GX3190 146 x 290 3.5Gb/s Crosspoint Switch with Trace Equalization and Output De-emphasis Key Features
Description
•
The GX3190 is a low-power, high-speed 146 x 290 crosspoint switch, with robust signal conditioning circuits for driving and receiving high-speed signals through backplanes.
• • • • • • • • • • • • • •
146 x 290 crosspoint switch architecture supporting broadcast and multi-cast modes Supports all data rates up to 3.5Gb/s Low power consumption: 31.51W typical (all channels active) Sophisticated, dynamic on-chip power management control Independent, programmable input trace equalization to reduce deterministic jitter (ISI) Independent, programmable output de-emphasis for driving long board traces High-speed, video-optimized control for multi-format applications Built-in system test features with on-chip PRBS generators and analyzers 2.5V analog core voltage, 1.8V digital core voltage Input and output voltages support either 1.2V, 1.8V or 2.5V CML JTAG-controlled boundary scan Selectable parallel/serial host interface 50mm x 50mm BGA (2377 ball) Operating temperature range: 0°C to +85°C RoHS compliant
Applications Large m x n cascaded routers/switch fabrics for: • • • •
Professional broadcast applications Enterprise and carrier applications High-speed automated test equipment 10GbE and InfiniBand networks
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
The device typically consumes 31.51W of power with all channels operational, and features sophisticated, dynamically scalable power management. Unused portions of the core are automatically turned off without affecting the operation of the remaining channels. The signal conditioning features of the GX3190 include per-input programmable equalization and per-output programmable de-emphasis. The input equalizer removes ISI jitter—typically caused by PCB trace losses—by opening the input data eye in applications where long PCB traces are used. There are four settings available for the input equalizer, allowing flexibility in adjusting the equalization level on a per-input basis. Output de-emphasis capability provides a boost of the high-frequency content of the output signal, such that the data eye remains open after passing through a long interconnect of PCB traces and connectors. There are four de-emphasis settings that can be enabled on a per-output basis. Two integrated programmable pattern generators, and two pattern checkers are provided to assist in system test and configuration. The pattern generators can each be routed to any output of the device without impacting the normal operation of any other channel. Any input can be routed to each of the pattern checkers. The chip features eight independent strobe inputs, UPDATE_EN[7:0], which are used to determine the timing of the output updates. Any output can be linked to any strobe.
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TDI TMS
TCK TDO
JTAG and Boundary Scan
SDIN
HOST_S/P RESET
S_CS
SCLK
SDOUT
P_DAT [15:0] P_ADD P_R/W [11:0]
P_ADS P_CS
Parallel/Serial Interfaces and General Registers
Input Configuration Latch Active Configuration Latch
UPDATE_EN[7:0]
Trace EQ
SDI[0]/SDI[0]
Output 0
Input 0
Trace EQ
SDI[287]/SDI[287]
Input 143 EXT_PG0/EXT_PG0
EXT_PG1/EXT_PG1
SDO[0]/SDO[0]
De-Emp
146 x 290 Differential Cross-point Switch Matrix
SDO[287]/SDO[287]
De-Emp
Output 287
Trace EQ
De-Emp
Input 144
Output 288
Trace EQ
De-Emp
Input 145
Output 289
Programmable Pattern Generator 1
Pattern Checker & Status Monitor 1
Programmable Pattern Generator 0
Pattern Checker & Status Monitor 0
MON0/MON0
MON1/MON1
Reference Clock/Crystal Buffer
REF_CLK_IN
REF_CLK_OUT
GX3190 Functional Block Diagram
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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Revision History
Version
ECO
PCN
Date
2
011798
–
March 2013
Corrected second bullet in Section 4.7.1, and added a note in Section 4.4. Included ESD Voltage Sensitivity in Table 2-1. Modifications to Table 4-18 and Section 4.12.2 to include Auto-Increment Timing and functionality. Updates to Appendix - Relevant Documentation with clear reference to correct documents. Converted document to Data Sheet.
1
158397
–
October 2012
0
157405
–
March 2012
A
157287
–
November 2011
Changes and/or Modifications
Converted document to Preliminary Data Sheet. Updates throughout. New document.
Contents Key Features ........................................................................................................................................................1 Applications.........................................................................................................................................................1 Description...........................................................................................................................................................1 Revision History .................................................................................................................................................3 1. Ball Out .............................................................................................................................................................5 1.1 Ball Assignment ................................................................................................................................5 1.2 Ball Descriptions ...............................................................................................................................6 2. Electrical Characteristics ............................................................................................................................9 2.1 Absolute Maximum Ratings ..........................................................................................................9 2.2 Recommended Operating Conditions .................................................................................... 10 2.3 DC Electrical Characteristics ..................................................................................................... 11 2.4 AC Electrical Characteristics ..................................................................................................... 15 3. Input/Output Equivalent Circuits ......................................................................................................... 17 4. Detailed Description.................................................................................................................................. 20 4.1 Serial Data Input ............................................................................................................................ 20 4.2 Serial Data Output ......................................................................................................................... 21 4.3 Crosspoint Switch Matrix Operation ...................................................................................... 23 4.4 Propagation Delay ......................................................................................................................... 24 4.5 Using Multiple Strobes ................................................................................................................. 24 4.6 Pattern Generator and Pattern Checker ................................................................................ 25 4.6.1 Pattern Generator.............................................................................................................. 25 4.6.2 Pattern Checker.................................................................................................................. 26 4.7 Horizontal Eye Measurement .................................................................................................... 30 4.7.1 Configuration for Horizontal Eye Measurement .................................................... 30 4.8 Temperature Sensors .................................................................................................................... 30 4.9 27MHz Reference Clock .............................................................................................................. 33
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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4.10 Device Power-Up ........................................................................................................................ 33 4.11 Device Reset .................................................................................................................................. 34 4.12 Host Interface ............................................................................................................................... 34 4.12.1 Parallel Host Interface Specifications ...................................................................... 34 4.12.2 Serial Host Interface Specifications .......................................................................... 39 5. Application Information .......................................................................................................................... 41 5.1 Power Supply Filtering and Recommendations .................................................................. 41 5.2 Estimated Worst-Case Load Current Steps ........................................................................... 42 5.2.1 VCC_25_A Supply............................................................................................................. 42 5.2.2 VCC_OUT1, VCC_OUT2 Supplies ................................................................................ 42 5.2.3 VCC_IN1, VCC_IN2 Supplies......................................................................................... 43 6. Package and Ordering Information...................................................................................................... 44 6.1 Package Dimensions ..................................................................................................................... 44 6.2 Package Thermal Data and Information ................................................................................ 45 6.3 Marking Diagram ........................................................................................................................... 45 6.4 Solder Reflow Profile .................................................................................................................... 46 6.5 Ordering Information ................................................................................................................... 46 Appendix - Relevant Documentation...................................................................................................... 46
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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1. Ball Out 1.1 Ball Assignment A
1
2
3
4
5
6
7
8
9
13
14
29
30
33
34
37
38
48
49
NC
NC
NC
GND
SDO_ 268
SDO_ 268
SDO_ 244
SDO_ 244
SDO_ 264
SDO_ 264
SDO_ 248
SDO_ 248
SDO_ 228
SDO_ 228
GND
SDO_ 208
SDO_ 208
SDO_ 192
SDO_ SDO_ 176 192
SDO_ 176
SDO_ 160
SDO_ 160
GND
SDO_ 144
SDO_ 144
SDO_ 124
SDO_ 124
SDO_ 112
SDO_ 112
SDO_ 96
