – leave open for normal operation
CTOUT2
H
Factory test output – leave open for normal operation
TEST[1:2]
H
Factory test inputs – leave open for normal operation
AUTOMDIX
H
F/U = Enable Auto MDI/MDIX (normal operation)
D = Disable Auto MDI/MDIX
T[1:3] & T[5]
H
Factory test inputs – leave open (float) for normal operation
T[4]
H
F/D = normal operation (default)
U = Disable FEF
QH[2:5]
H
Factory test outputs – leave open for normal operation
QL[2:5]
H
Factory test outputs – leave open for normal operation
IO_SWM
H
Factory test input – tie high for normal operation
RLPBK
H
Factory test input – tie low for normal operation
BIST
H
Factory test input – tie low for normal operation
TEST
PWR
Serial data for EEPROM
VDD_RX
2.0V for equalizer
GND_RX
Ground for equalizer
VDD_TX
2.0V for transmit circuitry
GND_TX
Ground for transmit circuitry
VDD_RCV
2.0V for clock recovery circuitry
GND_RCV
Ground for clock recovery
VDD_PLLTX
Note 1.
Selects between EEPROM or processor for programming interface.
0 = Processor interface
1 = EEPROM interface or not programmed on this interface (SCL / SDA not used)
2.0V for phase locked loop circuitry
All unmanaged programming takes place at reset time only. For unmanaged programming: F = Float, D = Pull-down, U = Pull-up.
See “Reference Circuits” section.
January 2005
17
KS8999
KS8999
Group
Micrel
I/O Names
GND_PLLTX
GND-ISO
VDD
VDD-IO
GND
KS8999
Active Status
Description
Ground for phase locked loop circuitry
Analog ground
2.0V for core digital circuitry
2.0V, 2.5V or 3.3V for I/O circuitry
Ground for digital circuitry
18
January 2005
KS8999
Micrel
IO_SWM
GND
GND
LED[8][0]
LED[8][1]
LED[8][2]
LED[8][3]
LED[7][0]
VDD_IO
LED[7][1]
LED[7][2]
LED[7][3]
LED[6][0]
LED[6][1]
LED[6][2]
LED[6][3]
LED[5][0]
LED[5][1]
LED[5][2]
LED[5][3]
GND
VDD
LED[4][0]
LED[4][1]
LED[4][2]
LED[4][3]
LED[3][0]
LED[3][1]
LED[3][2]
LED[3][3]
GND
VDD_IO
MRXC
MRXD[0]
MRXD[1]
MRXD[2]
MRXD[3]
MRXDV
LED[2][0]
LED[2][1]
LED[2][2]
LED[2][3]
LED[1][0]
LED[1][1]
LED[1][2]
LED[1][3]
RST#
BIST
VDD
GND
GND
VDD_IO
Pin Configuration
105
VDD
LED[9][3]
LED[9][2]
LED[9][1]
LED[9][0]
MIIS[1]
MIIS[0]
MODESEL[3]
MODESEL[2]
MODESEL[1]
MODESEL[0]
TESTEN
SCANEN
PRSV
CFGMODE
T[5]
T[4]
RESERVE
RESERVE
X1
X2
VDD_PLLTX
GND_PLLTX
CTOUT
BTOUT
VDD_RCV
VDD_RCV
GND_RCV
GND_RCV
VDD_RCV
VDD_RCV
GND_RCV
GND_RCV
FXSD[1]
FXSD[2]
FXSD[3]
FXSD[4]
VDD_RX
GND_RX
RXP[1]
RXM[1]
GND_TX
TXP[1]
TXM[1]
VDD_TX
VDD_TX
TXP[2]
TXM[2]
GND_TX
RXP[2]
RXM[2]
GND_ISO
157
53
MCRS
MCOL
MTXC
MTXER
MTXD[0]
MTXD[1]
MTXD[2]
MTXD[3]
MTXEN
GND
VDD
SCL
SDA
EN1P
T[3]
T[2]
T[1]
AUTOMDIX
TEST[2]
TEST[1]
MUX[2]
MUX[1]
RLPBK
CTOUT2
BTOUT2
VDD_RCV
VDD_RCV
GND_RCV
GND_RCV
VDD_RCV
VDD_RCV
GND_RCV
GND_RCV
FXSD[8]
FXSD[7]
FXSD[6]
FXSD[5]
VDD_RX
GND_RX
RXM[8]
RXP[8]
GND_TX
TXM[8]
TXP[8]
VDD_TX
VDD_TX
TXM[7]
TXP[7]
GND_TX
RXM[7]
RXP[7]
GND_ISO
VDD_RX
GND_RX
GND_RX
VDD_RX
RXP[3]
RXM[3]
AOUT2
DOUT[2]
TXP[3]
TXM[3]
QH[5]
QH[4]
QH[3]
QH[2]
GND_TX
VDD_TX
VDD_TX
GND_ISO
TXP[4]
TXM[4]
GND_TX
RXP[4]
RXM[4]
GND_RX
VDD_RX
ISET
GND_ISO
VDD_RX
GND_RX
RXP[5]
RXM[5]
GND_TX
TXP[5]
TXM[5]
GND_ISO
VDD_TX
VDD_TX
GND_TX
QL[2]
QL[3]
QL[4]
QL[5]
TXP[6]
TXM[6]
DOUT
AOUT
RXP[6]
RXM[6]
VDD_RX
GND_RX
GND_RX
VDD_RX
1
208-Pin PQFP (PQ)
January 2005
19
KS8999
KS8999
Micrel
Functional Overview: Physical Layer Transceiver
100BaseTX Transmit
The 100BaseTX transmit function performs parallel to serial conversion, 4B/5B coding, scrambling, NRZ to NRZI conversion, MLT3 encoding and transmission. The circuit starts with a parallel to serial conversion, which converts the 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, then transmitted in MLT3 current output.
The output current is set by an external 1% 3.01kΩ resistor for the 1:1 transformer ratio. It has a typical rise/fall time of 4
ns and complies to the ANSI TP-PMD standard regarding amplitude balance, overshoot and timing jitters. The waveshaped 10BaseT output is also incorporated into the 100BaseTX transmitter.
100BaseTX Receive
The 100BaseTX receiver function performs adaptive equalization, DC restoration, MLT3 to NRZI conversion, data and
clock recovery, NRZI to NRZ conversion, de-scrambling, 4B/5B decoding and serial to parallel conversion. The receiving
side starts with the equalization filter to compensate inter-symbol interference (ISI) over the twisted pair cable. Since the
amplitude loss and phase distortion is a function of the length of the cable, the equalizer has to adjust its characteristics to
optimize the performance. This is an ongoing process and can self adjust to the environmental changes such as temperature variations. The equalized signal then goes through a DC restoration and data conversion block. The DC restoration
circuit is used to compensate for the effect of base line wander and improve the dynamic range. The differential data
conversion circuit converts the MLT3 format back to NRZI. The slicing threshold is also adaptive. The clock recovery
circuit extracts the 125MHz clock from the edges of the NRZI signal. This recovered clock is then used to convert the
NRZI signal into the NRZ format. The signal is then sent through the de-scrambler followed by the 4B/5B decoder. Finally,
the NRZ serial data is provided as the input data to the MAC.
PLL Clock Synthesizer
The KS8999 generates 125MHz, 62.5MHz, 25MHz and 10MHz clocks for system timing. Internal clocks are generated
from an external 25MHz crystal.
Scrambler/De-scrambler (100BaseTX only)
The purpose of the scrambler is to spread the power spectrum of the signal in order to reduce EMI and baseline wander.
The data is scrambled by the use of an 11-bit wide linear feedback shift register (LFSR). This can generate a 2047-bit
non-repetitive sequence. The receiver will then de-scramble the incoming data stream with the same sequence at the
transmitter.
100BaseFX Operation
100BaseFX operation is very similar to 100BaseTX operation with the differences being that the scrambler/de-scrambler
and MLT3 encoder/decoder are bypassed on transmission and reception. In this mode the auto-negotiation feature is
bypassed since there is no standard that supports fiber auto-negotiation.