SDO_ 96
SDO_ 80
SDO_ 80
GND
SDO_ 60
SDO_ 60
SDO_ 44
SDO_ SDO_ 44 28
SDO_ 28
SDO_ 12
SDO_ MON0 MON0 12
GND
NC
NC
NC
A
SDO_ 280
SDO_ 236
SDO_ 236
SDO_ 240
10
SDO_ 240
11 12
SDO_ 232
SDO_ 232
15
GND
SDO_ 212
SDO_ 212
16
SDO_ 188
17 18
SDO_ 188
SDO_ 172
19
SDO_ 172
20
SDO_ 156
21
SDO_ 156
22 23
GND
SDO_ 140
24
SDO_ 140
25
SDO_ 128
26
SDO_ 128
27 28
SDO_ 108
SDO_ 108
SDO_ 92
SDO_ 92
31 32
SDO_ 76
SDO_ 76
GND
SDO_ 64
35 36
SDO_ 64
SDO_ 48
SDO_ 48
SDO_ 32
39
SDO_ 32
40
SDO_ 16
41 42
SDO_ 16
SDO_ 0
43 44
SDO_ RSV _DNC 0
45 46
47
GND
GND
NC
NC
B
B
NC
NC
GND
GND
GND
SDO_ 280
C
NC
GND
GND
GND
GND
VCC_ OUT1
SDO_ 284
SDO_ 284
SDO_ 272
SDO_ 272
SDO_ 204
SDO_ 204
GND
SDO_ 216
SDO_ 216
SDO_ 196
SDO_ 196
SDO_ 180
SDO_ 180
SDO_ 164
SDO_ 164
GND
SDO_ 148
SDO_ 148
SDO_ 132
SDO_ 132
SDO_ 116
SDO_ 116
SDO_ 100
SDO_ 100
SDO_ 84
SDO_ 84
GND
SDO_ 68
SDO_ 68
SDO_ 52
SDO_ 52
SDO_ 36
SDO_ 36
SDO_ 20
SDO_ 20
SDO_ 4
SDO_ RSV _DNC 4
GND
GND
GND
GND
NC
C
D
GND
GND
GND
GND
GND
GND
RSV _DNC
SDO_ 260
SDO_ 260
SDO_ 252
SDO_ 252
SDO_ 224
SDO_ 224
GND
SDO_ 200
SDO_ 200
SDO_ 184
SDO_ 184
SDO_ 168
SDO_ 168
SDO_ 152
SDO_ 152
GND
SDO_ 136
SDO_ 136
SDO_ 120
SDO_ 120
SDO_ 104
SDO_ 104
SDO_ 88
SDO_ 88
GND
SDO_ 72
SDO_ 72
SDO_ 56
SDO_ 56
SDO_ 40
SDO_ SDO_ 24 40
SDO_ 24
SDO_ 8
SDO_ 8
GND
GND
GND
GND
GND
GND
D
E
EXT _PG1
RSV _DNC
GND
GND
GND
GND
GND
DTHERMA 3
SDO_ 276
SDO_ SDO_ 276 256
SDO_ SDO_ 220 256
SDO_ 220
GND
SDO_ 258
SDO_ 258
SDO_ 210
SDO_ 210
SDO_ 186
SDO_ 186
SDO_ 178
SDO_ 178
GND
SDO_ 150
SDO_ 150
SDO_ 138
SDO_ 138
SDO_ 122
SDO_ 122
SDO_ 98
SDO_ 98
GND
SDO_ 74
SDO_ 74
SDO_ 50
SDO_ 50
SDO_ 26
SDO_ 26
SDO_ 2
SDO_ 2
VCC_ OUT1
GND
GND
GND
GND
GND
GND
SDI _0
E
F
EXT _PG1
SDI_ 3
RSV _DNC
GND
GND
GND
GND
GND
DTHERMK 3
SDO_ 282
SDO_ 274
SDO_ 274
SDO_ 234
SDO_ 234
GND
SDO_ 242
SDO_ 242
SDO_ 190
SDO_ 190
SDO_ 198
SDO_ 198
SDO_ 174
SDO_ 174
GND
SDO_ 146
SDO_ 146
SDO_ 126
SDO_ 126
SDO_ 102
SDO_ 102
SDO_ 78
SDO_ 78
GND
SDO_ 54
SDO_ 54
SDO_ 34
SDO_ 34
SDO_ 6
SDO_ 6
GND
GND
GND
GND
GND
GND
VCC _IN1
SDI_ 4
SDI_ 0
F
G
SDI_ 7
SDI_ 3
SDI_ 11
GND
GND
GND
GND
GND
GND
VCC_ SDO_ OUT1 286
SDO_ 286
SDO_ 270
SDO_ 270
SDO_ 250
SDO_ 250
GND
SDO_ 214
SDO_ SDO_ 218 214
SDO_ 218
SDO_ 194
SDO_ 194
SDO_ 170
SDO_ 170
GND
SDO_ 130
SDO_ SDO_ 130 106
SDO_ 106
SDO_ 82
SDO_ 82
SDO_ 58
SDO_ 58
GND
SDO_ 30
SDO_ SDO_ 30 10
SDO_ 10
VCC_ OUT1
GND
GND
GND
GND
GND
RSV _DNC
SDI_ 8
SDI_ 4
SDI_ 20
G
H
SDI_ 7
SDI_ 19
SDI_ 11
SDI_ 23
VCC _IN2
GND
GND
GND
GND
GND
GND
SDO_ 278
SDO_ 278
SDO_ 254
SDO_ SDO_ 246 254
SDO_ 246
GND
SDO_ 206
SDO_ 206
SDO_ 182
SDO_ SDO_ 158 182
SDO_ 158
SDO_ 134
SDO_ 134
GND
SDO_ 110
SDO_ 110
SDO_ 86
SDO_ 86
SDO_ 62
SDO_ 62
SDO_ 38
SDO_ 38
GND
SDO_ 14
SDO_ 14
GND
GND
GND
GND
GND
GND
DTHERMA 0
SDI_ 12
SDI_ 8
SDI_ 24
SDI_ 20
H
J
SDI_ 15
SDI_ 19
SDI_ 43
SDI_ 23
RSV _IO
GND
GND
GND
GND
GND
GND
VCC_ SDO_ OUT1 262
SDO_ 262
SDO_ 266
SDO_ 266
SDO_ 226
SDO_ 226
GND
SDO_ 202
SDO_ 202
SDO_ 162
SDO_ SDO_ 154 162
SDO_ 154
SDO_ 114
SDO_ 114
GND
SDO_ 90
SDO_ 90
SDO_ 66
SDO_ 66
SDO_ 42
SDO_ 42
SDO_ 18
SDO_ 18
GND
VCC_ OUT1
GND
GND
GND
GND
GND
DTHERMK 0
SDI_ 16
SDI_ 12
SDI_ 28
SDI_ 24
SDI_ 40
J
K
SDI_ 15
SDI_ 35
SDI_ 43
SDI_ 27
RSV _IO
RSV _IO
VCC _IN2
GND
GND
GND
GND
GND
GND
SDO_ 238
SDO_ 238
SDO_ 230
SDO_ SDO_ 222 230
SDO_ 222
GND
SDO_ 166
SDO_ 166
SDO_ 142
SDO_ SDO_ 142 118
SDO_ 118
SDO_ 94
SDO_ 94
GND
SDO_ 70
SDO_ 70
SDO_ 46
SDO_ 46
SDO_ 22
SDO_ 22
GND
GND
GND
GND
GND
GND
GND
VCC _IN1
RSV _IO
SDI_ 16
SDI_ 32
SDI_ 28
SDI_ 44
SDI_ 40
K
L
SDI_ 31
SDI_ 35
SDI_ 59
SDI_ 27
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
GND
GND
GND
VCC_ VCC_ OUT1 OUT1
VCC_ OUT1
VCC_ VCC_ OUT1 OUT1
VCC_ VCC_ OUT1 OUT1
VCC_ OUT1
VCC_ VCC_ OUT1 OUT1
VCC_ VCC_ OUT1 OUT1
VCC_ VCC_ OUT1 OUT1
GND
GND
GND
GND
GND
GND
GND
RSV _IO
RSV _IO
SDI_ 36
SDI_ 32
SDI_ 48
SDI_ 44
SDI_ 60
L
M
SDI_ 31
SDI_ 51
SDI_ 59
SDI_ 39
RSV _IO
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
SDI_ 36
SDI_ 52
SDI_ 48
SDI_ 64
SDI_ 60
M N
SDO_ 282
VCC_ OUT1
VCC_ OUT1
VCC_ OUT1
VCC_ VCC_ VCC_ OUT1 OUT1 OUT1
VCC_ OUT1
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
N
SDI_ 47
SDI_ 51
SDI_ 71
SDI_ 39
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
GND
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 56
SDI_ 52
GND
SDI_ 64
SDI_ 76
P
SDI_ 47
SDI_ 67
SDI_ 71
SDI_ 55
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
GND
GND
GND
GND
GND
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
VCC_ OUT1
GND
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 56
GND
SDI_ 68
GND
SDI_ 76
P
LDO0
VCC _25_ VCO0
EXT CLK0
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
SDI_ 72
SDI_ 68
SDI_ 80
GND
R
R
GND
SDI_ 67
SDI_ 75
SDI_ 55
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
VCC EXT _25_ LDO2 _CLK2 VCO2
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
T
SDI_ 63
GND
SDI_ 75
SDI_ 87
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
GND
EXT _CLK2
GND
LF2
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
LF0
GND
EXT CLK0
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
SDI_ 72
SDI_ 84
SDI_ 80
SDI_ 92
T
U
SDI_ 63
SDI_ 83
GND
SDI_ 87
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
GND
GND
GND
GND
GND
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
GND
GND
GND
GND
GND
GND
VCC _IN1
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
SDI_ 88
SDI_ 84
SDI_ 96
SDI_ 92
U
V
SDI_ 79
SDI_ 83
SDI_ 91
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
VDD _25
GND
VDD_ 18
VDD_ 18
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VDD_ 18
VDD_ 18
GND
VDD_ 25
GND
GND
VCC _IN1
VCC _IN1
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
SDI_ 88
SDI_ 100
SDI_ 96
SDI_ 108
V
W
SDI_ 79
SDI_ 99
SDI_ 91
SDI_ 103
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
GND
GND
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 104
SDI_ 100
SDI_ 112
SDI_ 108
W
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 104
SDI_ 116
SDI_ 112
SDI_ 128
Y
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
GND
GND
VCC _IN1
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 120
SDI_ 116
SDI_ 124
SDI_ 128
AA AB
Y
SDI_ 95
SDI_ 99
SDI_ 107
SDI_ 103
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
AA
SDI_ 95
SDI_ 115
SDI_ 107
SDI_ 119
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
VCC _IN2
VCC _IN2
GND
GND
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
AB
SDI_ 111
SDI_ 115
SDI_ 123
SDI_ 119
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
GND
GND
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ VCC_ 25_A 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC _IN1
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 120
GND
SDI_ 124
SDI_ 144
AC
SDI_ 111
SDI_ 131
SDI_ 123
SDI_ 135
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
GND
GND
GND
GND
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
SDI_ 132
GND
SDI_ 144
AC
AD
SDI_ 127
SDI_ 131
SDI_ 139
SDI_ 135
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_ REF_ CLK
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
SDI_ 136
SDI_ 132
SDI_ 140
GND
AD
AE
SDI_ 127
SDI_ 147
SDI_ 139
SDI_ 151
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VDD_ 25
SDI_ 136
SDI_ 148
AE
AF
GND
SDI_ 147
SDI_ 155
SDI_ 151
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
VDD_ 25
GND
VDD_ 18
VDD_ 18
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VDD_ 18
VDD_ 18
GND
AG
SDI_ 143
GND
SDI_ 155
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
GND
GND
GND
AH
SDI_ 143
SDI_ 163
GND
SDI_ 167
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
GND
EXT _CLK1
GND
LF1
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
LF_ DIGITAL
GND
AJ
SDI_ 159
SDI_ 163
SDI_ 171
SDI_ 167
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
GND
EXT _CLK1
VCC_ 25_ VCO1
LDO1
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
VCC_ 25_A
VCC_ 25_A
GND
GND
VCC_ 25_A
VCC_ 25_A
GND
LDO_ DIGITAL
AK
SDI_ 159
SDI_ 175
SDI_ 171
SDI_ 183
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
VDD_ 18
GND
VDD_ 18
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND VCC _IN1
RSV _IO
RSV _IO
GND
GND
VCC _IN1
RSV _IO
RSV _IO
GND
RSV _IO
SDI_ 140
SDI_ 160
GND
GND
VCC _IN1
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
SDI_ 152
SDI_ 148
SDI_ 156
SDI_ 160
AF
GND
GND
GND
GND
GND
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
SDI_ 152
SDI_ 164
SDI_ 156
SDI_ 176
AG
EXT_ CLK_ DIGITAL
GND
GND
GND
GND
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 168
SDI_ 164
SDI_ 172
SDI_ 176
AH
VCC_ EXT_ VCO_ CLK_ DIGITAL DIGITAL
GND
GND
VCC _IN1
VCC _IN1
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 168
SDI_ 180
SDI_ 172
SDI_ 192
AJ
GND
VCC _IN1
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 184
SDI_ 180
SDI_ 188
SDI_ 192
AK AL
RSV _DNC
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 184
SDI_ 196
SDI_ 188
P_ADD P_ADD P_ADD P_ADD P_ADD P_ADD P_ADD P_ADD P_ADD P_ADD P_ADD P_ADD UPDATE UPDATE UPDATE UPDATE UPDATE UPDATE UPDATE UPDATE _EN0 _EN1 _EN2 _EN3 _EN4 _EN5 _EN6 _EN7 0 1 2 3 4 5 6 7 8 9 10 11
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
SDI_ 196
SDI_ 204
SDI_ 208
AM
GND
VCC _IN1
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
SDI_ 200
GND
SDI_ 204
SDI_ 224
AN
GND
VCC _IN1
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
SDI_ 200
SDI_ 212
GND
SDI_ 224
AP
GND
GND
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
SDI_ 232
SDI_ 212
SDI_ 220
GND
AR
GND
RSV _IO
RSV _IO
RSV _IO
SDI_ 232
SDI_ 216
SDI_ 220
SDI_ 240
AT
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 248
SDI_ 216
SDI_ 236
SDI_ 240
AU
AL
SDI_ 179
SDI_ 175
SDI_ 187
SDI_ 183
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
GND
GND
GND
GND
GND
SDI_ 179
SDI_ 191
SDI_ 187
SDI_ 199
RSV _IO
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
GND
GND
AN
SDI_ 195
SDI_ 191
SDI_ 203
SDI_ 199
RSV _IO
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
VCC _IN2
GND
GND
HOST_ SCLK S/P
AP
SDI_ 195
SDI_ 207
SDI_ 203
SDI_ 215
RSV _IO
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
VDD_ 18
AR
GND
SDI_ 207
SDI_ 219
SDI_ 215
GND
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
VDDIO VDDIO VDDIO GND _D _D _D
AT
SDI_ 211
GND
SDI_ 219
GND
SDI_ 231
RSV _IO
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
AU
SDI_ 211
SDI_ 223
GND
SDI_ 235
SDI_ 231
RSV _IO
RSV _IO
RSV _IO
RSV _IO
GND
GND
GND
GND
GND
AV
SDI_ 227
SDI_ 223
SDI_ 239
SDI_ 235
SDI_ 251
RSV _IO
RSV _IO
RSV _IO
VCC _IN2
GND
GND
GND
GND
GND
GND
GND
GND
AW
SDI_ 227
SDI_ 243
SDI_ 239
SDI_ 255
SDI_ 251
RSV _IO
RSV _IO
GND
GND
GND
GND
GND
GND
VCC_ 25_A
VCC_ OUT2
VCC_ OUT2
VCC_ OUT2
GND
CLK_ REF_ IN CLK_ REF_ OUT
SDI_ 208
AM
GND
GND
RSV _DNC
GND
TCK
TMS
TDO
SDIN SDOUT S_CS
VDDIO GND VDDIO _D _D GND
TDI
GND
GND
P_CS P_R/W P_ADS GND
GND
GND
GND
GND
GND
GND
GND
GND RSV _DNC
GND RSV _DNC
GND
P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT P_DAT GND 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
GND VDDIO VDDIO GND _D _D VDD_ 18
GND
VDD_ VDD_ 18 18
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
GND
GND
GND
VCC_ VCC_ OUT2 OUT2
GND
GND
GND
GND
GND
GND
VDDIO GND _D
GND
GND
GND
GND
GND
RSV _IO
VDD_ 18
VDDIO VDD_ 18 _D
GND
VDD_ VDDIO 18 _D
GND
VDDIO VDDIO GND VDDIO VDDIO _D _D _D _D
GND
VDD_ 18
GND
VDD_ 18
GND
VDD_ 18