100BaseFX Signal Detection
The physical port runs in 100BaseFX mode if FXSDx >0.6V. FXSDx is considered ‘low’ when 0.6V<FXSDx<1.25V and
considered ‘high’ when FXSDx>1.25V. If FXSDx goes into ‘low’ state, the link is considered lost and the link active LED
will go off. For FXSDx in the high state, the link is considered active. When FXSDx is below .6V then 100BaseFX mode is
disabled. (see application note for detailed information).
100BaseFX Far End Fault
Far end fault occurs when the signal detection is logically false from the receive fiber module which occurs when FXSDx is
below 1.2V and above 0.6V. When this occurs, the transmission side signals the other end of the link by sending 84 1’s followed
by a zero in the idle period between frames.
10BaseT Transmit
The output 10BaseT driver is incorporated into the 100BaseT driver to allow transmission with the same magnetics. They are
internally wave-shaped and pre-emphasized into outputs with a typical 2.3V amplitude.
10BaseT Receive
On the receive side, input buffer and level detecting squelch circuits are employed. A differential input receiver circuit and a
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 400mV or with short pulse widths in order to prevent noises at the RXP or
RXM input from falsely triggering the decoder. When the input exceeds the squelch limit, the PLL locks onto the incoming signal
and the KS8999 decodes a data frame. The receiver clock is maintained active during idle periods in between data reception.
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Micrel
Power Management
Power Save Mode
The KS8999 will turn off everything except for the Energy Detect and PLL circuits when the cable is not installed on an individual
port basis. In other words, the KS8999 will shutdown most of the internal circuits to save power if there is no link.
MDI/MDI-X Auto Crossover
The KS8999 supports MDI/MDI-X auto crossover. This facilitates the use of either a straight connection CAT-5 cable or a
crossover CAT-5 cable. The auto-sense function will detect remote transmit and receive pairs, and correctly assign the transmit
and receive pairs from the Micrel device. This can be highly useful when end users are unaware of cable types and can also
save on an additional uplink configuration connection.
The auto MDI/MDI-X is achieved by the Micrel device listening for the far end transmission channel and assigning transmit/
receive pairs accordingly. Auto MDI/MDI-X can be disabled by pulling the pin 87 (AUTOMDIX) to low.
Auto-Negotiation
The KS8999 conforms to the auto-negotiation protocol as described by the 802.3 committee. Auto-negotiation allows UTP
(Unshielded Twisted Pair) link partners to select the best common mode of operation. In auto-negotiation the link partners
advertise capabilities across the link to each other. If auto-negotiation is not supported or the link partner to the KS8999 is forced
to bypass auto-negotiation , then the mode is set by observing the signal at the receiver. This is known as parallel mode because
while the transmitter is sending auto-negotiation advertisements, the receiver is listening for advertisements or a fixed signal
protocol.
The flow for the link set up is depicted below.
Start Auto Negotiation
Force Link Setting
Parallel
Operation
No
Yes
Bypass
Auto-Negotiation
and Set Link Mode
Attempt
Auto-Negotiation
Listen for 100BaseTX
Idles
Listen for 10BaseT
Link Pulses
No
Join Flow
Link Mode Set ?
Yes
Link Mode Set
Figure 2. Auto-Negotiation
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KS8999
KS8999
Micrel
Functional Overview: Switch Core
Address Look-Up
The internal look-up table stores MAC addresses and their associated information. It contains 1K full CAM with 48-bit address
plus switching information. The KS8999 is guaranteed to learn 1K addresses and distinguishes itself from hash-based lookup tables which, depending on the operating environment and probabilities, may not guarantee the absolute number of
addresses it can learn.
Learning
The internal look-up engine will update its table with a new entry if the following conditions are met:
• The received packet’s SA does not exist in the look-up table.
• The received packet is good; the packet has no receiving errors, and is of legal length.
The look-up engine will insert the qualified SA into the table, along with the port number, time stamp. If the table is full, the last
entry of the table will be deleted first to make room for the new entry.
Migration
The internal look-up engine also monitors whether a station is moved. If it happens, it will update the table accordingly.
Migration happens when the following conditions are met:
• The received packet’s SA is in the table but the associated source port information is different.
• The received packet is good; the packet has no receiving errors, and is of legal length.
The look-up engine will update the existing record in the table with the new source port information.
Aging
The look-up engine will update time stamp information of a record whenever the corresponding SA appears. The time stamp
is used in the aging process. If a record is not updated for a period of time, the look-up engine will then remove the record from
the table. The look-up engine constantly performs the aging process and will continuously remove aging records. The aging
period is 300 seconds. This feature can be enabled or disabled by external pull-up or pull-down resistors.
Forwarding
The KS8999 will forward packets as follows:
• If the DA look-up results is a “match”, the KS8999 will use the destination port information to determine where the
packet goes.
• If the DA look-up result is a “miss”, the KS8999 will forward the packet to all other ports except the port that received
the packet.
• All the multicast and broadcast packets will be forwarded to all other ports except the source port.
The KS8999 will not forward the following packets:
• Error packets. These include framing errors, FCS errors, alignment errors, and illegal size packet errors.
• 802.3x pause frames. The KS8999 will intercept these packets and do the appropriate actions.
• “Local” packets. Based on destination address (DA) look-up. If the destination port from the look-up table matches
the port where the packet was from, the packet is defined as “local”.
Switching Engine
The KS8999 has a very high performance switching engine to move data to and from the MAC’s, packet buffers. It operates
in store and forward mode, while the efficient switching mechanism reduces overall latency.
The KS8999 has an internal buffer for frames that is 32Kx32 (128KB). This resource could be shared between the nine ports
and is programmed at system reset time by using the unmanaged program mode (I/O strapping).
Each buffer is sized at 128B and therefore there are a total of 1024 buffers available. Two different modes are available for
buffer allocation. One mode equally allocates the buffers to all the ports (113 buffers per port). The other mode adaptively
allocates buffers up to 512 to a single port based on loading. Selection is achieved by using LED[7][1] in the unmanaged
programming description.
MAC Operation
The KS8999 strictly abides by IEEE 802.3 standard to maximize compatibility.
Inter Packet Gap (IPG)
If a frame is successfully transmitted, the 96 bit time IPG is measured between the two consecutive MTXEN. If the current
packet is experiencing collision, the 96 bit time IPG is measured from MCRS and the next MTXEN.
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Backoff Algorithm
The KS8999 implements the IEEE Std 802.3 binary exponential back-off algorithm, and optional “aggressive mode” back off.
After 16 collisions, the packet will be optionally dropped depending on the chip configuration.
Late Collision
If a transmit packet experiences collisions after 512 bit times of the transmission, the packet will be dropped.
Illegal Frames
The KS8999 discards frames less than 64 bytes and can be programmed to accept frames up to 1536 bytes. Since the KS8999
supports VLAN tags, the maximum sizing is adjusted when these tags are present.
Flow Control
The KS8999 supports standard 802.3x flow control frames on both transmit and receive sides.
On the receive side, if the KS8999 receives a pause control frame, the KS8999 will not transmit the next normal frame until
the timer, specified in the pause control frame, expires. If another pause frame is received before the current timer expires,
the timer will be updated with the new value in the second pause frame. During this period (being flow controlled), only flow
control packets from the KS8999 will be transmitted.
On the transmit side, the KS8999 has intelligent and efficient ways to determine when to invoke flow control. The flow control
is based on availability of the system resources, including available buffers, available transmit queues and available receive
queues.
The KS8999 will flow control a port, which just received a packet, if the destination port resource is being used up. The KS8999
will issue a flow control frame (XOFF), containing the maximum pause time defined in IEEE standard 802.3x. Once the resource
is freed up, the KS8999 will send out the other flow control frame (XON) with zero pause time to turn off the flow control (turn
on transmission to the port). A hysteresis feature is provided to prevent flow control mechanism from being activated and
deactivated too many times.
The KS8999 will flow control all ports if the receive queue becomes full.
Half Duplex Back Pressure
Half duplex back pressure option (Note: not in 802.3 standards) is also provided. The activation and deactivation conditions
are the same as the above in full duplex mode. If back pressure is required, the KS8999 will send preambles to defer other
stations’ transmission (carrier sense deference). To avoid jabber and excessive deference defined in 802.3 standard, after a
certain time it will discontinue the carrier sense but it will raise the carrier sense quickly. This short silent time (no carrier sense)
is to prevent other stations from sending out packets and keeps other stations in carrier sense deferred state. If the port has
packets to send during a back pressure situation, the carrier sense type back pressure will be interrupted and those packets
will be transmitted instead. If there are no more packets to send, carrier sense type back pressure will be active again until switch
resources free up. If a collision occurs, the binary exponential back-off algorithm is skipped and carrier sense is generated
immediately, reducing the chance of further colliding and maintaining carrier sense to prevent reception of packets.
Broadcast Storm Protection
The KS8999 has an intelligent option to protect the switch system from receiving too many broadcast packets. Broadcast
packets will be forwarded to all ports except the source port, and thus will use too many switch resources (bandwidth and
available space in transmit queues). The KS8999 will discard broadcast packets if the number of those packets exceeds the
threshold (configured by strapping during reset and EEPROM settings) in a preset period of time. If the preset period expires
it will then resume receiving broadcast packets until the threshold is reached. The options are 5% of network line rate for the
maximum broadcast receiving threshold or unlimited (feature off).
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KS8999
Micrel
MII Interface Operation
The MII (Media Independent Interface) operates in either a MAC or PHY mode. In the MAC mode, the KS8999 MII acts like
a MAC and in the PHY mode, it acts like a PHY device. This interface is specified by the IEEE 802.3 committee and provides
a common interface between physical layer and MAC layer devices. There are two distinct groups, one being for transmission
and the other for receiving. The table below describes the signals used in this interface in MAC and PHY modes.
PHY Mode Connection
MAC Mode Connection
External MAC
Controller Signals
KS8999
PHY Signals
Description
External
PHY Signals
KS8999
MAC Signals
MTXEN
MTXEN
Transmit enable
MTXEN
MRXDV
MTXER
MTXER
Transmit error
MTXER
Not used
MTXD3
MTXD[3]
Transmit data bit 3
MTXD3
MRXD[3]
MTXD2
MTXD[2]
Transmit data bit 2
MTXD2
MRXD[2]
MTXD1
MTXD[1]
Transmit data bit 1
MTXD1
MRXD[1]
MTXD0
MTXD[0]
Transmit data bit 0
MTXD0
MRXD[0]
MTXC
MTXC
Transmit clock
MTXC
MTXC
MCOL
MCOL
Collision detection
MCOL
MCOL
MCRS
MCRS
Carrier sense
MCRS
MCRS
MRXDV
MRXDV
Receive data valid
MRXDV
SMTXEN
MRXER
Not used
Receive error
MRXER
MTXER
MRXD3
MRXD[3]
Receive data bit 3
MRXD3
MTXD[3]
MRXD2
MRXD[2]
Receive data bit 2
MRXD2
MTXD[2]
MRXD1
MRXD[1]
Receive data bit 1
MRXD1
MTXD[1]
MRXD0
MRXD[0]
Receive data bit 0
MRXD0
MTXD[0]
MRXC
MRXC
Receive clock
MRXC
MRXC
Table 1. MII Signals
This interface is a nibble wide data interface and therefore runs at _ the network bit rate (not encoded). Additional signals on
the transmit side indicate when data is valid or when an error occurs during transmission. Likewise, the receive side has
indicators that convey when the data is valid and without physical layer errors.
For half-duplex operation there is a signal that indicates a collision has occurred during transmission.
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Note that the signal MRXER is not provided on the MII interface for the KS8999 for PHY mode operation and MTXER is not
represented for MAC mode. Normally this would indicate a receive / transmit error coming from the physical layer /MAC device,
but is not appropriate for this configuration. If the connecting device has a MRXER pin, this should be tied low on the other device
for reverse or if it has a MTXER pin in the forward mode it should also be tied low on the other device.
The following explains the KS8999 in PHY mode and MAC mode of operation:
KS8999 PHY Mode
MTXC
External
MAC
Controller
MTXD[3:0]
MTXEN
KS8999
In PHY
mode
MTXER
Figure 3. Data Sent from External MAC Controller to KS8999 PHY Mode
MRXC
External
MAC
Controller
MRXD[3:0]
MRXEN
KS8999
In PHY
Mode
Figure 4. Data Sent from PHY Mode to External MAC Controller
KS8999 MAC Mode
MRXC
KS8999
In MAC
mode
MTXD[3:0]
External
PHY
MTXEN
MTXER
Figure 5. Data Sent from PHY Device to KS8999 MAC Mode
MTXC
KS8999
In MAC
Mode
MRXD[3:0]
External
PHY
MRXDV
Figure 6. Data Sent from KS8999 PHY Mode to External PHY Device
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KS8999
Micrel
SNI Interface (7-wire) Operation
The SNI (Serial Network Interface) is compatible with some controllers used for network layer protocol processing. KS8999
acts like a PHY device to external controllers. This interface can be directly connected to these types of devices. The signals
are divided into two groups, one being for transmission and the other being the receive side. The signals involved are described
in the table below.
SNI Signal
Description
KS8999
SNI Signal
KS8999
Input/Output
TXEN
Transmit enable
MTXEN
Input
TXD
Serial transmit data
MTXD[0]
Input
TXC
Transmit clock
MTXC
Output
COL
Collision detection
MCOL
Output
CRS
Carrier sense
MRXDV
Output
RXD
Serial receive data
MRXD[0]
Output
RXC
Receive clock
MRXC
Output
Table 2. SNI Signals
This interface is a bit wide data interface and therefore runs at the network bit rate (not encoded). An additional signal on the
transmit side indicates when data is valid. Likewise, the receive side has an indicator that conveys when the data is valid.
For half-duplex operation there is a signal that indicate a collision has occurred during transmission.
Programmable Features
Priority Schemes
The KS8999 can determine priority through three different means at the ingress point. The first method is a simple per port
method, the second is via the 802.1p frame tag and the third is by viewing the DSCP (TOS) field in the IPv4 header. Of course
for the priority to be effective, the high and low priority queues must be enabled on the destination port or egress point.
Per Port Method
General priority can be specified on a per port basis. In this type of priority all traffic from the specified input port is considered
high priority in the destination queue. This can be useful in IP phone applications mixed with other data types of traffic where
the IP phone connects to a specific port. The IP phone traffic would be high priority (outbound) to the wide area network. The
inbound traffic to the IP phone is all of the same priority to the IP phone.
802.1p Method
This method works well when used with ports that have mixed data and media flows. The inbound port examines the priority
field in the tag and determines the high or low priority. Priority profiles are setup in the Priority Classification Control in the
EEPROM.
IPv4 DSCP Method
This is another per frame way of determining outbound priority. The DSCP (Differentiated Services Code Point – RFC#2474)
method uses the TOS field in the IP header to determine high and low priority on a per code point basis. Each fully decoded
code point can have either a high or low priority. A larger spectrum of priority flows can be defined with this larger code space.
More specific to implementation, the most significant 6 bits of the TOS field are fully decoded into 64 possibilities, and the
singular code that results is compared against the corresponding bit in the DSCP register. If the register bit is a 1, the priority
is high and if 0, the priority is low.
Other Priority Considerations
When setting up the priority scheme, one should consider other available controls to regulate the traffic. One of these is Priority
Control Scheme (register 2 bits 2-3) which controls the interleaving of high and low priority frames. Options allow from a 2:1
ratio up to a setting that sends all the high priority first. This setting controls all ports globally. Another global feature is Priority
Buffer Reserve (register 2 bit 1). If this is set, there is a 6KB (10%) buffer dedicated to high priority traffic, otherwise if cleared
the buffer is shared between all traffic.
On an individual port basis there are controls that enable DSCP, 802.1p, port based and high/low priority queues. These are
contained in registers 4-12 bits 5-3 and 0. It should be noted that there is a special pin that generally enables the 802.1p priority
for all ports (pin 91). When this pin is active (high) all ports will have the 802.1p priority enabled unless specifically disabled
by EEPROM programming (bit 4 of registers 4-12). Default high priority is a value greater than 4 in the VLAN tag with low priority
being 3 or less.
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The table below briefly summarizes priority features. For more detailed settings see the EEPROM register description.