VDD_ 18
VDD_ 18
GND
VDD_ 18
GND
POR_ DFT
RSV _DNC
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
GND
GND
GND
VCC_ 25_A
GND
RSV _IO
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
VCC_ OUT2
GND
GND
GND
GND
VCC_ 25_A
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
VCC_ VCC_ OUT2 OUT2
VCC_ OUT2
VCC_ OUT2
VCC_ VCC_ OUT2 OUT2
RESET
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
VCC _IN1
RSV _IO
RSV _IO
RSV _IO
RSV _IO
SDI_ 248
SDI_ 228
SDI_ 236
SDI_ 256
AV
VCC_ VCC_ VCC_ OUT2 OUT2 OUT2
VCC_ OUT2
VCC_ OUT2
VCC_ VCC_ OUT2 OUT2
VCC_ VCC_ OUT2 OUT2
VCC_ OUT2
GND
GND
GND
GND
GND
GND
GND
RSV _IO
RSV _IO
RSV _IO
SDI_ 260
SDI_ 228
SDI_ 252
SDI_ 256
AW
AY
SDI_ 247
SDI_ 243
SDI_ 259
SDI_ 255
SDI_ 271
RSV _IO
VCC _IN2
GND
GND
GND
GND
GND
VCC_ 25_A
GND
SDO_ 265
SDO_ 265
SDO_ 241
SDO_ 241
SDO_ 217
SDO_ 217
GND
SDO_ 193
SDO_ 193
SDO_ 169
SDO_ 169
SDO_ 145
SDO_ 145
SDO_ 121
SDO_ 121
GND
SDO_ 65
SDO_ 65
SDO_ 57
SDO_ 57
SDO_ 49
SDO_ 49
GND
GND
GND
GND
GND
GND
VCC _IN1
RSV _IO
RSV _IO
SDI_ 260
SDI_ 244
SDI_ 252
SDI_ 272
AY
BA
SDI_ 247
SDI_ 263
SDI_ 259
SDI_ 275
SDI_ 271
DTHERMK 2
GND
GND
GND
GND
GND
VCC_ OUT2
GND
SDO_ 269
SDO_ 269
SDO_ 245
SDO_ 245
SDO_ 221
SDO_ 221
SDO_ 197
SDO_ 197
GND
SDO_ 173
SDO_ 173
SDO_ 133
SDO_ 133
SDO_ 125
SDO_ 125
SDO_ 85
SDO_ 85
GND
SDO_ 61
SDO_ 61
SDO_ 21
SDO_ 21
SDO_ 25
SDO_ 25
VCC_ OUT2
GND
GND
GND
GND
GND
GND
RSV _IO
SDI_ 264
SDI_ 244
SDI_ 268
SDI_ 272
BA
SDI_ 279
SDI_ 275
SDO_ 9
SDI_ 264
SDI_ 276
BB
BB
SDI_ 267
SDI_ 263
DTHERMA 2
GND
GND
GND
GND
GND
GND
SDO_ 273
SDO_ 273
GND
SDO_ 249
SDO_ 249
SDO_ 225
SDO_ 225
SDO_ 201
SDO_ 201
SDO_ 177
SDO_ 177
GND
SDO_ 153
SDO_ 153
SDO_ 129
SDO_ 129
SDO_ 105
SDO_ 105
SDO_ 81
SDO_ 81
GND
SDO_ 41
SDO_ 41
SDO_ 33
SDO_ 33
SDO_ 9
GND
GND
GND
GND
GND
GND
VCC _IN1
SDI_ 268
SDI_ 280
Legend:
BC
SDI_ 267
SDI_ 283
SDI_ 279
RSV _DNC
GND
GND
GND
GND
GND
VCC_ OUT2
SDO_ 277
SDO_ 277
SDO_ 257
SDO_ 257
GND
SDO_ 229
SDO_ 229
SDO_ 205
SDO_ 205
SDO_ 181
SDO_ 181
SDO_ 157
SDO_ 157
GND
SDO_ 117
SDO_ 117
SDO_ 93
SDO_ 93
SDO_ 69
SDO_ 69
SDO_ 73
SDO_ 73
GND
SDO_ 37
SDO_ 37
SDO_ 17
SDO_ 17
SDO_ 1
SDO_ 1
VCC_ OUT2
GND
GND
GND
GND
GND
GND
SDI_ 276
SDI_ 284
SDI_ 280
BC
Power
BD
SDI_ 287
SDI_ 283
VCC _IN2
GND
GND
GND
GND
GND
GND
SDO_ 281
SDO_ 281
SDO_ 253
SDO_ 253
SDO_ 233
SDO_ 233
GND
SDO_ 209
SDO_ 209
SDO_ 185
SDO_ 185
SDO_ 161
SDO_ 161
SDO_ 141
SDO_ 141
GND
SDO_ 113
SDO_ 113
SDO_ 89
SDO_ 89
SDO_ 97
SDO_ 97
SDO_ 45
SDO_ 45
GND
SDO_ 53
SDO_ 53
SDO_ 13
SDO_ 13
SDO_ 5
SDO_ 5
DTHERMK 1
GND
GND
GND
GND
GND
RSV _DNC
SDI_ 284
EXT _PG0
BD
Ground
BE
SDI_ 287
GND
GND
GND
GND
GND
GND
VCC_ OUT2
SDO_ 285
SDO_ 285
SDO_ 261
SDO_ 261
SDO_ 237
SDO_ 237
SDO_ 213
SDO_ 213
GND
SDO_ 189
SDO_ 189
SDO_ 165
SDO_ 165
SDO_ 149
SDO_ 149
SDO_ 137
SDO_ 137
GND
SDO_ 109
SDO_ 109
SDO_ 101
SDO_ 101
SDO_ 77
SDO_ 77
SDO_ 29
SDO_ 29
GND
SDO_ 67
SDO_ 67
SDO_ 31
SDO_ 31
SDO_ 11
SDO_ 11
DTHERMA 1
GND
GND
GND
GND
GND
RSV _DNC
EXT _PG0
BE
Input
BF
GND
GND
GND
GND
GND
GND
GND
SDO_ 279
SDO_ 279
SDO_ 263
SDO_ 263
SDO_ 247
SDO_ 247
SDO_ 231
SDO_ 231
SDO_ 215
SDO_ 215
GND
SDO_ 199
SDO_ 199
SDO_ 183
SDO_ 183
SDO_ 167
SDO_ 167
SDO_ 151
SDO_ 151
GND
SDO_ 135
SDO_ 135
SDO_ 119
SDO_ 119
SDO_ 103
SDO_ 103
SDO_ 87
SDO_ 87
GND
SDO_ 63
SDO_ 63
SDO_ 35
SDO_ 35
SDO_ 27
SDO_ 27
RSV _DNC
GND
GND
GND
GND
GND
GND
BF
SDO_ 283
SDO_ 283
SDO_ 267
SDO_ 267
SDO_ 251
SDO_ 251
SDO_ 235
SDO_ 235
SDO_ 219
SDO_ 219
GND
SDO_ 203
SDO_ 203
SDO_ 187
SDO_ 187
SDO_ 171
SDO_ 171
SDO_ 155
SDO_ 155
SDO_ 139
SDO_ 139
GND
SDO_ 123
SDO_ 123
SDO_ 107
SDO_ 107
SDO_ 91
SDO_ 91
SDO_ 71
SDO_ 71
GND
SDO_ 83
SDO_ 83
SDO_ 15
SDO_ 15
SDO_ 3
SDO_ 3
VCC_ OUT2
GND
GND
GND
GND
NC
BG
SDO_ DIGITAL _CL_SEL GND 7
GND
NC
NC
BH
SDO_ 19
NC
NC
NC
BJ
46 47
48
49
NC
GND
GND
GND
GND
RSV _DNC
BH
NC
NC
GND
GND
RSV _DNC
SDO_ 287
SDO_ 287
SDO_ 271
SDO_ 271
SDO_ 255
SDO_ 255
SDO_ 239
SDO_ 239
SDO_ 223
SDO_ 223
GND
SDO_ 211
SDO_ 211
SDO_ 195
SDO_ 195
SDO_ 179
SDO_ 179
SDO_ 159
SDO_ 159
SDO_ 147
SDO_ 147
GND
SDO_ 131
SDO_ 131
SDO_ 115
SDO_ 115
SDO_ 99
SDO_ 99
SDO_ 75
SDO_ 75
GND
SDO_ 55
SDO_ 55
SDO_ 47
SDO_ 47
SDO_ 51
SDO_ 51
SDO_ 7
BJ
NC
NC
NC
GND MON1 MON1
SDO_ 275
SDO_ 275
SDO_ 259
SDO_ 259
SDO_ 243
SDO_ 243
SDO_ 227
SDO_ 227
GND
SDO_ 207
SDO_ 207
SDO_ 191
SDO_ 191
SDO_ 175
SDO_ 175
SDO_ 163
SDO_ 163
SDO_ 143
SDO_ 143
GND
SDO_ 127
SDO_ 127
SDO_ 111
SDO_ 111
SDO_ 95
SDO_ 95
SDO_ 79
SDO_ 79
GND
SDO_ 59
SDO_ 59
SDO_ 39
SDO_ 39
SDO_ 23
SDO_ 23
SDO_ 43
SDO_ SDO_ 19 43
1
2
3
7
8
9
10
11
12
13
14
15
16
17
18
19 20
21
24 25
26
27
28
29
30
33
34
Output
BG
Digital Control Reserved
4
5
6
22 23
31 32
35 36
37 38 39
40
41 42
43
44
45
GND
Figure 1-1: GX3190 Ball Assignment Overview (Top View)
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
www.semtech.com
5 of 47 Proprietary & Confidential
1.2 Ball Descriptions Table 1-1 shows the descriptions for selected GX3190 balls. For a comprehensive list of balls from the GX3190 Crosspoint family, please refer to GX3290 (and family) Crosspoint Ball Guide. Table 1-1: Ball Descriptions Ball #
Ball Name
I/O
Description
AN16
SCLK
I
Serial Host Interface Clock. If unused, tie to ground.
AN17
SDIN
I
Serial Host Interface Data Input. If unused, tie to ground.
AN18
SDOUT
O
Serial Host Interface Data Output. Leave NC if not used.
AN19
S_CS
I
Serial Host Interface Chip Select. Active-LOW. Must be tied LOW when HOST_S/P is set LOW.
AL23
P_CS
I
Parallel host interface chip select. Active-LOW. Must be tied LOW when HOST_S/P is set HIGH.
AL24
P_R/W
I
Selects between read and write operations on the parallel host interface. HIGH = Read, LOW = Write. If unused, tie to ground.
AL25
P_ADS
I
Address and Data Strobe. Strobe signal for latching the address and data into the chip. See Section 4.12.1 for timing information. If unused, tie to ground.
AM27 - AM16
P_ADD[11:0]
I
Address bus for the parallel interface. If unused, tie to ground.
AN35 - AN20
P_DAT[15:0]
I/O
AN15
HOST_S/P
I
Host Interface Select pin. Selects between serial and parallel host interfaces. Serial host interface is enabled when HIGH, parallel host interface is enabled when LOW. Must assert RESET after changing this pin.
AM35 - AM28
UPDATE_EN [7:0]
I
Update Strobes used to update the switch matrix configuration (see Section 4.5). If unused, weak pull-down to ground.
AR33
POR_DFT
I
This pin disables the Power On Reset circuitry when HIGH. Weak internal pull-down. Leave NC if not used.
AR35
RESET
I
Active-LOW reset for entire chip (see Section 4.11 for timing details). Weak internal pull-up. Leave NC if not used.
AL17
TCK
I
JTAG test clock. Weak pull-up if not used.
AL18
TMS
I
JTAG test mode start. Weak pull-up if not used.
AL19
TDO
O
JTAG test data out. Leave NC if not used.
AL20
TDI
I
JTAG test data in. Weak pull-up if not used.
Serial Interface I/O
Parallel Interface I/O
Bi-directional data bus for the parallel interface. If P_CS is HIGH, these pins are configured as inputs. Leave NC if parallel interface is not used. If unused, tie to ground.
General I/O
Test Interface
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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Table 1-1: Ball Descriptions (Continued) Ball #
Ball Name
I/O
Description
R17
LDO2
—
LDO filter capacitor for VCO_2. Connect through a 220nF capacitor to ground. See Figure 3-3 for configuration.
R33
LDO0
—
LDO filter capacitor for VCO_0. Connect through a 220nF capacitor to ground. See Figure 3-3 for configuration.
T17
LF2
—
PLL loop filter capacitor for VCO_2. See Figure 3-3 for configuration. Leave NC if not used.
T33
LF0
—
PLL loop filter capacitor for VCO_0. See Figure 3-3 for configuration. Leave NC if not used.
AH17
LF1
—
PLL loop filter capacitor for VCO_1. See Figure 3-3 for configuration. Leave NC if not used.
AH33
LF_DIGITAL
—
PLL loop filter capacitor for VCO_DIGITAL. Connect through a 47nF capacitor to ground. See Figure 3-3 for configuration.
AJ17
LDO1
—
LDO filter capacitor for VCO_1. Connect through a 220nF capacitor to ground. See Figure 3-3 for configuration.
AJ33
LDO_DIGITAL
—
LDO filter capacitor for VCO_DIGITAL. Connect through a 220nF capacitor to ground. See Figure 3-3 for configuration.
AE35
REF_CLK_IN
—
Connect a 27MHz crystal between this ball and REF_CLK_OUT. See Section 4.9 and Figure 3-5.
AF35
REF_CLK_OUT
—
Connect a 27MHz crystal between this ball and REF_CLK_IN. See Section 4.9 and Figure 3-5. Leave NC if not used.
R15
EXT_CLK2
I
External CML clock for Pattern Generator 1 (true). Leave NC if not used.
R35
EXT_CLK0
I
External CML clock for Pattern Checker 0 (true). Leave NC if not used.
T15
EXT_CLK2
I
External CML clock for Pattern Generator 1 (complement). Leave NC if not used.
T35
EXT_CLK0
I
External CML clock for Pattern Checker 0 (complement). Leave NC if not used.
AH15
EXT_CLK1
I
External CML clock for Pattern Checker 1 (complement). Leave NC if not used.
AH35
EXT_CLK _DIGITAL
I
External CML clock for Pattern Transmitter 0/Digital Core (complement). Leave NC if not used.
AJ15
EXT_CLK1
I
External CML clock for Pattern Checker 1 (true). Leave NC if not used.
AJ35
EXT_CLK _DIGITAL
I
External CML clock for Pattern Transmitter 0/Digital Core (true). Leave NC if not used.
BH45
DIGITAL_CL_SEL
I
Clock select between external clock source (EXT_CLK_DIGITAL) and internal VCO (VCO_DIGITAL). This pin has a weak internal pull-up, and should be pulled LOW to use an external clock.
Filtering
Crystal Oscillator
External Clocks
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Table 1-1: Ball Descriptions (Continued) Ball #
Ball Name
I/O
Description
E8
DTHERMA3
—
Thermometer 3 diode terminals. See Section 4.8. Leave NC if not used.
F9
DTHERMK3
—
Thermometer 3 diode terminals. See Section 4.8. Leave NC if not used.
H45
DTHERMA0
—
Thermometer 0 diode terminals. See Section 4.8. Leave NC if not used.
J44
DTHERMK0
—
Thermometer 0 diode terminals. See Section 4.8. Leave NC if not used.
BA6
DTHERMK2
—
Thermometer 2 diode terminals. See Section 4.8. Leave NC if not used.
BB5
DTHERMA2
—
Thermometer 2 diode terminals. See Section 4.8. Leave NC if not used.
BD41
DTHERMK1
—
Thermometer 1 diode terminals. See Section 4.8. Leave NC if not used.
BE42
DTHERMA1
—
Thermometer 1 diode terminals. See Section 4.8. Leave NC if not used.
A44
MON0
O
Serial monitoring output 0 (complement). Leave NC if not used.
A45
MON0
O
Serial monitoring output 0 (true). Leave NC if not used.
BJ5
MON1
O
Serial monitoring output 1 (true). Leave NC if not used.
BJ6
MON1
O
Serial monitoring output 1 (complement). Leave NC if not used.
Temperature Sensors
Monitors
External Pattern Generators E1
EXT_PG1
I
Serial pattern generator input 1 (complement). Leave NC if not used.
F1
EXT_PG1
I
Serial pattern generator input 1 (true). Leave NC if not used.
BD49
EXT_PG0
I
Serial pattern generator input 0 (true). Leave NC if not used.
BE49
EXT_PG0
I
Serial pattern generator input 0 (complement). Leave NC if not used.
Reserved - Do Not Connect B45, C44, D7, E2, F3, G46, AL32, AL33, AL34, AL35, AR34, BC4, BD47, BE48, BF43, BG6, BH5,
RSV_DNC
—
Reserved. Do not connect.
SDI/SDO Refer to the GX3290 (and family) Crosspoint Ball Guide for a detailed list of SDI and SDO balls.
Power Refer to the GX3290 (and family) Crosspoint Ball Guide for a detailed list of power supply balls.