Register(s)
Bit(s)
Global/Port
Description
General
2
3-2
Global
Priority Control Scheme: Transmit buffer high/low interleave control
2
1
Global
Priority Buffer Reserve: Reserves 6KB of the buffer for high priority traffic
4-12
0
Port
Enable Port Queue Split: Splits the transmit queue on the desired port for high and low
priority traffic
DSCP Priority
4-12
5
Port
Enable Port DSCP: Looks at DSCP field in IP header to decide high or low priority
40-47
7-0
Global
DSCP Priority Points: Fully decoded 64 bit register used to determine priority from
DSCP field (6 bits) in the IP header
802.1p Priority
4-12
4
Port
Enable Port 802.1p Priority: Uses the 802.1p priority tag (3 bits) to determine frame
priority
3
7-0
Global
Priority Classification: Determines which tag values have high priority
Per Port Priority
4-12
3
Port
Enable Port Priority: Determines which ports have high or low priority traffic
Table 3. Priority Control
VLAN Operation
The VLAN’s are setup by programming the VLAN Mask Registers in the EEPROM. The perspective of the VLAN is from the
input port and which output ports it sees directly through the switch. For example if port 1 only participated in a VLAN with ports
2 and 9 then one would set bits 0 and 7 in register 13 (Port 1 VLAN Mask Register). Note that different ports can be setup
independently. An example of this would be where a router is connected to port 9 and each of the other ports would work
autonomously. In this configuration ports 1 through 8 would only set the mask for port 9 and port 9 would set the mask for ports1
through 8. In this way, the router could see all ports and each of the other individual ports would only communicate with the
router.
All multicast and broadcast frames adhere to the VLAN configuration. Unicast frame treatment is a function of register 2 bit
0. If this bit is set then unicast frames only see ports within their VLAN. If this bit is cleared unicast frames can traverse VLAN’s.
VLAN tags can be added or removed on a per port basis. Further, there are provisions to specify the tag value to be inserted
on a per port basis.
The table below briefly summarizes VLAN features. For more detailed settings see the EEPROM register description.
Register(s)
Bit(s)
Global/Port
Description
4-12
2
Port
Insert VLAN Tags: If specified, will add VLAN tags to frames without existing tags
4-12
1
Port
Strip VLAN Tags: If specified, will remove VLAN tags from frames if they exist
2
0
Global
VLAN Enforcement: Allows unicast frames to adhere or ignore the VLAN configuration
13-21
7-0
Port
VLAN Mask Registers: Allows configuration of individual VLAN grouping.
22-39
7-0
Port
VLAN Tag Insertion Values: Specifies the VLAN tag to be inserted if enabled (see above)
Table 4. VLAN Control
Station MAC Address (control frames only)
The MAC source address can be programmed as used in flow control frames. The table below briefly summarizes this
programmable feature.
Register(s)
Bit(s)
Global/Port
Description
48-53
7-0
Global
Station MAC Address: Used as source address for MAC control frames as used in full
duplex flow control mechanisms.
Table 5. Misc. Control
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EEPROM Operation
The EEPROM interface utilizes 2 pins that provide a clock and a serial data path. As part of the initialization sequence, the
KS8999 reads the contents of the EEPROM and loads the values into the appropriate registers. Note that the first two bytes
in the EEPROM must be “55” and “99” respectively for the loading to occur properly. If these first two values are not correct,
all other data will be ignored.
Data start and stop conditions are signaled on the data line as a state transition during clock high time. A high to low transition
indicates start of data and a low to high transition indicates a stop condition. The actual data that traverses the serial line
changes during the clock low time.
The KS8999 EEPROM interface is compatible with the Atmel AT24C01A part. Address A0, A1 and A2 are fixed to 000. Further
timing and data sequences can be found in the Atmel AT24C01A specification.
Optional CPU Interface
Instead of using an EEPROM to program the KS8999, one can use an external processor. To utilize this feature, the CFGMODE
pin (only available on the 208 pin package) needs to pulled low. This makes the KS8999 serial and clock interface into a slave
rather than a master. In this mode, clock and data are sourced from the processor.
Due to timing constraints, the maximum clock speed that the processor can generate is 8MHz. Data timing is referenced to
the rising edge of the clock and are 10ns for setup and 60ns for hold. The processor needs to supply the exact number of clock
cycles and data bits to program the KS8999 properly. KS8999 won’t start until all of the registers are programmed. Bits are
loaded from high order (bit 7) to low order (bit 0) starting with register 0 and finishing with register 53.
Register 0: Skip clock on first bit 7
SCL clock cycle: 7
Register 1 to Register 53: provide clock on bit 7 to bit 0
SCL clock cycle: 424
Total SCL clock cycle: 431
SCL
SDA
B7
B6
B5
B4
B3
B2
B1
B0
B7
B6
B5
B4
B3
Register 1
Register 0
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EEPROM Memory Map
Address
Name
Description
Default
(chip) Value
0
7-0
Signature byte 1. Value = “55”
0x55
1
7-0
Signature byte 2. Value = “99”
0x99
General Control Register
2
7-4
Reserved – set to zero
0000
2
3-2
Priority control scheme (all ports)
00 = Transmit all high priority before any low priority
01= Transmit high and low priority at a 10:1 ratio
10 = Transmit high and low priority at a 5:1 ratio
11 = Transmit high and low priority at a 2:1 ratio
00
2
1
Priority buffer reserve for high priority traffic
1 = Reserve 6KB of buffer space for high priority
0 = None reserved
0
2
0
VLAN enforcement
1 = All unicast frames adhere to VLAN configuration
0 = Unicast frames ignore VLAN configuration
0
Priority Classification Control – 802.1p tag field
3
7
1 = State “111” is high priority
0 = State “111” is low priority
1
3
6
1 = State “110” is high priority
0 = State “110” is low priority
1
3
5
1 = State “101” is high priority
0 = State “101” is low priority
1
3
4
1 = State “100” is high priority
0 = State “100” is low priority
1
3
3
1 = State “011” is high priority
0 = State “011” is low priority
0
3
2
1 = State “010” is high priority
0 = State “010” is low priority
0
3
1
1 = State “001” is high priority
0 = State “001” is low priority
0
3
0
1 = State “000” is high priority
0 = State “000” is low priority
0
Port 1 Control Register
4
7-6
Reserved – set to zero
00
4
5
TOS priority classification enable for port 1
1 = Enable
0 = Disable
0
4
4
802.1p priority classification enable for port 1
1 = Enable
0 = Disable
0
4
3
Port based priority classification for port 1
1 = High priority
0 = Low priority
0
4
2
Insert VLAN tags for port 1 if non-existent
1 = Enable
0 = Disable
0
4
1
Strip VLAN tags for port 1 if existent
1 = Enable
0 = Disable
0
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Address
Name
Description
Default
(chip) Value
4
0
Enable high and low output priority queues for port 1
1 = Enable
0 = Disable
0
Port 2 Control Register
5
7-6
Reserved – set to zero
00
5
5
TOS priority classification enable for port 2
1 = Enable
0 = Disable
0
5
4
802.1p priority classification enable for port 2
1 = Enable
0 = Disable
0
5
3
Port based priority classification for port 2
1 = High priority
0 = Low priority
0
5
2
Insert VLAN tags for port 2 if non-existent
1 = Enable
0 = Disable
0
5
1
Strip VLAN tags for port 2 if existent
1 = Enable
0 = Disable
0
5
0
Enable high and low output priority queues for port 2
1 = Enable
0 = Disable
0
Port 3 Control Register
6
7-6
Reserved – set to zero
00
6
5
TOS priority classification enable for port 3
1 = Enable
0 = Disable
0
6
4
802.1p priority classification enable for port 3
1 = Enable
0 = Disable
0
6
3
Port based priority classification for port 3
1 = High priority
0 = Low priority
0
6
2
Insert VLAN tags for port 3 if non-existent
1 = Enable
0 = Disable
0
6
1
Strip VLAN tags for port 3 if existent
1 = Enable
0 = Disable
0
6
0
Enable high and low output priority queues for port 3
1 = Enable
0 = Disable
0
Port 4 Control Register
7
7-6
Reserved – set to zero
00
7
5
TOS priority classification enable for port 4
1 = Enable
0 = Disable
0
7
4
802.1p priority classification enable for port 4
1 = Enable
0 = Disable
0
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Address
Name
Description
Default
(chip) Value
7
3
Port based priority classification for port 4
1 = High priority
0 = Low priority
0
7
2
Insert VLAN tags for port 4 if non-existent
1 = Enable
0 = Disable
0
7
1
Strip VLAN tags for port 4 if existent
1 = Enable
0 = Disable
0
7
0
Enable high and low output priority queues for port 4
1 = Enable
0 = Disable
0
Port 5 Control Register
8
7-6
Reserved – set to zero
00
8
5
TOS priority classification enable for port 5
1 = Enable
0 = Disable
0
8
4
802.1p priority classification enable for port 5
1 = Enable
0 = Disable
0
8
3
Port based priority classification for port 5
1 = High priority
0 = Low priority
0
8
2
Insert VLAN tags for port 5 if non-existent
1 = Enable
0 = Disable
0
8
1
Strip VLAN tags for port 5 if existent
1 = Enable
0 = Disable
0
8
0
Enable high and low output priority queues for port 5
1 = Enable
0 = Disable
0
Port 6 Control Register
9
7-6
Reserved – set to zero
00
9
5
TOS priority classification enable for port 6
1 = Enable
0 = Disable
0
9
4
802.1p priority classification enable for port 6
1 = Enable
0 = Disable
0
9
3
Port based priority classification for port 6
1 = High priority
0 = Low priority
0
9
2
Insert VLAN tags for port 6 if non-existent
1 = Enable
0 = Disable
0
9
1
Strip VLAN tags for port 6 if existent
1 = Enable
0 = Disable
0
9
0
Enable high and low output priority queues for port 6
1 = Enable
0 = Disable
0
January 2005
31
KS8999
KS8999
Address
Micrel
Name
Description
Default
(chip) Value
Port 7 Control Register
10
7-6
Reserved – set to zero
00
10
5
TOS priority classification enable for port 7
1 = Enable
0 = Disable
0
10
4
802.1p priority classification enable for port 7
1 = Enable
0 = Disable
0
10
3
Port based priority classification for port 7
1 = High priority
0 = Low priority
0
10
2
Insert VLAN tags for port 7 if non-existent
1 = Enable
0 = Disable
0
10
1
Strip VLAN tags for port 7 if existent
1 = Enable
0 = Disable
0
10
0
Enable high and low output priority queues for port 7
1 = Enable
0 = Disable
0
Port 8 Control Register
11
7-6
Reserved – set to zero
00
11
5
TOS priority classification enable for port 8
1 = Enable
0 = Disable
0
11
4
802.1p priority classification enable for port 8
1 = Enable
0 = Disable
0
11
3
Port based priority classification for port 8
1 = High priority
0 = Low priority
0
11
2
Insert VLAN tags for port 8 if non-existent
1 = Enable
0 = Disable
0
11
1
Strip VLAN tags for port 8 if existent
1 = Enable
0 = Disable
0
11
0
Enable high and low output priority queues for port 8
1 = Enable
0 = Disable
0
Port 9 Control Register
12
7-6
Reserved – set to zero
00
12
5
TOS priority classification enable for port 9
1 = Enable
0 = Disable
0
12
4
802.1p priority classification enable for port 9
1 = Enable
0 = Disable
0
12
3
Port based priority classification for port 9
1 = High priority
0 = Low priority
0
KS8999
32
January 2005
KS8999
Micrel
Address
Name
Description
Default
(chip) Value
12
2
Insert VLAN tags for port 9 if non-existent
1 = Enable
0 = Disable
0
12
1
Strip VLAN tags for port 9 if existent
1 = Enable
0 = Disable
0
12
0
Enable high and low output priority queues for port 9
1 = Enable
0 = Disable
0
Port 1 VLAN Mask Register
13
7
Port 9 inclusion
1 = Port 9 in the same VLAN as port 1
0 = Port 9 not in the same VLAN as port 1
1
13
6
Port 8 inclusion
1 = Port 8 in the same VLAN as port 1
0 = Port 8 not in the same VLAN as port 1
1
13
5
Port 7 inclusion
1 = Port 7 in the same VLAN as port 1
0 = Port 7 not in the same VLAN as port 1
1
13
4
Port 6 inclusion
1 = Port 6 in the same VLAN as port 1
0 = Port 6 not in the same VLAN as port 1
1
13
3
Port 5 inclusion
1 = Port 5 in the same VLAN as port 1
0 = Port 5 not in the same VLAN as port 1
1
13
2
Port 4 inclusion
1 = Port 4 in the same VLAN as port 1
0 = Port 4 not in the same VLAN as port 1
1
13
1
Port 3 inclusion
1 = Port 3 in the same VLAN as port 1
0 = Port 3 not in the same VLAN as port 1
1
13
0
Port 2 inclusion
1 = Port 2 in the same VLAN as port 1
0 = Port 2 not in the same VLAN as port 1
1
Port 2 VLAN Mask Register
14
7
Port 9 inclusion
1 = Port 9 in the same VLAN as port 2
0 = Port 9 not in the same VLAN as port 2
1
14
6
Port 8 inclusion
1 = Port 8 in the same VLAN as port 2
0 = Port 8 not in the same VLAN as port 2
1
14
5
Port 7 inclusion
1 = Port 7 in the same VLAN as port 2
0 = Port 7 not in the same VLAN as port 2
1
14
4
Port 6 inclusion
1 = Port 6 in the same VLAN as port 2
0 = Port 6 not in the same VLAN as port 2
1
14
3
Port 5 inclusion
1 = Port 5 in the same VLAN as port 2
0 = Port 5 not in the same VLAN as port 2
1
14
2
Port 4 inclusion
1 = Port 4 in the same VLAN as port 2
0 = Port 4 not in the same VLAN as port 2
1
January 2005
33
KS8999
KS8999
Micrel
Address
Name
Description
Default
(chip) Value
14
1
Port 3 inclusion
1 = Port 3 in the same VLAN as port 2
0 = Port 3 not in the same VLAN as port 2
1
14
0
Port 1 inclusion
1 = Port 1 in the same VLAN as port 2
0 = Port 1 not in the same VLAN as port 2
1
Port 3 VLAN Mask Register
15
7
Port 9 inclusion
1 = Port 9 in the same VLAN as port 3
0 = Port 9 not in the same VLAN as port 3
1
15
6
Port 8 inclusion
1 = Port 8 in the same VLAN as port 3
0 = Port 8 not in the same VLAN as port 3
1
15
5
Port 7 inclusion
1 = Port 7 in the same VLAN as port 3
0 = Port 7 not in the same VLAN as port 3
1
15
4
Port 6 inclusion
1 = Port 6 in the same VLAN as port 3
0 = Port 6 not in the same VLAN as port 3
1
15
3
Port 5 inclusion
1 = Port 5 in the same VLAN as port 3
0 = Port 5 not in the same VLAN as port 3
1
15
2
Port 4 inclusion
1 = Port 4 in the same VLAN as port 3
0 = Port 4 not in the same VLAN as port 3
1
15
1
Port 2 inclusion
1 = Port 2 in the same VLAN as port 3
0 = Port 2 not in the same VLAN as port 3
1
15
0
Port 1 inclusion
1 = Port 1 in the same VLAN as port 3
0 = Port 1 not in the same VLAN as port 3
1
Port 4 VLAN Mask Register
16
7
Port 9 inclusion
1 = Port 9 in the same VLAN as port 4
0 = Port 9 not in the same VLAN as port 4
1
16
6