Ground Refer to the GX3290 (and family) Crosspoint Ball Guide for a detailed list of ground balls.
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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2. Electrical Characteristics 2.1 Absolute Maximum Ratings Table 2-1: Absolute Maximum Ratings Parameter
Value
Supply Voltage (VDD_18)
-0.3V to +2.1V
Supply Voltage (VCC_IN1, VCC_IN2, VCC_25_A, VDD_25, VDDIO_D, VCC_OUT1, VCC_OUT2, VCC_25_REF_CLK, VCC_25_VCO0, VCC_25_VCO1, VCC_25_VCO2)
-0.3V to +2.8V
-0.3 to (0.3 + min[VCC_IN1, VCC_25_A])V for even numbered SDI inputs and EXT_PG0 Input Voltage Range -0.3 to (0.3 + min[VCC_IN2, VCC_25_A])V for odd numbered SDI inputs and EXT_PG1 ESD Voltage (HBM; all balls)
1kV
ESD Voltage (CDM; all balls)
100V
Storage Temperature Range
-50ºC to +125ºC
Operating Temperature Range
0ºC to 85ºC
Solder Reflow Temperature
245ºC
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2.2 Recommended Operating Conditions Table 2-2: Recommended Operating Conditions Parameter
Symbol
Min
Typ
Max
Units
Notes
VCC_25_A, VCC_25_REF_CLK
2.375
2.5
2.625
V
1
1.14
1.2
1.26
V
2
1.71
1.8
1.89
V
3
2.375
2.5
2.625
V
1
1.14
1.2
1.26
V
2
1.71
1.8
1.89
V
3
2.375
2.5
2.625
V
1
1.71
1.8
1.89
V
3
1.71
1.8
1.89
V
3
2.375
2.5
2.625
V
1
VDD_25
2.375
2.5
2.625
V
1
Operating Temperature Range (case)
TOP
0
25
85
°C
—
Start-up Temperature Range
TSU
-40
—
85
°C
—
VCC_IN1, VCC_IN2
Operating Power Supply
VCC_OUT1, VCC_OUT2
VDD_18 VDDIO_D
Notes: 1. 2.5V supply. 2. 1.2V supply. 3. 1.8V supply.
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2.3 DC Electrical Characteristics Table 2-3: DC Electrical Characteristics Parameter
Symbol
Conditions
Min
Typ
Max
Units
Note
All channels active, VCC_IN[1,2] = VCC_OUT[1,2] = 1.2V±5%, ΔVOD = 200mV, ΔVSDI = 800mVppd, de-emphasis=6, without Pattern Generator/Checker, AC-coupled
—
31.51
42
W
1
All channels active, VCC_IN[1,2] = VCC_OUT[1,2] = 1.2V±5%, ΔVOD = 400mV, ΔVSDI = 800mVppd, de-emphasis=6, without Pattern Generator/Checker, AC-coupled
—
35.94
—
W
1
All channels active, VCC_IN[1,2] = VCC_OUT[1,2] = 2.5V±5%, ΔVOD = 800mV, ΔVSDI = 800mVppd, de-emphasis=6, without Pattern Generator/Checker, AC-coupled
—
41.86
53
W
1
All channels active, VCC_IN[1,2] = VCC_OUT[1,2] = 2.5V±5%, ΔVOD = 1200mV, ΔVSDI = 800mVppd, de-emphasis=6, without Pattern Generator/Checker, AC-coupled
—
46.82
58.5
W
1
PRBS Generator/Checker
—
1.86
—
W
—
RESET = 0
—
0.5
—
W
—
With de-emphasis, without Pattern Generator/Checker
—
13.4
15.8
A
—
Without de-emphasis, without Pattern Generator/Checker
—
12.4
—
A
—
System
Power
Power in Reset Mode
Current - VCC_25_A
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
P
P
ICC_25_A
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Table 2-3: DC Electrical Characteristics (Continued) Parameter
Current - VCC_IN1
Current - VCC_IN2
Current - VCC_OUT1
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
Symbol
Conditions
Min
Typ
Max
Units
Note
All inputs active, ΔVSDI = 1.2Vppd, DC-coupled
—
0.85
—
A
2
All inputs active, ΔVSDI = 1.2Vppd, AC-coupled
-0.2
—
0
A
3
All inputs active, ΔVSDI = 1.2Vppd, DC-coupled
—
0.85
—
A
2
All inputs active, ΔVSDI = 1.2Vppd, AC-coupled
-0.2
—
0
A
3
VCC_OUT1 = 1.2V ±5%, all outputs active, ΔVOD = 200mV, with De-emphasis
—
0.31
0.38
A
4
VCC_OUT1 = 1.2V ±5%, all outputs active, ΔVOD = 400mV, with De-emphasis
—
0.59
—
A
4
VCC_OUT1 = 1.2V ±5%, all outputs active, ΔVOD = 800mV, with De-emphasis
—
1.11
—
A
4, 5
VCC_OUT1 = 2.5V ±5%, all outputs active, ΔVOD = 200mV, with De-emphasis
—
0.33
—
A
4
VCC_OUT1 = 2.5V ±5%, all outputs active, ΔVOD = 400mV, with De-emphasis
—
0.59
—
A
4
VCC_OUT1 = 2.5V ±5%, all outputs active, ΔVOD = 800mV, with De-emphasis
—
1.22
1.55
A
4
VCC_OUT1 = 2.5V ±5%, all outputs active, ΔVOD = 1200mV, with De-emphasis
—
1.63
2.13
A
4
ICC_IN1
ICC_IN2
ICC_OUT1
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Table 2-3: DC Electrical Characteristics (Continued) Parameter
Current - VCC_OUT2
Symbol
ICC_OUT2
Conditions
Min
Typ
Max
Units
Note
VCC_OUT2 = 1.2V ±5%, all outputs active, ΔVOD = 200mV, with De-emphasis
—
0.31
0.38
A
4
VCC_OUT2 = 1.2V ±5%, all outputs active, ΔVOD = 400mV, with De-emphasis
—
0.59
—
A
4
VCC_OUT2 = 1.2V ±5%, all outputs active, ΔVOD = 800mV, with De-emphasis
—
1.11
—
A
4,5
VCC_OUT2 = 2.5V ±5%, all outputs active, ΔVOD = 200mV, with De-emphasis
—
0.33
—
A
4
VCC_OUT2 = 2.5V ±5%, all outputs active, ΔVOD = 400mV, with De-emphasis
—
0.59
—
A
4
VCC_OUT2 = 2.5V ±5%, all outputs active, ΔVOD = 800mV, with De-emphasis
—
1.22
1.55
A
4
VCC_OUT2 = 2.5V ±5%, all outputs active, ΔVOD = 1200mV, with De-emphasis
—
1.63
2.13
A
4
Current - VCC_25_REF_CLK
ICC_25 _REF_CLK
—
—
20
40
mA
—
Current - VCC_VCO_DIGITAL
ICC_VCO _DIGITAL
—
—
6
10
mA
—
Current - VCC_25_VCO0
ICC_25 _VCO0
—
—
6
10
mA
—
Current - VCC_25_VCO1
ICC_25 _VCO1
—
—
6
10
mA
—
Current - VCC_25_VCO2
ICC_25 _VCO2
—
—
6
10
mA
—
Current - VDD_18
IDD_18
VDD_18 = 1.8V±5%
—
260
750
mA
—
Current - VDD_25
IDD_25
VDD_25 = 2.5V±5%
—
20
40
mA
—
VDDIO_D = 1.8V±5%, all inputs active (15pF load)
—
50
100
mA
—
VDDIO_D = 2.5V±5%, all inputs active (15pF load)
—
70
140
mA
—
Current - VDDIO_D
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Table 2-3: DC Electrical Characteristics (Continued) Parameter
Symbol
Conditions
Min
Typ
Max
Units
Note
Differential
—
100
—
Ω
Single-ended
—
50
—
Ω
Differential
—
100
—
Ω
—
VCC_IN [1,2] (ΔVSDI _max/4)
—
VCC_IN [1,2] (ΔVSDI _min/4)
V
7, 8, 9, 10
VCC_OUT [1,2] (ΔVOD_ max/4)
—
VCC_OUT [1,2] (ΔVOD_ min/4)
V
—
V
11
V
11
High-speed Inputs/Outputs Serial Input Termination Serial Output Termination
— —
Serial Input Common Mode Voltage
VICM
VCC_IN[1,2] = 1.2V±5%, VCC_IN[1,2] = 1.8V±5%, VCC_IN[1,2] = 2.5V±5%, terminated to VCC_IN[1,2]
Serial Output Common Mode Voltage
VOCM
VCC_OUT[1,2] = 1.2V±5%, VCC_OUT[1,2] = 1.8V±5%, VCC_OUT[1,2] = 2.5V±5%
6
Host Interface Logic HIGH voltage on digital input pins
VIH
—
Logic LOW voltage on digital input pins
VIL
—
Output Logic LOW
Output Logic HIGH
0.7 x VDDIO_D
—
VDDIO_D
+ 0.3 0.3 x
-0.3
—
IOL = 2mA, 2.5V operation
—
—
0.7
V
11
IOL = 2mA, 1.8V operation
—
—
0.45
V
11
IOH = -2mA, 2.5V operation
1.7
—
—
V
11
IOH = -2mA, 1.8 operation
1.35
—
—
V
11
VDDIO_D
VOL
VOH
Notes: 1. Total Maximum Power is lower than individual maximum currents multiplied by individual maximum supply voltages because the individual maximum currents can not occur simultaneously (they occur at different conditions). 2. The ICC_IN1 and ICC_IN2 current flows out of the GX3190 and into the input signal source, and is subject to variability in that source. Some variability in input signal source current draw should be assumed, and up to ±15% is possible. 3. When the common mode termination points for AC-coupled inputs are connected to VCC_IN1, VCC_IN2, the GX3190 equalizer input bias currents can lead to current flowing out of the VCC_IN1, VCC_IN2 supply pins. 4. Currents apply for output DC-coupled applications. When AC-coupled, the current draw may be increased by up to 2x. 5. For DC-coupled applications only. 6. Input termination is selectable between 100Ω differential and 50Ω single-ended. See Section 3. Input/Output Equivalent Circuits. 7. DC common mode current into/out of each EQ input differential pair should not exceed 14mA, and the current into/out of each half of the differential pair should not exceed 14mA. 8. No more than VCC_IN[1,2] - ΔVSDI_actual/4. 9. Where it is understood that VCC_IN[1,2] have a ±5% tolerance. 10.In no case should either side of the input differential pair be allowed to rise above VCC_25_A + 0.3V or fall below -0.3V. 11.Specifications relate to all host interface pins.
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2.4 AC Electrical Characteristics Table 2-4: AC Electrical Characteristics Parameter
Symbol
Conditions
Min
Typ
Max
Units
Notes
System Serial Input Data Rate Propagation Delay Propagation Delay Difference
DRSDO
—
—
—
3.5
Gb/s
—
tP
—
—
—
6
ns
1
ΔtP
Between any two channels
—
—
5.5
ns
1
—
—
0.9
—
1.8
μs
2
ΔVSDI
—
100
—
1200
mVppd
—
VCC_OUT[1,2] = 1.2V±5%, Output = 200mVppd
150
225
300
mVppd
—
VCC_OUT[1,2] = 1.2V±5%, Output = 400mVppd
300
450
600
mVppd
—
VCC_OUT[1,2] = 1.2V±5%, Output = 800mVppd
600
900
1200
mVppd
3
VCC_OUT[1,2] = 1.8V±5%, Output = 200mVppd
150
225
300
mVppd
—
VCC_OUT[1,2] = 1.8V±5%, Output = 400mVppd
300
450
600
mVppd
—
VCC_OUT[1,2] = 1.8V±5%, Output = 800mVppd
600
900
1200
mVppd
—
VCC_OUT[1,2] = 2.5V±5%, Output = 200mVppd
150
225
300
mVppd
—
VCC_OUT[1,2] = 2.5V±5%, Output = 400mVppd
300
450
600
mVppd
—
VCC_OUT[1,2] = 2.5V±5%, Output = 800mVppd
600
900
1200
mVppd
—
VCC_OUT[1,2] = 2.5V±5%, Output = 1200mVppd
1000
1350
1700
mVppd
—
All output swings. 20% to 80%.
—
—
150
ps
—
High-speed Inputs/Outputs Output Switch Time using Update Enable Strobes Input Voltage Swing
Output Voltage Swing
ΔVOD
Output Rise/Fall Time
tr/tf
Duty Cycle Distortion
—
All data rates, all output swings.
-50
—
+50
ps
—
Additive Jitter
—
All inputs active, peak-to-peak (PRBS 31)
—
—
60
psp-p
—
Input Trace Equalization
—
—
0
—
12
dB
4
Range
0
—
11.2
dB
Output De-Emphasis
— Maximum Setting
9
—
—
dB
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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Table 2-4: AC Electrical Characteristics (Continued) Parameter
Symbol
Conditions
Min
Typ
Max
Units
Notes
Host Interface Parallel Rate of Operation
—
—
0.1
—
112.5
Mop/s
5, 6, 7
Serial Interface Operating Speed
—
—
0.1
—
25
MHz
5, 8
Notes: 1. See Section 4.4 for more details. 2. This parameter is the time it takes for the outputs to change to a new switch matrix configuration when the corresponding strobe signal assigned to that output is asserted. 3. DC-coupled. 4. Selectable, maximum gain occurs at 3Gb/s (or 1.5GHz). 5. Specifications relate to all host interface pins. 6. Millions of operations per second. 7. For detailed timing specifications, see Section 4.12.1. 8. For detailed timing specifications, see Section 4.12.2.
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3. Input/Output Equivalent Circuits Note: Please refer to the following supplementary documents: Crosspoint Design Guide and EB-GX3290 Schematics, PCB Layout and Bill of Materials. VCC_25_A HIZ_ACCM VCC_25_A VCC_IN[1,2] SDI[0:287] 50Ω
50Ω SDI[0:287]
EQ_TERMINATION[287:0] HIZ_ACCM
Figure 3-1: Equalizer Input Equivalent Circuit (includes the EXT_PG0 & EXT_PG1 inputs) VCC_OUT[1,2]
50Ω
50Ω
VCC_OUT[1,2] SDO[0:287]
VCC_OUT[1,2] SDO[0:287]
Delayed
Main
Figure 3-2: Trace Driver Output Equivalent Circuit (includes the MON0 & MON1 outputs) Note: the MON0 and MON1 outputs are terminated to the VCC_25_A supply.
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If the internal temperature ADCs, pattern generators, and checkers are used, these connections are required.
If the internal temperature ADCs, pattern generators, and checkers are not used, only these connections are required.
VCC_25_A
VCC_VCO_DIGITAL VCC_25_VCO0 VCC_25_VCO1 VCC_25_VCO2
267Ω
267Ω
1µF
10nF
10µF
LF_DIGITAL LF2 47nF
1µF
10µF
LF0 LF1 LF2
LF_DIGITAL 47nF
47nF
0Ω
LDO_DIGITAL LDO0 LDO1 LDO2
VCC_25_VCO0 VCC_25_VCO1 VCC_25_VCO2
VCC_VCO_DIGITAL
10nF
LF0 LF1
VCC_25_A
0Ω
LDO0 LDO1 LDO2
LDO_DIGITAL 220nF
220nF
220nF
Note 1: Each of the VCC_VCO_DIGITAL, VCC_VCO0, VCC_VCO1, and VCC_VCO2 pins require an independent RC network. Note 2: The LF_DIGITAL and LF2 pins each require an independent RC network. Note 3: The LF0 and LF1 pins each require an independent capacitor to ground. Note 4: Each of the LDO_DIGITAL, LDO0, LDO1, and LDO2 pins require an independent capacitor to ground. Note 5: VCC_VCO_DIGITAL, LF_DIGITAL and LDO_DIGITAL used for pattern generator TX0, digital communication (GSPI and APPI), and the internal temperature ADC for JNCTN_TEMP_1. VCC_VCO_DIGITAL, LF_DIGITAL and LDO_DIGITAL must always be connected. Note 6: VCC_25_VCO0, LF0, LDO0 used for pattern checker RX0 and the internal temperature ADC for JNCTN_TEMP_0. If VCC_25_VCO0, LF0, and LDO0 are not connected, pattern checker RX0 and the internal temperature ADC for JNCTN_TEMP_0 will not operate. Note 7: VCC_25_VCO1, LF1, LDO1 used for pattern checker RX1 and the internal temperature ADC for JNCTN_TEMP_2. If VCC_25_VCO1, LF1, and LDO1 are not connected, pattern checker RX1 and the internal temperature ADC for JNCTN_TEMP_2 will not operate. Note 8: VCC_25_VCO2, LF2, LDO2 used for pattern generator TX1 and the internal temperature ADC for JNCTN_TEMP_3. If VCC_25_VCO2, LF2, and LDO2 are not connected, pattern generator TX1 and the internal temperature ADC for JNCTN_TEMP_3 will not operate.
Figure 3-3: Required connections for VCC_VCO_DIGITAL, VCC_25_VCO0, VCC_25_VCO1, VCC_25_VCO2, LF_DIGITAL, LF0, LF1, LF2, LDO_DIGITAL, LDO0, LDO1 and LDO2
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DIGITAL_CL_SEL EXT_CLK_DIGITAL /2
0
EXT_CLK_DIGITAL REF_CLK_IN REF_CLK_OUT
XTAL OSC.
Pattern TX0 CMU
1
Note: The clock used to drive Pattern Generator TX0 is also used to derive the clock timing for the digital core. Therefore, GSPI/APPI interface timing and update timing will track the external clock frequency if one is selected from the EXT_CLK_DIGITAL/EXT_CLK_DIGITAL pins for Pattern Generator TX0.
BIST_RX_5 0x83C b4 EXT_CLK0 /2
0
EXT_CLK0 REF_CLK_IN REF_CLK_OUT
XTAL OSC.
Pattern RX0 CMU
1
BIST_RX_5 0x83C b6 EXT_CLK1
/2
0
CMU
1
EXT_CLK1 REF_CLK_IN REF_CLK_OUT
XTAL OSC.
Pattern RX1
BIST_TX_0 0x823 b0 EXT_CLK2
/2
0
CMU
1
EXT_CLK2 REF_CLK_IN REF_CLK_OUT
XTAL OSC.
Pattern TX1
Figure 3-4: PRBS Generator/Checker Clock Selection
Using a crystal
Using a single-ended 27MHz oscillator
REF_CLK_IN
REF_CLK_IN 1MΩ
27MHz
27MHz Oscillator
C1
REF_CLK_OUT
REF_CLK_OUT C2
Note: The value of the C1 and C2 load capacitors are dependent on the chosen crystal.
Figure 3-5: Crystal Oscillator
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4. Detailed Description 4.1 Serial Data Input Each of the GX3190 SDI inputs provide on-chip 100Ω differential terminations. Each is compatible with input differential amplitudes from 100mVppd to 1200mVppd, and input signal sources having CML outputs referred to DC supplies of 1.2V, 1.8V or 2.5V. Note that for AC-coupled inputs, the recommended supply voltage for VCC_IN1 and VCC_IN2 is 1.8V. Each of the 146 SDI input channels include frequency domain equalization, independently-programmable to one of four levels, to compensate from 0 to 47 inches (119 cm) of FR4 trace at 3Gb/s. The boost at the 1.5GHz Nyquist frequency, and recommended trace length range, are shown under EQ_BOOST[287:0], EXT_PG0_EQ_BOOST, EXT_PG1_EQ_BOOST in Table 4-1. See Figure 3-1. Each input can be powered-down independently using the corresponding EQ_POWERDOWN[287:0] or EXT_PG0_EQ_POWERDOWN or EXT_PG1_EQ_POWERDOWN bit. To accommodate input signal sources with 1.2V supplies and 1200mVppd signal amplitudes, the input common mode point should be terminated to the respective VCC_IN1 or VCC_IN2 supply. The common mode termination connection to the respective VCC_IN1 or VCC_IN2 supply of each input can be independently controlled using the EQ_TERMINATION[287:0] or EXT_PG0_EQ_TERMINATION or EXT_PG1_EQ_TERMINATION bit (see Figure 3-1 and Table 4-1). Note 1: When the HIZ_ACCM bit is set (register address 0x400h bit 0), inputs with their common mode termination not connected to VCC_IN1 or VCC_IN2 are connected to an internal common mode bias. When an input EQ is powered-down, its common mode termination is automatically disconnected from the corresponding VCC_IN1 or VCC_IN2. For each of the inputs, there are control parameters (register address 0x401h to 0x522h). See Table 4-1 below. Note 2: The EXT_PG01_SOURCE_PIN_PRBSB and EXT_PG1_SOURCE_PIN_PRBSB bits in the TEST_SETUP register must be set to connect the EXT_PG0 and EXT_PG1 pins to the matrix. Table 4-1: Serial Data Input EQ_BOOST[287:0], EXT_PG0_EQ_BOOST and EXT_PG1_EQ_BOOST bits 1:0 (binary)
Boost Applied (@ nominal 1.5GHz)
00
0dB boost
0” to 6” (15 cm) trace
01
3.5dB boost
6” (15 cm) to 16” (40 cm) trace
10
7.6dB boost
16” (40 cm) to 35” (89 cm) trace
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Table 4-1: Serial Data Input (Continued) EQ_BOOST[287:0], EXT_PG0_EQ_BOOST and EXT_PG1_EQ_BOOST bits 1:0 (binary)
Boost Applied (@ nominal 1.5GHz)
11
35” (89 cm) to 47” (119 cm) trace
12dB boost
EQ_TERMINATION[287:0], EXT_PG0_EQ_TERMINATION and EXT_PG1_EQ_TERMINATION bits 3:3
Input Termination Common Mode Point Switch to VCC_IN_1, VCC_IN_2
0
Open (see Figure 3-1)
1
Closed (see Figure 3-1)
EQ_POWERDOWN[287:0], EXT_PG0_EQ_POWERDOWN and EXT_PG1_EQ_POWERDOWN bits 4:4
Equalizer Power
0
On
1
Off
4.2 Serial Data Output Each of the GX3190 SDI outputs have two on-chip 50Ω single-ended terminations, and can be programmed to output differential amplitudes of 200mVppd, 400mVppd or 800mVppd when the corresponding VCC_OUT1 or VCC_OUT2 is connected to either 1.2V or 1.8V, or 200mVppd, 400mVppd, 800mVppd, or 1200mVppd when the corresponding VCC_OUT1 or VCC_OUT2 is connected to 2.5V. The selection of the output swing is made using the corresponding OUTPUT_SWING_SET[287:0], MON0_OUTPUT_SWING_SET or MON1_OUTPUT_SWING_SET bits, shown in Table 4-3. If the HIGH_OP_V bit is set when either the VCC_OUT1 or VCC_OUT2 supplies are 1.2V or 1.8V, the 800mVppd swing setting is no longer valid for that output bank. Swing settings for an output bank connected to a 2.5V supply are unaffected. Table 4-2: HIGH_OP_V Swing Selection HIGH_OP_V = 0
HIGH_OP_V = 1
VCC_OUTx Supply Voltage (V)
Valid Output Swing Selection (mVppd)
Valid Output Swing Selection (mVppd)
Note
1.2
200, 400, 800
200, 400
1
1.8
200, 400, 800
200, 400
—
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Table 4-2: HIGH_OP_V Swing Selection (Continued) HIGH_OP_V = 0
HIGH_OP_V = 1
VCC_OUTx Supply Voltage (V)
Valid Output Swing Selection (mVppd)
Valid Output Swing Selection (mVppd)
Note
2.5
200, 400, 800
200, 400, 800, 1200
2
Notes: 1. For an 800mVppd output swing when the corresponding VCC_OUT1 or VCC_OUT2 is connected to 1.2V, the output must be DC-coupled to a receiving device terminated to 1.2V. 2. When VCC_OUT1 or VCC_OUT2 is set to 2.5V, the HIGH_OP_V bit must be set to enable 1200mVppd swing selection.
Each of the 290 SDI output channels provide independently programmable de-emphasis, to compensate from 0 to 47 inches (119 cm) of FR4 trace at 3Gb/s. The selection of the amount of output de-emphasis is made using the corresponding OUTPUT_DEEMPHASIS[287:0], MON0_OUTPUT_DEEMPHASIS or MON1_OUTPUT_DEEMPHASIS bits, shown in Table 4-3. Each output can be independently powered-down by the setting of the corresponding bit: ACTIVE_POWER_DOWN[287:0], DYNAMIC_POWER_DOWN[287:0] together with the assigned strobe, MON0_POWER_DOWN, or MON1_POWER_DOWN. The polarity of the signal at each output can be independently inverted by setting the corresponding bit: ACTIVE_SIGNAL_INVERT[287:0], DYNAMIC_SIGNAL_INVERT[287:0] together with the assigned strobe, MON0_SIGNAL_INVERT, or MON1_SIGNAL_INVERT. Table 4-3: Serial Data Output OUTPUT_SWING_SET[287:0], MON0_OUTPUT_SWING_SET and MON1_OUTPUT_SWING_SET bits 2:0 (binary)
Output Swing
000
200mVppd
001
400mVppd
011
800mVppd
110
1200mVppd
111
Reserved. Do not use.
OUTPUT_DEEMPHASIS[287:0], MON0_OUTPUT_DEEMPHASIS and MON1_OUTPUT_DEEMPHASIS bits 5:3 (binary)
Level of De-emphasis
000
Off
100
12” (30 cm) nominal
101
24” (60 cm) nominal
110
36” (90 cm) nominal
111
48” (120 cm) nominal
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Table 4-3: Serial Data Output (Continued) ACTIVE_SIGNAL_INVERT[287:0], DYNAMIC_SIGNAL_INVERT[287:0], MON0_SIGNAL_INVERT or MON1_SIGNAL_INVERT
Status
0
Not inverted
1
Inverted
ACTIVE_POWER_DOWN[287:0], DYNAMIC_POWER_DOWN[287:0], MON0_POWER_DOWN or MON1_POWER_DOWN
Status
0
On
1
Off
4.3 Crosspoint Switch Matrix Operation The crosspoint switch matrix routes the serial digital input signals (SDI[0:287]/SDI[0:287], EXT_PG0/EXT_PG0 or EXT_PG1/EXT_PG1) to one or more serial digital outputs (SDO[0:287]/SDO[0:287], MON0/MON0 or MON1/MON1). The matrix is configured on a per output basis. Each serial digital output can be configured to accept a signal from one serial digital input. Multiple serial digital outputs can accept input from the same serial digital input. Updates to the switch matrix take place as soon as they are written to the host interface when controlling the device through the ACTIVE Configuration and Status Registers. These registers are the ACTIVE[287:0], MON0, and MON1 registers found in Section 2 of the Crosspoint (GX3290 and family) Reference Manual (for CSRs) document. Before the ACTIVE[287:0], MON0, and MON1 registers at addresses 0x200h through 0x321h can be directly used to update the crosspoint switch matrix, an initialization procedure is required. One of the UPDATE_EN[7:0] pins needs be toggled from a low state to a high state, and back to a low state again. Alternatively, set the SOFTWARE_UPDATE_ENABLE bit in the CONTROL_SETUP register at address 0xA00h to a value of 1, and then toggle one of the SOFT_UPDATE_EN[7:0] bits in the SOFT_UPDATE_CONTROL register at address 0xA01h from a value of 0 to a value of 1, and then back to a value of 0. If the ACTIVE[287:0], MON0, and MON1 registers are not being directly written by the system controller, this procedure is not required. Reading from the ACTIVE[287:0], MON0, and MON1 registers will work regardless of whether or not the above procedure is executed. Updating the crosspoint switch matrix using the DYNAMIC[287:0] registers (discussed below) does not require the initialization procedure described above. The switch matrix can also be updated using double-buffering when controlling the device through the DYNAMIC Configuration and Status Registers. These registers are DYNAMIC[287:0] in Section 1 of the Crosspoint (GX3290 and family) Reference Manual (for CSRs) document.