Port 8 inclusion
1 = Port 8 in the same VLAN as port 4
0 = Port 8 not in the same VLAN as port 4
1
16
5
Port 7 inclusion
1 = Port 7 in the same VLAN as port 4
0 = Port 7 not in the same VLAN as port 4
1
16
4
Port 6 inclusion
1 = Port 6 in the same VLAN as port 4
0 = Port 6 not in the same VLAN as port 4
1
16
3
Port 5 inclusion
1 = Port 5 in the same VLAN as port 4
0 = Port 5 not in the same VLAN as port 4
1
16
2
Port 3 inclusion
1 = Port 3 in the same VLAN as port 4
0 = Port 3 not in the same VLAN as port 4
1
16
1
Port 2 inclusion
1 = Port 2 in the same VLAN as port 4
0 = Port 2 not in the same VLAN as port 4
1
KS8999
34
January 2005
KS8999
Micrel
Address
Name
Description
Default
(chip) Value
16
0
Port 1 inclusion
1 = Port 1 in the same VLAN as port 4
0 = Port 1 not in the same VLAN as port 4
1
Port 5 VLAN Mask Register
17
7
Port 9 inclusion
1 = Port 9 in the same VLAN as port 5
0 = Port 9 not in the same VLAN as port 5
1
17
6
Port 8 inclusion
1 = Port 8 in the same VLAN as port 5
0 = Port 8 not in the same VLAN as port 5
1
17
5
Port 7 inclusion
1 = Port 7 in the same VLAN as port 5
0 = Port 7 not in the same VLAN as port 5
1
17
4
Port 6 inclusion
1 = Port 6 in the same VLAN as port 5
0 = Port 6 not in the same VLAN as port 5
1
17
3
Port 4 inclusion
1 = Port 4 in the same VLAN as port 5
0 = Port 4 not in the same VLAN as port 5
1
17
2
Port 3 inclusion
1 = Port 3 in the same VLAN as port 5
0 = Port 3 not in the same VLAN as port 5
1
17
1
Port 2 inclusion
1 = Port 2 in the same VLAN as port 5
0 = Port 2 not in the same VLAN as port 5
1
17
0
Port 1 inclusion
1 = Port 1 in the same VLAN as port 5
0 = Port 1 not in the same VLAN as port 5
1
Port 6 VLAN Mask Register
18
7
Port 9 inclusion
1 = Port 9 in the same VLAN as port 6
0 = Port 9 not in the same VLAN as port 6
1
18
6
Port 8 inclusion
1 = Port 8 in the same VLAN as port 6
0 = Port 8 not in the same VLAN as port 6
1
18
5
Port 7 inclusion
1 = Port 7 in the same VLAN as port 6
0 = Port 7 not in the same VLAN as port 6
1
18
4
Port 5 inclusion
1 = Port 5 in the same VLAN as port 6
0 = Port 5 not in the same VLAN as port 6
1
18
3
Port 4 inclusion
1 = Port 4 in the same VLAN as port 6
0 = Port 4 not in the same VLAN as port 6
1
18
2
Port 3 inclusion
1 = Port 3 in the same VLAN as port 6
0 = Port 3 not in the same VLAN as port 6
1
18
1
Port 2 inclusion
1 = Port 2 in the same VLAN as port 6
0 = Port 2 not in the same VLAN as port 6
1
18
0
Port 1 inclusion
1 = Port 1 in the same VLAN as port 6
0 = Port 1 not in the same VLAN as port 6
1
January 2005
35
KS8999
KS8999
Address
Micrel
Name
Description
Default
(chip) Value
Port 7 VLAN Mask Register
19
7
Port 9 inclusion
1 = Port 9 in the same VLAN as port 7
0 = Port 9 not in the same VLAN as port 7
1
19
6
Port 8 inclusion
1 = Port 8 in the same VLAN as port 7
0 = Port 8 not in the same VLAN as port 7
1
19
5
Port 6 inclusion
1 = Port 6 in the same VLAN as port 7
0 = Port 6 not in the same VLAN as port 7
1
19
4
Port 5 inclusion
1 = Port 5 in the same VLAN as port 7
0 = Port 5 not in the same VLAN as port 7
1
19
3
Port 4 inclusion
1 = Port 4 in the same VLAN as port 7
0 = Port 4 not in the same VLAN as port 7
1
19
2
Port 3 inclusion
1 = Port 3 in the same VLAN as port 7
0 = Port 3 not in the same VLAN as port 7
1
19
1
Port 2 inclusion
1 = Port 2 in the same VLAN as port 7
0 = Port 2 not in the same VLAN as port 7
1
19
0
Port 1 inclusion
1 = Port 1 in the same VLAN as port 7
0 = Port 1 not in the same VLAN as port 7
1
Port 8 VLAN Mask Register
20
7
Port 9 inclusion
1 = Port 9 in the same VLAN as port 8
0 = Port 9 not in the same VLAN as port 8
1
20
6
Port 7 inclusion
1 = Port 7 in the same VLAN as port 8
0 = Port 7 not in the same VLAN as port 8
1
20
5
Port 6 inclusion
1 = Port 6 in the same VLAN as port 8
0 = Port 6 not in the same VLAN as port 8
1
20
4
Port 5 inclusion
1 = Port 5 in the same VLAN as port 8
0 = Port 5 not in the same VLAN as port 8
1
20
3
Port 4 inclusion
1 = Port 4 in the same VLAN as port 8
0 = Port 4 not in the same VLAN as port 8
1
20
2
Port 3 inclusion
1 = Port 3 in the same VLAN as port 8
0 = Port 3 not in the same VLAN as port 8
1
20
1
Port 2 inclusion
1 = Port 2 in the same VLAN as port 8
0 = Port 2 not in the same VLAN as port 8
1
20
0
Port 1 inclusion
1 = Port 1 in the same VLAN as port 8
0 = Port 1 not in the same VLAN as port 8
1
KS8999
36
January 2005
KS8999
Address
Micrel
Name
Description
Default
(chip) Value
Port 9 VLAN Mask Register
21
7
Port 8 inclusion
1 = Port 8 in the same VLAN as port 9
0 = Port 8 not in the same VLAN as port 9
1
21
6
Port 7 inclusion
1 = Port 7 in the same VLAN as port 9
0 = Port 7 not in the same VLAN as port 9
1
21
5
Port 6 inclusion
1 = Port 6 in the same VLAN as port 9
0 = Port 6 not in the same VLAN as port 9
1
21
4
Port 5 inclusion
1 = Port 5 in the same VLAN as port 9
0 = Port 5 not in the same VLAN as port 9
1
21
3
Port 4 inclusion
1 = Port 4 in the same VLAN as port 9
0 = Port 4 not in the same VLAN as port 9
1
21
2
Port 3 inclusion
1 = Port 3 in the same VLAN as port 9
0 = Port 3 not in the same VLAN as port 9
1
21
1
Port 2 inclusion
1 = Port 2 in the same VLAN as port 9
0 = Port 2 not in the same VLAN as port 9
1
21
0
Port 1 inclusion
1 = Port 1 in the same VLAN as port 9
0 = Port 1 not in the same VLAN as port 9
1
Port 1 VLAN Tag Insertion Value Registers
22
7-5
User priority [2:0]
000
22
4
CFI
0
22
3-0
VID [11:8]
0x0
23
7-0
VID [7:0]
0x00
Port 2 VLAN Tag Insertion Value Registers
24
7-5
User priority [2:0]
000
24
4
CFI
0
24
3-0
VID [11:8]
0x0
25
7-0
VID [7:0]
0x00
Port 3 VLAN Tag Insertion Value Registers
26
7-5
User priority [2:0]
000
26
4
CFI
0
26
3-0
VID [11:8]
0x0
27
7-0
VID [7:0]
0x00
Port 4 VLAN Tag Insertion Value Registers
28
7-5
User priority [2:0]
000
28
4
CFI
0
28
3-0
VID [11:8]
0x0
29
7-0
VID [7:0]
0x00
January 2005
37
KS8999
KS8999
Micrel
Address
Name
Description
Default
(chip) Value
Port 5 VLAN Tag Insertion Value Registers
30
7-5
User priority [2:0]
000
30
4
CFI
0
30
3-0
VID [11:8]
0x0
31
7-0
VID [7:0]
0x00
Port 6 VLAN Tag Insertion Value Registers
32
7-5
User priority [2:0]
000
32
4
CFI
0
32
3-0
VID [11:8]
0x0
33
7-0
VID [7:0]
0x00
Port 7 VLAN Tag Insertion Value Registers
34
7-5
User priority [2:0]
000
34
4
CFI
0
34
3-0
VID [11:8]
0x0
35
7-0
VID [7:0]
0x00
Port 8 VLAN Tag Insertion Value Registers
36
7-5
User priority [2:0]
000
36
4
CFI
0
36
3-0
VID [11:8]
0x0
37
7-0
VID [7:0]
0x00
Port 9 VLAN Tag Insertion Value Registers
38
7-5
User priority [2:0]
000
38
4
CFI
0
38
3-0
VID [11:8]
0x0
39
7-0
VID [7:0]
0x00
Diff Serv Code Point Registers
40
7-0
DSCP[63:56]
0x00
41
7-0
DSCP[55:48]
0x00
42
7-0
DSCP[47:40]
0x00
43
7-0
DSCP[39:32]
0x00
44
7-0
DSCP[31:24]
0x00
45
7-0
DSCP[23:16]
0x00
46
7-0
DSCP[15:8]
0x00
47
7-0
DSCP[7:0]
0x00
Station MAC Address Registers (all ports – MAC control frames only)
48
7-0
MAC address [47:40]
0x00
49
7-0
MAC address [39:32]
0x40
50
7-0
MAC address [31:24]
0x05
51
7-0
MAC address [23:16]
0x43
52
7-0
MAC address [15:8]
0x5E
53
7-0
MAC address [7:0]
0xFE
Note:
KS8999
The MAC address is reset to the value in the above table, but can set to any value via the EEPROM interface. This MAC address is used as
the source address in MAC control frames that execute flow control between link peers.