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When using dynamic configuration, updates to the switch matrix are first written to the DYNAMIC[287:0] registers where they are held until the corresponding update strobe signal, selected using the UPDATE_SELECT[287:0] bits in the DYNAMIC[287:0] registers, changes state from LOW-to-HIGH. The source for the update strobes can either be via external pins (UPDATE_EN[7:0]) or register bits (SOFT_UPDATE_EN[7:0]) as selected by the setting of the SOFTWARE_UPDATE_ENABLE bit in the CONTROL_SETUP register. Setting the SOFTWARE_UPDATE_ENABLE bit LOW causes the device to use the external UPDATE_EN[7:0] pins as update strobes for the switch matrix. Setting the SOFTWARE_UPDATE_ENABLE bit HIGH causes the device to use the SOFT_UPDATE_EN[7:0] bits as update strobes for the switch matrix. See Section 6 of the Crosspoint (GX3290 and family) Reference Manual (for CSRs) document. When the selected update strobe signal (or bit) transitions from LOW-to-HIGH, the state of all the outputs configured to respond to that update strobe signal (or bit) are updated at that time. Regardless of which register set is used to configure the switch matrix, the current configuration of the matrix is always available by reading back the ACTIVE[287:0] registers. Note: The MON0 and MON1 outputs can not be powered up/down, switched, or polarity inverted dynamically (Dynamic Configuration). They can only be configured in the Active Configuration mode described above using the settings in registers 0x320h and 0x321h, respectively. Also, the MON0 and MON1 outputs are terminated to the VCC_25_A supply.
4.4 Propagation Delay The propagation delay is dependent on the path that the signal takes through the device. Although the delay difference from the shortest path to the longest path could be up to 5.5ns, this difference is at a minimum for connections from inputs numerically close together and on the same side of the device to outputs that are numerically close together and on the same side of the device. Propagation delay differences of less than 750ps can be expected when the inputs are adjacent in the ballout and the outputs are also adjacent in the ballout. Note: The 750ps propagation delay difference (skew) between physically adjacent channels is guaranteed by simulation.
4.5 Using Multiple Strobes The GX3190 has eight fully-independent update strobes. Outputs 287 to 0 can be assigned to one of the eight strobes through the setting of the UPDATE_SELECT bits in the corresponding DYNAMIC[287:0] register. The input signal selection, output power switching and signal inversion will take effect on the LOW-to-HIGH edge of its assigned strobe signal or bit. This allows different portions of the crosspoint to be switched at different points in time. This is particularly useful in systems supporting multiple data or video formats, where the switch point/time varies from format to format.
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4.6 Pattern Generator and Pattern Checker 4.6.1 Pattern Generator Note 1: There are two pattern generator “Tx” blocks in the GX3190. In the following, wherever only TX0 is mentioned, the corresponding is also true for TX1. Note 2: When the PRBS Generator is disabled, the generated signal does not completely terminate. The PRBS polynomial bits must be re-written in order to terminate the signal. The two pattern generator “Tx” blocks in the GX3190 can each independently generate PRBS 27-1, PRBS 215-1, and PRBS 223-1 data patterns, or alternating 1's and 0's. The built-in clock multiplier PLLs independently synthesize rates of 270Mb/s and 2.97Gb/s from the required, external 27MHz reference clock (see Section 4.9). Other rates up to 3Gb/s can be generated by providing an external clock signal at 2x, 4x, or 22x the desired bit rate to TX1, with a maximum external clock frequency of 6GHz. Table 4-4: Tx External Clocks TX0
TX1
EXT_CLK_DIGITAL (AJ35)
EXT_CLK2 (R15)
EXT_CLK_DIGITAL (AH35)
EXT_CLK2 (T15)
While this facility exists for both TX0 and TX1, the user is cautioned that the digital core clock is derived from the TX0 data clock, and therefore interface and update timing will track the external clock frequency if one is provided to TX0. The pattern generators are enabled by the TX0_PRBS_GEN_ENABLE and TX1_PRBS_GEN_ENABLE bits (register address 0x802h, bits [1:0] respectively). The PRBS generating polynomials used are: 1. PRBS7: x7 + x6 + 1 2. PRBS15: x15 + x14 + 1 3. PRBS23: x23 + x18 + 1 The pattern generated is selected via the TX0_PRBS_POLYNOMIAL and TX1_PRBS_POLYNOMIAL bits (register address 0x800h and 0x801h respectively). Table 4-5: Generated Patterns TX0_PRBS_POLYNOMIAL[1:0] (binary)
Pattern Generated
00
PRBS7
01
PRBS15
10
PRBS23
11
Square Wave
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4.6.2 Pattern Checker The pattern checkers de-serialize incoming serial data before checking for errors in the parallel domain. Three comparison modes are supported: 1. Neutral Phase Comparison Mode. The incoming data is re-timed in a CDR, and sampled at the neutral (eye center) phase recovered by the CDR before de-serialization. Errors with respect to the supported PRBS sequences can be counted. 2. Offset Phase Comparison Mode. The phase at which the incoming data is sampled with respect to the recovered clock is adjustable over a full UI. Errors with respect to the supported PRBS sequences can be counted. By sweeping the sampling phase and counting errors at each phase, an error rate “bathtub curve” can be recorded, and the horizontal eye opening evaluated. 3. Arbitrary Data Comparison Mode. This mode can operate on arbitrary data patterns. The incoming serial data is sampled at both the neutral phase and the adjustable phase, and each of the two sampled data streams is de-serialized and the two streams are compared in the parallel domain. The pattern checker allows a true measurement of bit error rate for the supported PRBS sequences in the first two modes above. The third, arbitrary data comparison mode, gives an indication of the degree of eye closure at a given sampling phase offset, but cannot detect bit errors in the incident data. See Figure 4-1 and Figure 4-2 below.
EXT_PG0/EXT_PG0
Input 144
Output 288
Crosspoint Core (146 x 290)
MON0/MON0
Serializer/ Pattern Generator CDR
/2
Neutral Phase Deserializer
/11 Variable Phase Deserializer
/2
Pattern Generator 0
CMU
/2
Pattern Checker 0
27MHz
Pattern Checker
EXT_CLK0
EXT_CLK0
REF_CLK_OUT
REF_CLK_IN
EXT_CLK_DIGITAL
EXT_CLK_DIGITAL
xtal osc.
Figure 4-1: Simplified Pattern Generator/Checker Zero Block Diagram
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EXT_PG1/EXT_PG1
Input 145
Output 289
Crosspoint Core (146 x 290)
MON1/MON1
Serializer/ Pattern Generator CDR
/2
Neutral Phase Deserializer
/11 Variable Phase Deserializer
/2
Pattern Generator 1
CMU
/2
Pattern Checker 1
27MHz
Pattern Checker
EXT_CLK1
EXT_CLK1
REF_CLK_OUT
REF_CLK_IN
EXT_CLK2
EXT_CLK2
xtal osc.
Figure 4-2: Simplified Pattern Generator/Checker One Block Diagram Note: There are two pattern checker “Rx” blocks in the GX3190. In the following, wherever only RX0 is mentioned, the corresponding is also true for RX1. The CDR integrated in each Rx block can independently lock to data at rates of 270Mb/s, 1.485Gb/s and 2.97Gb/s. Other rates up to 3Gb/s can be analyzed by providing an external clock signal of 2x, 4x, or 22x the desired bit rate, with a maximum external clock frequency of 6GHz. Note that retiming is not possible when using an external clock signal for the Rx block. The external clock must be synchronous with any data to be checked and the RX0_PRBS_CHK_MODE bits must be set to a value of '01'. The two pattern checker “Rx” blocks in the GX3190 can each independently check PRBS 27-1, PRBS 215-1, and PRBS 223-1 data patterns. Table 4-6: Rx External Clocks RX0
RX1
EXT_CLK0 (R35)
EXT_CLK1 (AJ15)
EXT_CLK0 (T35)
EXT_CLK1 (AH15)
The error checking modes are selected by the RX0_PRBS_CHK_MODE bits and the RX1_PRBS_CHK_MODE bits (addresses 0x804h and 0x810h respectively). Table 4-7: Checking Modes RX0_PRBS_CHK_MODE[1:0] (binary)
Input Mode
00
Check data sampled at neutral phase
01
Check data sampled at adjustable phase
10 or 11
Compare nominally sampled data with phase offset data (allows eye monitoring of arbitrary patterns)
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The pattern checker will check for the PRBS pattern specified by the RX0_PRBS_POLYNOMIAL and RX1_PRBS_POLYNOMIAL bits (addresses 0x803h and 0x811h respectively). The PRBS checkers are enabled by the RX0_PRBS_ENABLE and RX1_PRBS_ENABLE bits (register address 0x81Dh[1:0]). Table 4-8: Checked Patterns RX0_PRBS_POLYNOMIAL[1:0] (binary)
Pattern Checked
00
PRBS7
01
PRBS15
10
PRBS23
The incident data can be inverted before checking by setting the corresponding RX0_INVERT_PRBS_IN or RX1_INVERT_PRBS_IN bit (address 0x803h[2:2] and 0x811h[2:2]) to '1'. The number of words to be compared is selectable via the corresponding RX0_PRBS_BER_TIME and RX1_PRBS_BER_TIME bits (registers 0x80Ah and 0x817h). Table 4-9: Compared Words RX0_PRBS_BER_TIME[3:0] (binary)
Number of words* compared (decimal)
0000
Infinite
0001
13
0010
26
0011
3277
0100
6554
0101
838861
0110
1677722
*Note: Each word is comprised of 10 bits, therefore the actual number of samples compared is 10 times the number of words compared.
The status of the two pattern checking blocks is available in the RX0_PRBS_LOCK and RX1_PRBS_LOCK, RX0_PRBS_PASS and RX1_PRBS_PASS, RX0_PRBS_FAIL and RX1_PRBS_FAIL, and RX0_PRBS_ERROR_COUNT and RX1_PRBS_ERROR_COUNT read-only bits (see register addresses 0x81Eh to 0x821h). •
RX0_PRBS_LOCK [0] - When HIGH, indicates that the pattern checker has acquired the pattern
•
RX0_PRBS_PASS [1] - When HIGH, indicates that the pattern was locked, and the specified number of words have been compared with fewer detected errors than specified by the RX0_PRBS_BER_THRESH parameter
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•
RX0_PRBS_FAIL [2] - Indicates that the test terminated in a failure condition. There are three possible failure conditions: 1. The pattern generator failed to lock in the number of attempts specified by RX0_PRBS_LOCK_ATTEMPTS (in which case RX0_PRBS_LOCK would still be '0'). 2. The pattern generator locked, but over the period of time indicated by the RX0_PRBS_LOL_TIME bits, a greater number of errors were detected than allowed by the RX0_PRBS_LOL_THRESH setting. In this error condition, the device determines that it has “lost lock“, and terminates the test. This error condition is detectable if both RX0_PRBS_LOCK and RX0_PRBS_FAIL bits are HIGH, and the value of RX0_PRBS_ERROR_COUNT is less than RX0_PRBS_BER_THRESH (the same applies for RX1_PRBS_LOCK, RX1_PRBS_FAIL and RX1_PRBS_ERROR_COUNT). 3. The pattern generator locked, but the number of errors observed exceeded the value indicated by the RX0_PRBS_BER_THRESH bits. This error is detectable if RX0_PRBS_LOCK and RX0_PRBS_FAIL are both HIGH, and the value of RX0_PRBS_ERROR_COUNT is equal or greater than the value in RX0_PRBS_BER_THRESH.
Note that the values of RX0_PRBS_LOCK and RX1_PRBS_LOCK, RX0_PRBS_PASS and RX1_PRBS_PASS, RX0_PRBS_FAIL and RX1_PRBS_FAIL, RX0_PRBS_ERROR_COUNT and RX1_PRBS_ERROR_COUNT are reset whenever any of the corresponding test parameters for the RX0 and RX1 pattern checkers are updated as well as whenever the corresponding RX0_PRBS_ENABLE or RX1_PRBS_ENABLE bits are set to '1' when previously set to '0'. To start a new PRBS test when the previous one has already been run, either re-write RX0_PRBS_BER_TIME/RX1_PRBS_BER_TIME or toggle RX0_PRBS_ENABLE/RX1_PRBS_ENABLE. Note: The pattern checkers will count zero errors if the incident data is simply a static zero.
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4.7 Horizontal Eye Measurement As explained above, the GX3190 enables the measurement of bit error “bathtub” curves at the video rates of 1485Mb/s and 2970Mb/s to assist in evaluating how much margin there is in the system. See Using the Monitoring Features of the GX3290 Application Note for more information.
4.7.1 Configuration for Horizontal Eye Measurement •
Route the input signal of interest to the MON0 or MON1 of the matrix
•
Route the monitor output of matrix to pattern checker Rx, (RX0 in the notes below) by changing the RX0_CHECK_KEY_D2A word from its default value of 512 (decimal) to 288 (decimal)
•
For a PRBS pattern, select a pattern length with a value of the RX0_PRBS_POLYNOMIAL bits set to match the source pattern, and set the RX0_PRBS_CHK_MODE bits to 1 to select the phase interpolator path
•
For an arbitrary pattern, set the RX0_PRBS_CHK_MODE bits to 2 to select the direct data comparison mode
•
Set initial sampling phase with the RX0_PHASE_INTERPOLATOR_PHASE_SEL_D2A bits (in the BIST_RX_4 register)
•
Initiate error counting as described in Section 4.6.2 above
•
Increment the sampling phase
•
Count errors
•
Repeat last two steps to cover one UI
4.8 Temperature Sensors The GX3190 has twelve on-chip temperature sensors comprised of four junction diode temperature sensors and four ADCs, each with two selectable temperature sensors. Analog output voltages can be used to determine the temperature of the chip at the junction diode temperature sensors in four different locations. An external test current is applied to each sensor, and the voltage across the sensor is measured. Note that the “A” and “K” of the pin names indicate the preferred direction of the test current, but other junctions are present internally. Test currents should be limited to 10mA or less. DTHERMA[3:0]
DTHERMK[3:0]
Figure 4-3: Temperature Sensors
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In addition to the diode temperature sensors, four ADCs, each with two selectable temperature sensors, are also provided. Digitized temperatures can be read through the device’s host interface.
thermo ADC 3
Even Outputs 0 to 288
thermo ADC 2
Even Inputs 0 to 288
Odd Inputs 1 to 289
thermo ADC 1
Crosspoint Core
Odd Outputs 1 to 289
Legend: ADC and “local” temperature sensors “remote” temperature sensors
thermo ADC 0
Package Top-view of Die
Figure 4-4: Map of Thermometer ADC Positions on Die Table 4-10: Junction Temperature Registers Thermometer ADC
Sensor Location Select Register
Result Register
0
ADC_IN_0
JNCTN_TEMP_0
1
ADC_IN_1
JNCTN_TEMP_1
2
ADC_IN_2
JNCTN_TEMP_2
3
ADC_IN_3
JNCTN_TEMP_3
Digitized 10-bit temperature values can be read through the host interface from registers JNCTN_TEMP_0 (register 0xA08h[9:0]) through JNCTN_TEMP_3 (register 0xA0Bh[9:0]). The temperature word in each register will be updated every 213 clock cycles, provided the value of the respective COUNT_PD_[3:0] bit remains LOW. When a COUNT_PD_[3:0] bit goes HIGH, the ADC is reset and the corresponding JNCTN_TEMP_[3:0] register retains its last updated value. The clock rate can be selected between 211kHz or 844kHz through the corresponding ADC_CTRL_CLK_SEL_[3:0] bits (registers 0xA04h, 0xA05h, 0xA06h and 0xA07h). The junction temperature at each temperature sensor in terms of the ADC output code is given by:
T j = 0.5489 × JNCTN_TEMP_[3:0] – 263 + δ 3 Where δ3 is the temperature uncertainty. The accuracy of the temperature sensors can be improved by calibrating the GX3190 at a known junction temperature. Without calibration, the temperature uncertainty, due to process variations and component mismatch, can be as high as ±27°C. After calibration, the uncertainty can be reduced to about ±2°C. GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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See Using the Monitoring Features of the GX3290 Application Note for more information. Table 4-11: Nominal Temperature-to-Code Conversion Tj (°C)
JNCTN_TEMP_ [3:0]
Tj (°C)
JNCTN_TEMP_ [3:0]
Tj (°C)
JNCTN_TEMP_ [3:0]
Tj (°C)
JNCTN_TEMP_ [3:0]
-40
406
2
483
44
559
86
636
-38
410
4
486
46
563
88
639
-36
414
6
490
48
567
90
643
-34
417
8
494
50
570
92
647
-32
421
10
497
52
574
94
650
-30
424
12
501
54
578
96
654
-28
428
14
505
56
581
98
658
-26
432
16
508
58
585
100
661
-24
435
18
512
60
588
102
665
-22
439
20
516
62
592
104
669
-20
443
22
519
64
596
106
672
-18
446
24
523
66
599
108
676
-16
450
26
527
68
603
110
680
-14
454
28
530
70
607
112
683
-12
457
30
534
72
610
114
687
-10
461
32
538
74
614
116
690
-8
465
34
541
76
618
118
694
-6
468
36
545
78
621
120
698
-4
472
38
548
80
625
122
701
-2
475
40
552
82
629
124
705
0
479
42
556
84
632
126
709
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4.9 27MHz Reference Clock The GX3190 requires an external 27MHz reference clock for correct operation. This clock is multiplied to generate the digital core and interface clocks, and is also used to synthesize video rate clocks in the pattern generation blocks, and to acquire video rate signals in the pattern checker blocks. The reference clock has no impact on the jitter measurement performance when the pattern checker blocks are locked to external data sources, but has a direct impact on jitter performance within the loop bandwidth of the CMU PLL in the pattern generation blocks. The 27MHz reference clock can be generated by connecting a crystal between the REF_CLK_IN and REF_CLK_OUT balls, along with appropriate loading capacitors and a feedback resistor (see Figure 3-5). Alternatively, an LVCMOS 27MHz external clock source can be connected to the REF_CLK_IN ball with the REF_CLK_OUT ball left floating. The frequency variation of the crystal (including aging, supply and temperature variation) should be less than +/-100ppm if the PRBS checking and generation features are to be used in video applications.
4.10 Device Power-Up Note 1: No power supply sequencing is required (see Section 4.11). There is a 50μs delay (tidle) between the power supplies reaching their nominal value and the device becoming operational. During this time, there should be no host interface activity, and the UPDATE_EN[7:0] pins must be held LOW. The RC filter, shown in Figure 3-3, on each of the four VCO supplies—VCC_25_VCO0, VCC_25_VCO1, VCC_25_VCO2 and VCC_VCO_DIGITAL—is required to minimize the phase noise of the PLLs in pattern generation/detection modes, but the rise time of the filter on VCC_VCO_DIGITAL in particular can impact the start-up time of the device internal clock. Note 2: In applications where power supplies reach their final voltage in under 1ms (the time for the internal clock to start), approximately two time constants of the RC filter on VCC_VCO_DIGITAL, can dominate the time for the GX3190 to emerge from reset upon power-up. In such cases, the time for VCC_VCO_DIGITAL can be traded-off against supply filtering and hence low-frequency jitter of patterns generated by Pattern Generator Zero. Note 3: RESET must be held LOW until all power supplies have stabilized.
Supply voltage
{
Nominal voltage 95% Nominal voltage
tidle
Figure 4-5: Power-Up Timing Diagram
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4.11 Device Reset The RESET pin is an active-LOW asynchronous reset for the device. Assertion of the RESET pin sets the device in its minimum power state. The minimum pulse width of the RESET signal is 10ms (treset). There is a 50μs delay (tidle) between the RESET signal going HIGH (inactive) and the device becoming operational. During this time (all of treset + tidle), there should be no host interface activity and the UPDATE_EN[7:0] pins must be held LOW. Note 1: RESET must be held LOW until all power supplies have stabilized. Note 2: Upon emerging from reset, all SDI inputs and SDO outputs are powered-down, pattern generation and checking is inactive, and all registers assume their reset values as noted in the Semtech Crosspoint (GX3290 and family) Reference Manual (for CSRs). RESET
treset
tidle
Reset Timing Diagram
4.12 Host Interface 4.12.1 Parallel Host Interface Specifications The Asynchronous Parallel Peripheral Interface (APPI) on the GX3190 device allows an external host to access internal registers using parallel read and write operations. The GX3190 APPI is selected by setting the HOST_S/P pin LOW. Note: The S_CS pin must be pulled LOW when HOST_S/P is set LOW for parallel port communication. The host interface communicates with the Control and Status Registers (CSR) over an APPI bridge. It is possible to write one register every 10ns (100MHz write update rate). It is also possible to read one register every 20ns (50MHz read update rate). The parallel interface is asynchronous. During writes, an active-LOW P_CS (Chip Select) enables the interface and ADS (Address/Data Strobe) latches 12-bit write address and 16-bit write data into the device. During reads, the same P_CS signal is used, and the ADS signal latches the 12-bit read address and then clocks out the 16-bit read data. The P_R/W signal is used to differentiate between the two access types. An auto-increment mode exists for both reads and writes. This mode is configured by way of the APPI_AUTO_INCREMENT bit in the HOST_SETUP register. See Section 6 in the Semtech Crosspoint (GX3290 and family) Reference Manual (for CSRs).
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Table 4-12: APPI Inputs/Outputs Signal Name
I/O
Description
P_CS
I
Chip Select from the host.
P_ADS
I
Address/Data Strobe from the host; used to “clock” address and write data into the chip, and to “clock” read data out of the chip.
P_R/W
I
Read/Write indication from the host; HIGH for read, LOW for write.
P_ADD[11:0]
I
Address from the host.
P_DAT[15:0]
I/O
Write data from the host, or read data to the host.
4.12.1.1 APPI External Timing for Normal Write t CSH_w t SCS_w
P_CS
t HCS_w
P_R/W t SRW_w
P_ADD [11:0]
t HRW_w A[11:0] t SA_w
P_DAT [15:0]
t HA_w
D[15:0] t SD_w
t HD_w
P_ADS t PW_w
Figure 4-6: External Timing for Normal Write Cycle Table 4-13: APPI External Timing Specifications for Normal Write Symbol
Equiv. Cycles
Min
Typ
Max
Units
P_CS LOW before P_ADS positive edge
tSCS_w
—
10.0
—
—
ns
P_CS hold time after P_ADS positive edge
tHCS_w
2
14.8
—
—
ns
P_R/W low before P_CS negative edge
tSRW_w
—
1.5
—
—
ns
P_R/W hold time after P_ADS positive edge
tHRW_w
2
14.8
—
—
ns
P_ADD[11:0] setup before P_ADS positive edge
tSA_w
—
10.0
—
—
ns
P_ADD[11:0] hold after P_ADS positive edge
tHA_w
—
5.0
—
—
ns
P_DAT[15:0] setup before P_ADS positive edge
tSD_w
—
5.0
—
—
ns
P_DAT[15:0] hold after P_ADS positive edge
tHD_w
—
5.0
—
—
ns
P_ADS LOW pulse width
tPW_w
0.6
4.4
—
—
ns
P_CS HIGH before next read/write cycle
tCSH_w
5
37.0
—
—
ns
—
—
—
—
16.17
MHz
Parameter
Frequency for back-to-back single writes
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4.12.1.2 APPI External Timing for Auto-Increment Write
t CSH_w
P_CS t SCS_w
P_R/W
t HCS_w
t SRW_w
P_ADD [11:0]
t HRW_w An [11:0] t SA_w
P_DAT [15:0]
t HA_w
Dn [15:0] t SD_w
Dn+1 [15:0] t HD_w
t SD_w
t HD_w
P_ADS t PW_w
t ADSH_w
t PW_w
Figure 4-7: External Timing for Auto-Increment Write Cycle
Table 4-14: APPI External Timing Specifications for Auto-Increment Write Symbol
Equiv. Cycles
Min
Typ
Max
Units
P_CS LOW before P_ADS positive edge
tSCS_w
—
10.0
—
—
ns
P_CS hold time after last P_ADS positive edge
tHCS_w
2
14.8
—
—
ns
P_R/W LOW before P_CS negative edge
tSRW_w
—
1.5
—
—
ns
P_R/W hold time after P_ADS positive edge
tHRW_w
2
14.8
—
—
ns
P_ADD[11:0] setup before P_ADS positive edge
tSA_w
—
10.0
—
—
ns
P_ADD[11:0] hold after P_ADS positive edge
tHA_w
—
5.0
—
—
ns
P_DAT[15:0] setup before P_ADS positive edge
tSD_w
—
4.0
—
—
ns
P_DAT[15:0] hold after P_ADS positive edge
tHD_w
—
4.0
—
—
ns
P_ADS LOW pulse width
tPW_w
0.6
4.4
—
—
ns
tADSH_w
0.6
4.4
—
—
ns
P_CS HIGH before next read/write cycle
tCSH_w
5
37.0
—
—
ns
Frequency during auto-increment write
—
—
—
—
112.5
MHz
Parameter
P_ADS HIGH before next pulse
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4.12.1.3 APPI External Timing for Normal Read t CSH_r
P_CS
t HCS_r
t SCS_r
t CDZ
P_R/W t HRW_r
t SRW_r
t RDZ
P_ADD [11:0]
A[11:0] t SA_r
P_DAT [15:0]
t HA_r
t DNZ D[15:0] t DO
P_ADS t PW_r
Figure 4-8: External Timing for Normal Read Cycle
Table 4-15: APPI External Timing Specifications for Normal Read Symbol
Equiv. Cycles
Min
Typ
Max
Units
—
1
—
—
—
—
P_CS LOW before P_ADS negative edge
tSCS_r
—
5.0
—
—
ns
P_CS hold time after P_ADS positive edge
tHCS_r
—
5.0
—
—
ns
P_R/W HIGH before P_CS negative edge
tSRW_r
—
1.5
—
—
ns
P_R/W hold time after P_ADS positive edge
tHRW_r
—
5.0
—
—
ns
P_ADD[11:0] setup before P_ADS negative edge
tSA_r
—
0.0
—
—
ns
P_ADD[11:0] hold after P_ADS positive edge
tHA_r
—
0.0
—
—
ns
P_DAT[15:0] out of tristate after P_ADS negative edge
tDNZ
2
14.8
—
—
ns
P_DAT[15:0] becomes valid after P_ADS negative edge
tDO
—
—
—
65.0
ns
P_DAT[15:0] goes tristate after P_CS positive edge
tDZ
—
—
—
45.0
ns
P_DAT[15:0] goes tristate after P_ADS positive edge
tDZ
—
—
—
45.0
ns
P_ADS LOW pulse width
tPW
—
65.0
—
—
ns