38
January 2005
KS8999
Micrel
Absolute Maximum Ratings (Note 1)
Operating Ratings (Note 2)
Supply Voltage
(VDD_RX, VDD_TX, VDD_RCV, VDD,
VDD_PLLTX) .............................................. –0.5V to +2.3V
(VDDIO) .................................................... –0.5V to +3.8V
Input Voltage ............................................... –0.5V to +4.0V
Output Voltage ............................................ –0.5V to +4.0V
Lead Temperature (soldering, 10 sec.) ..................... 270°C
Storage Temperature (TS) ....................... –55°C to +150°C
Supply Voltage
(VDD_RX, VDD_TX, VDD_RCV, VDD,
VDD_PLLTX) .............................................. +2.0V to +2.3V
(VDDIO) ....................... +2.0V to +2.3V or +3.0V to +3.6V
Ambient Temperature (TA)
Commercial .............................................. –0°C to +70°C
Industrial ................................................. –40°C to +85°C
Package Thermal Resistance, (Note 3)
PQFP (θJA) No Air Flow ................................... 39.1°C/W
Electrical Characteristics (KS8999) (Note 4)
VDD = 2.0V to 2.3V; TA = 0°C to +70°; unless noted.
Symbol
Parameter
VDD
Supply Voltage
Condition
Min
Typ
Max
Units
2.00
2.10
2.30
V
100BaseTX Operation—Total
0.64
0.85
A
IDX
100BaseTX (Transmitter)
0.35
0.40
A
IDA
100BaseTX (Analog)
0.18
0.25
A
IDD
100BaseTX (Digital)
0.11
0.20
A
10BaseT Operation—Total
1.04
1.32
A
IDX
100BaseTX (Transmitter)
0.84
0.95
A
IDA
100BaseTX (Analog)
0.11
0.17
A
IDD
100BaseTX (Digital)
0.09
0.20
A
Supply Current (including TX output driver current)
TTL Inputs
VIH
Input High Voltage
VIL
Input Low Voltage
IIN
Input Current
VIN = GND ~ VDD
VOH
Output High Voltage
IOH = –4mA
VOL
Output Low Voltage
IOL = 4mA
|IOZ|
Output Tri-State Leakage
(1/2 VDDIO)
+0.4
–10
V
(1/2 VDDIO)
–0.4
V
10
µA
TTL Outputs
VDDIO
–0.4
V
+0.4
V
10
µA
1.05
V
2
%
100BaseTX Transmit (measured differentially after 1:1 transformer)
VO
Peak Differential Output Voltage
50Ω from each output to VDD
0.95
VIMB
Output Voltage Imbalance
50Ω from each output to VDD
tr, tt
Rise/Fall Time
3
5
ns
Rise/Fall Time Imbalance
0
0.5
ns
Note 1.
Exceeding the absolute maximum rating may damage the device.
Note 2.
The device is not guaranteed to function outside its operating rating. Unused inputs must always be tied to an appropriate logic voltage level
(Ground to VDD).
Note 3.
No HS (heat spreader) in package.
Note 4.
Specification for packaged product only.
January 2005
39
KS8999
KS8999
Symbol
Micrel
Parameter
Condition
Min
Typ
Max
Units
±0.5
ns
5
%
100BaseTX Transmit (measured differentially after 1:1 transformer)
Duty Cycle Distortion
Overshoot
VSET
Reference Voltage of ISET
Output Jitters
0.75
V
Peak-to-peak
0.7
1.4
ns
5MHz square wave
400
mV
2.3
V
10BaseTX Receive
VSQ
Squelch Threshold
10BaseT Transmit (measured differentially after 1:1 transformer)
VP
Peak Differential Output Voltage
50Ω from each output to VDD
Jitters Added
50Ω from each output to VDD
Rise/Fall Times
KS8999
±3.5
28
40
ns
ns
January 2005
KS8999
Micrel
Timing Diagrams
tcyc
SCL
ts
th
SDA
Figure 7. EEPROM Input Timing
Symbol
Parameter
Min
Typ
Max
tCYC
Clock Cycle
tS
Set-Up Time
20
ns
tH
Hold Time
20
ns
16384
Units
ns
Table 5. EEPROM Input Timing Parameters
tcyc
SCL
tov
SDA
Figure 8. EEPROM Output Timing
Symbol
Parameter
tCYC
Clock Cycle
tOV
Output Valid
Min
Typ
Max
16384
4096
4112
Units
ns
4128
ns
Table 6. EEPROM Output Timing Parameters
January 2005
41
KS8999
KS8999
Micrel
tcyc
MTXC
ts
th
MTXD[0],
MTXEN
Figure 9. SNI (7-wire) Input Timing
Symbol
Parameter
Min
Typ
Max
tCYC
Clock Cycle
tS
Set-Up Time
10
ns
tH
Hold Time
0
ns
100
Units
ns
Table 7. SNI (7-wire) Input Parameters
tcyc
MRXC
tov
MRXD[0],
MRXDV,
MCOL
Figure 10. SNI (7-wire) Output Timing
Symbol
Parameter
tCYC
Clock Cycle
tOV
Output Valid
Min
Typ
Max
100
0
3
Units
ns
6
ns
Table 8. SNI (7-wire) Output Timing Parameters
KS8999
42
January 2005
KS8999
Micrel
MTXC
External
MAC
Controller
MTXD[3:0]
MTXEN
KS8999
In PHY
mode
MTXER
Figure 11. KS8999 PHY Mode—Data Sent from External MAC Controller to KS8999
tcyc
MTXCLK
ts
th
MTXD[3:0]
MTXEN
MTXER
Figure 12. KS8999 PHY Mode Receive Timing
Symbol
Parameter
Min
Typ
Max
Units
tCYC
Clock Cycle
(100BaseT)
40
ns
tCYC
Clock Cycle
(10BaseT)
400
ns
tS
Set-Up Time
10
ns
tH
Hold Time
0
ns
Table 9. MII Timing in KS8999 PHY and MAC Mode Timing Parameters
January 2005
43
KS8999
KS8999
Micrel
MRXC
External
MAC
Controller
MRXD[3:0]
MRXEN
KS8999
In PHY
Mode
Figure 13. KS8999 PHY Mode—Data Sent from KS8999 PHY Mode to External MAC Controller
tcyc
MRXCLK
tov
MRXD[3:0]
MRXDV
Figure 14. KS8999 PHY Mode Transmit Timing
Symbol
Parameter
Min
tCYC
Clock Cycle
(100BaseT)
40
ns
tCYC
Clock Cycle
(10BaseT)
400
ns
tOV
Output Valid
18
Typ
25
Max
28
Units
ns
Table 10. KS8999 PHY Mode Transmit Timing Parameters
KS8999
44
January 2005
KS8999
Micrel
MRXC
KS8999
In MAC
Mode
External
PHY
MTXD[3:0]
MTXEN
MTXER
Figure 15. KS8999 MAC Mode—Data Sent from External PHY Device to KS8999
tcyc
MRXCLK
ts
th
MTXD[3:0]
MTXEN
MTXER
Figure 16. KS8999 MAC Mode Receive Timing
Symbol
Parameter
Min
Typ
Max
Units
tCYC
Clock Cycle
(100BaseT)
40
ns
tCYC
Clock Cycle
(10BaseT)
400
ns
tS
Output Valid
10
ns
tH
Output Valid
5
ns
Table 11. KS8999 PHY Mode Transmit Timing Parameters
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KS8999
KS8999
Micrel
MTXC
KS8999
In MAC
Mode
MRXD[3:0]
External
PHY
MRXDV
Figure 17. KS8999 MAC Mode Timing—Data Sent from KS8999 MAC mode to External PHY Device
tcyc
MTXCLK
tov
MRXD[3:0]
MRXDV
Figure 18. KS8999 MAC Mode Transmit Timing
Symbol
Parameter
Min
tCYC
Clock Cycle
(100BaseT)
40
ns
tCYC
Clock Cycle
(10BaseT)
400
ns
tOV
Output Valid
7
Typ
11
Max
16
Units
ns
Table 12. KS8999 MAC Mode Transmit Timing Parameters
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Micrel
Reference Circuits
See “I/O Description” section for pull-up/pull-down and float information.
VDD-IO
220Ω
Pull -up
10k
LED pin
KS8999
VDD-IO
220Ω
Float
LED pin
KS8999
VDD-IO
Pull Down
220Ω
Pull-down
LED pin
KS8999
1k
Reference circuits for unmanaged programming through LED ports
Note: For brighter LED operation use VDD-IO = 3.3V
Figure 19. Unmanaged Programming Circuit
Reset Reference Circuit
Micrel recommendeds the following discrete reset circuit as shown in Figure 20 when powering up the KS8999 device. For
the application where the reset circuit signal comes from another device (e.g., CPU, FPGA, etc), we recommend the reset circuit
as shown in Figure 21.
VCC
R
10k
D1
KS8999
CPU/FPGA
RST
RST_OUT_n
D2
C
10µF
D1, D2: 1N4148
Figure 20. Recommended Reset Circuit.
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KS8999
KS8999
Micrel
VCC
D1: 1N4148
R
10k
D1
KS8995X
RST
C
10µF
Figure 21. Recommended Circuit for Interfacing with CPU/FPGA Reset
At power-on-reset, R, C, and D1 provide the necessary ramp rise time to reset the KS8999 device. The reset out from CPU/
FPGA provides warm reset after power up. It is also recommended to power up the VDD core voltage earlier than VDDIO
voltage. At worst case, the both VDD core and VDDIO voltages should come up at the same time.
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Micrel
4B/5B Coding
In 100BaseTX and 100BaseFX the data and frame control are encoded in the transmitter (and decoded in the receiver) using
a 4B/5B code. The extra code space is required to encode extra control (frame delineation) points. It is also used to reduce
run length as well as supply sufficient transitions for clock recovery. The table below provides the translation for the 4B/5B
coding.
Code Type
4B Code
5B Code
Value
Data
0000
11110
Data value 0
0001
01001
Data value 1
0010
10100
Data value 2
0011
10101
Data value 3
0100
01010
Data value 4
0101
01011
Data value 5
0110
01110
Data value 6
0111
01111
Data value 7
1000
10010
Data value 8
1001
10011
Data value 9
1010
10110
Data value A
1011
10111
Data value B
1100
11010
Data value C
1101
11011
Data value D
1110
11100
Data value E
1111
11101
Data value F
Not defined
11111
Idle
0101
11000
Start delimiter part 1
0101
10001
Start delimiter part 2
Not defined
01101
End delimiter part 1
Not defined
00111
End delimiter part 2
Not defined
00100
Transmit error
Not defined
00000
Invalid code
Not defined
00001
Invalid code
Not defined
00010
Invalid code
Not defined
00011
Invalid code
Not defined
00101
Invalid code
Not defined
00110
Invalid code
Not defined
01000
Invalid code
Not defined
01100
Invalid code
Not defined
10000
Invalid code
Not defined
11001
Invalid code
Control
Invalid
Table 13. 4B/5B Coding
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Micrel
MLT3 Coding
For 100BaseTX operation the NRZI (Non-Return to Zero Invert on ones) signal is line coded as MLT3. The net result of using
MLT3 is to reduce the EMI (Electro Magnetic Interference) of the signal over twisted pair media. In NRZI coding, the level
changes from high to low or low to high for every “1” bit. For a “0” bit there is no transition. MLT3 line coding transitions through
three distinct levels. For every transition of the NRZI signal the MLT3 signal either increments or decrements depending on
the current state of the signal. For instance if the MLT3 level is at its lowest point the next two NRZI transitions will change the
MLT3 signal initially to the middle level followed by the highest level (second NRZI transition). On the next NRZI change, the
MLT3 level will decrease to the middle level. On the following transition of the NRZI signal the MLT3 level will move to the lowest
level where the cycle repeats. The diagram below describes the level changes. Note that in the actual 100BaseTX circuit there
is a scrambling circuit and that scrambling is not shown in this diagram.
Hex Value
A
3
8
E
9
4
T3
R3
I1
I1
Binary 4B
1010 0011 1000 1110 1001 0100 UUUU UUUU UUUU UUUU
Binary 5B
10110101011001011100100110101001101001111111111111
NRZ
NRZI
MLT3
Figure 20. MLT3 coding
MAC Frame
The MAC (Media Access Control) fields are described in the table below.
Field
Octect Length
Description
Preamble/SFD
8
Preamble and Start of Frame Delimiter
DA
6
48-bit Destination MAC Address
SA
6
48-bit Source MAC Address
Length
2
Frame Length
Protocol/Data
46 to 1500
Higher Layer Protocol and Frame Data
Frame CRC
4
32-bit Cyclical Redundancy Check
ESD
1
End of Stream Delimiter
Idle
Variable
Inter Frame Idles
Table 14. MAC Frame
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Micrel
Selection of Isolation Transformer(Note 1)
One simple 1:1 isolation transformer is needed at the line interface. An isolation transformer with integrated common-mode
choke is recommended for exceeding FCC requirements. The following table gives recommended transformer characteristics.
Characteristics Name
Value
Turns Ratio
1 CT : 1 CT
Open-Circuit Inductance (min.)
350µH
100mV, 100 KHz, 8mA
Leakage Inductance (max.)
0.4µH
1MHz (min.)
Inter-Winding Capacitance (max.)
12pF
D.C. Resistance (max.)
0.9Ω
Insertion Loss (max.)
1.0dB
HIPOT (min.)
1500Vrms
Note 1.
Test Condition
0MHz to 65MHz
The IEEE 802.3u standard for 100BaseTX assumes a transformer loss of 0.5dB. For the transmit line transformer, insertion loss of up to
1.3dB can be compensated by increasing the line drive current by means of reducing the ISET resistor value.
Selection of Reference Oscillator/Crystal
An oscillator or crystal with the following typical characteristics is recommended.
Characteristics Name
Value
Test Condition
Frequency
25.00000
MHz
Maximum Frequency Tolerance
±50
ppm
Maximum Jitter
150
ps(pk-pk)
The following transformer vendors provide compatible magnetic parts for Micrel’s device:
4-Port Integrated
Vendor
Part
Auto
MDIX
Number
of Port
Vendor
Single Port
Part
Auto
MDIX
Number
of Port
Pulse
H1164
Yes
4
Pulse
H1102
Yes
1
Bel Fuse
558-5999-Q9
Yes
4
Bel Fuse
S558-5999-U7
Yes
1
YCL
PH406466
Yes
4
YCL
PT163020
Yes
1
Transpower
HB826-2
Yes
4
Transpower
HB726
Yes
1
Delta
LF8731
Yes
4
Delta
LF8505
Yes
1
Table 15. Qualified Magnetics Vendor Lists
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KS8999
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Package Information
208-Pin PQFP (PQ)
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131
TEL
+ 1 (408) 944-0800
FAX
+ 1 (408) 474-1000
WEB
USA
http://www.micrel.com
The information furnished by Micrel in this datasheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its use.
Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can
reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into
the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser’s
use or sale of Micrel Products for use in life support appliances, devices or systems is at Purchaser’s own risk and Purchaser agrees to fully indemnify
Micrel for any damages resulting from such use or sale.
© 2005 Micrel, Incorporated.
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