P_CS HIGH before next read/write cycle
tCSH_r
3
22.2
—
—
ns
Frequency for back-to-back single reads
—
—
—
—
10.29
MHz
Parameter Internal read pipeline delay (0 if one-cycle read)
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4.12.1.4 APPI External Timing for Auto-Increment Read t CSH_r t SCS_r
P_CS
t HCS_r t CDZ
P_R/W
t HRW_r
t SRW_r
t RDZ
P_ADD [11:0]
An[11:0] t SA_r
P_DAT [15:0]
t HA_r t DNZ Dn [15:0] t DO1
Dn+1 [15:0] t DX t DO2
Dn+2 [15:0]
t DX
t DX t DO2
P_ADS t PW1_r
t ADSH_r
t PW2_r
t PW2_r
t ADSH_r
Figure 4-9: External Timing for Auto-Increment Read Cycle Table 4-16: APPI External Timing Specifications for Auto-Increment Read Symbol
Equiv. Cycles
Min
Typ
Max
Units
—
1
—
—
—
—
P_CS LOW before first P_ADS positive edge
tSCS_r
—
5.0
—
—
ns
P_CS hold time after last P_ADS positive edge
tHCS_r
—
5.0
—
—
ns
P_R/W HIGH before P_CS negative edge
tSRW_r
—
1.5
—
—
ns
P_R/W hold time after last P_ADS positive edge
tHRW_r
—
5.0
—
—
ns
P_ADD[11:0] setup before P_ADS negative edge
tSA_r
—
0.0
—
—
ns
P_ADD[11:0] hold after P_ADS positive edge
tHA_r
—
0.0
—
—
ns
P_DAT[15:0] out of tristate after P_ADS negative edge
tDNZ
2
14.8
—
—
ns
P_DAT[15:0] becomes valid after first P_ADS negative edge
tDO1
—
—
—
70.0
ns
P_DAT[15:0] becomes valid after P_ADS positive edge
tDO2
—
—
—
13.0
ns
P_DAT[15:0] becomes invalid after P_ADS positive edge
tDX
—
3.0
—
—
ns
P_DAT[15:0] goes tristate after P_CS positive edge
tDZ
—
12.0
—
45.0
ns
P_DAT[15:0] goes tristate after P_ADS positive edge
tDZ
—
12.0
—
45.0
ns
P_ADS first LOW pulse width
tPW1_r
—
70.0
—
—
ns
P_ADS subsequent LOW pulse widths
tPW2_r
1.2
8.9
—
—
ns
P_ADS HIGH between pulses
tADSH_r
1.2
8.9
—
—
ns
P_CS HIGH before next read/write cycle
tCSH_r
5
37.0
—
—
ns
Frequency during auto-increment read
—
—
—
—
56.25
MHz
Frequency for back-to-back single reads in auto-increment mode
—
—
—
—
8.54
MHz
Parameter Internal read pipeline delay (0 if one-cycle read)
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4.12.2 Serial Host Interface Specifications The Gennum Serial Peripheral Interface (GSPI) handles the communication with an external host over the SPI port. It allows configuration of the Control and Status Registers (CSR) using serial read and write operations. The GX3190 GSPI is selected by setting the HOST_S/P pin HIGH. Note 1: The P_CS pin must be pulled LOW when HOST_S/P is set HIGH for serial port communication. The GX3190 uses a four-wire protocol, with serial communication via the input SDIN pin, the output SDOUT pin, clock input signal (SCLK), and the chip select signal (S_CS). The signalling rate can be up to 25Mb/s. The interface uses 16-bit data and a 16-bit address/control. The 16-bit address and control consists of a 12-bit address, one read/write bit (‘1’ for read, ‘0’ for write), one bit for auto-increment and two unused bits. The four-wire protocol is implemented as shown in Figure 4-10 and Figure 4-11. When the Auto-Increment bit is set LOW, each Command Word must be followed by only one Data Word to ensure proper operation. If the Auto-Increment bit is set HIGH, the following Data Word is written into the address specified in the Command Word, and subsequent Data Words are written into incremental addresses from the first Data Word. This facilitates multiple address reads or writes without sending a Command Word for each Data Word. Table 4-17: GSPI Inputs/Outputs Signal Name
I/O
Reference Clock
SCLK
I
—
SDIN
I
SCLK
GSPI serial data input
SDOUT
O
SCLK
GSPI serial data output (on the negative edge of SCLK)
S_CS
I
—
t0
t1
Description GSPI clock
GSPI Chip Select
t2
t4
t7
SCLK t3
t8
S_CS SDIN SDOUT
R
R/W
RSV
RSV
RSV
RSV
Auto_Inc
Auto_Inc
A11
A11
A10
A10
A9
A9
A8
A8
A7
A7
A6
A6
A5
A5
A4
A4
A3
A3
A2
A2
A1
A1
A0
A0
D15
D15
D14
D14
D13
D12
D13
D12
D11
D11
D10
D10
D9
D9
D8
D8
D7
D7
D6
D6
D5
D5
D4
D4
D3
D3
D2
D2
D1
D1
D0
D0
SDIN signal is looped out on SDOUT
Figure 4-10: Serial Host Interface Timing Diagram - Write Mode
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t5 t9 SCLK t6 S_CS SDIN SDOUT
R/W
R/W
RSV
RSV
RSV
RSV
Auto_Inc
A11
Auto_Inc
A11
A10
A10
A9
A9
A8
A8
A7
A6
A7
A6
A5
A5
A4
A4
A3
A3
A2
A2
A1
A1
A0
A0
D15
D14
D13
SDIN signal is looped out on SDOUT
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Read Data is output on SDOUT
Figure 4-11: Serial Host Interface Timing Diagram - Read Mode
Table 4-18: Serial Host Interface Timing Parameter
Symbol
Conditions
Equiv. Cycles
Min
Typ
Max
Units
S_CS LOW before SCLK positive edge
t0
—
7.0
—
—
ns
SCLK frequency
—
—
0.1
—
25.0
MHz
SCLK period
t1
—
40.0
—
10,000
ns
SCLK duty cycle
t2
—
40.0
50.0
60.0
%
Input data setup time
t3
—
7.0
—
—
ns
Time between end of Command Word (or previous data word in Auto-Increment mode) and the first SCLK of the following Data Word write cycle
t4
—
40.0
—
—
ns
Time between end of Command Word (or previous data word in Auto-Increment mode) and the first SCLK of the following Data Word read cycle
t5
—
70.0
—
—
ns
SDO hold time after SCLK negative edge
t6
—
5.0
—
16.0
ns
S_CS HIGH after last SCLK negative edge
t7
1.2
9.0
—
—
ns
Input data hold time
t8
—
5.0
—
—
ns
S_CS HIGH time
t9
2.5
18.5
—
—
ns
50% levels; 3.3V or 1.8V operation
70ns (t5) = 5 clock cycles at 135MHz plus SCLK and SDO signal propagation. 18.5ns (t9) = 2.5 clock cycles at 135MHz. Max t6 (16ns) represents the latest time by which the SDO will be stable after the SCLK negative edge. As SDO must be sampled on the SCLK positive edge, this determines the minimum SCLK period, and therefore the maximum SCLK frequency. SDO maximum transition time with 15pF load: 2ns. SDO maximum transition time with 50pF load: 5ns.
Note 2: The GSPI and APPI are mutually exclusive (they can not both be used at the same time).
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5. Application Information Note: Please refer to the following supplementary documents: •
Crosspoint Design Guide
•
EB-GX3290 Schematics, PCB Layout and Bill of Materials
5.1 Power Supply Filtering and Recommendations One of the most important steps that PCB designers can take to ensure power supply integrity for the GX3190 device is to design the PCB layer stack-up to minimize power plane pair inductance. Locating supply planes adjacent to ground planes, and separated by minimum thickness dielectrics in the stack-up, will minimize plane-pair inductance, and incidentally maximize the plane pair capacitance. Holes and cuts in the planes should be avoided as much as possible. While such closely spaced plane pairs allow the lowest inductance connections to supply pins of the GX3190 when they are closest to the device mounting surface of the PCB, the need to balance PCB stack-ups will lead to closely spaced layers on the far side of the PCB. The supply currents drawn from the VDD_18 and VDDIO_D supplies are noisy and activity dependent, and the corresponding supply/ground plane pairs should be treated as for FPGA or CPU devices. Supply currents drawn from the VCC_25_A, VCC_IN1, VCC_IN2, VCC_OUT1 and VCC_OUT2 supplies are continuous except under changes of the high speed signal path configuration. The VCC_OUT1 and VCC_OUT2 supplies in particular are subject to rapid steps in current under some configuration changes: the maximum combined current draw of the VCC_OUT1 and VCC_OUT2 supplies, 8.52A, can be switched in as little as 10ns. This current step may be reduced by appropriate programming of the device. Locating point of use voltage regulators close to the GX3190 device on the PCB will maximize the regulation roll-off frequency. At the highest frequencies, the GX3190 package and mounting parasitics will limit the effectiveness of any measures on the PCB to suppress voltage ripple on the device supplies. In between the voltage regulator roll off frequencies and the frequencies where parasitics on each supply domain within the GX3190 isolate the die from the PCB, decoupling capacitors on the PCB are effective. PCB layout effort should be spent on details of the decoupling capacitor mounting layout. Some simple layout measures can help to reduce the inductance of capacitor mounting. See the Crosspoint Design Guide for more detailed recommendations.
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5.2 Estimated Worst-Case Load Current Steps Under normal operation, the power supply networks need to minimize voltage transients due to configuration change related load current steps. When the device reset is asserted while the device is drawing significant current, the load on power supplies could be shed fast enough to raise concerns about the board level voltage regulator dynamics, and the impact of any power supply network inductance.
5.2.1 VCC_25_A Supply The tail currents of CML blocks (the high-speed signal paths) in the matrix switch relatively slowly, with worst case switching times of 30ns and typical times ~50ns. The matrix supply current of ~9.3A could in principle switch in 30ns, but in practice the propagation delay of UPDATE_EN[7:0] signals across the matrix will increase the switching time somewhat. The VCC_25_A supply current drawn by individual EQs takes more than 10ns to rise upon application of control signals. The VCC_25_A supply current drops in as little as 5ns upon assertion of reset, though, and the reset signal arrival times at EQs in a bank are roughly uniformly distributed over an interval of 0.8ns. This means that the VCC_25_A current drawn by all EQs together, ~1.8A, could be shed in 5.8ns. The trace drivers draw significant current from the VCC_25_A supply, up to ~4.7A total for all trace drivers together, and this current can rise in as little as 20ns upon the de-assertion of power-down signals, or fall in as little as 1ns upon the assertion of power-down or reset signals. The arrival times of power-down or reset signals within the bottom trace driver bank are nearly uniformly distributed over an interval of 0.8ns, while the arrival time of power-down or reset signals within the top trace driver bank are nearly uniformly distributed over an interval of 4.4ns. The worst case total load current slew rate on the VCC_25_A supply is estimated from the above to be ~1.9GA/s.
5.2.2 VCC_OUT1, VCC_OUT2 Supplies In simulation, the tail currents of trace driver output stages turn on in as little as 10ns. Should all outputs be configured for maximum swing and enabled simultaneously, the load current step on each of VCC_OUT1, VCC_OUT2 would be as high as 4.26A (for AC-coupled applications) in ~14ns, 11ns respectively (including the propagation delay spread noted above). That large dI/dt can be reduced by appropriate programming of updates. The VCC_OUT1 and VCC_OUT2 supply current drawn by each trace driver drops in as little as 1ns upon the assertion of device reset. The greater spread of signal arrival times in the top bank leads to a significantly smaller magnitude of dI/dt on the VCC_OUT1 supply than on the VCC_OUT2 supply.
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5.2.3 VCC_IN1, VCC_IN2 Supplies The controls for the equalizers are serialized, and hence power switching of the equalizers in mission mode is staggered in time. Assertion of reset will however lead to more nearly synchronous shedding of load. The typical current drawn from the VCC_IN1 and VCC_IN2 supplies is 0.85A each, and this can be shed in 1ns, including the reset signal propagation delay. Table 5-1: Summary
Supply
Maximum Current (A)
Maximum Positive dI/dt
Maximum Negative dI/dt (reset/simultaneous power-down)
VCC_25_A
15.8
0.62GA/s
-1.9GA/s
VCC_OUT1
4.26
0.42GA/s
-1.4GA/s
VCC_OUT2
4.26
0.54GA/s
-3.6GA/s
VCC_IN1
0.85(typ)
<0.1GA/s
-0.9GA/s
VCC_IN2
0.85(typ)
<0.1GA/s
-0.9GA/s
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6. Package and Ordering Information 6.1 Package Dimensions 50mm x 50mm FCBGA (1mm pitch) Top View
Bottom View 0.20 (4X) A
50.00
A1 Ball Pad Corner
38.00 A1 Ball Pad Corner
A
48 46 44 42 40 38 36 34 32 30 28 26 24 22 20 18 16 14 12 10 8 6 4 2 49 47 45 43 41 39 37 35 33 31 29 27 25 23 21 19 17 15 13 11 9 7 5 3 1 A C
1.00 Φ1.35±0.25
38.00 50.00
(4.00)
4X (6.00)
A
B
D E F G H J K L M N P R T U V W Y AA AB AC AD AE AF AG AH AJ AK AL AM AN AP AR AT AU AV AW AY BA BB BC BD BE BF BG BH BJ
B
4X (6.00)
(4.00)
1.00
Side View 36.00
3.69±0.12 0.50±0.05
C
0.20 C
+0.06 Φ0.60 –0.14 Φ0.25 M C A B Φ0.10 M C Section A–A
Figure 6-1: Package Dimensions
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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6.2 Package Thermal Data and Information Table 6-1: Package Thermal Data and Information Parameter
Value
Package Type
50mm x 50mm HFC BGA
Moisture Sensitivity Level
3
Junction to Case Thermal Resistance, θj-c
0.31°C/W
Junction to Air Thermal Resistance, θj-a (at zero airflow)
N/A. This device requires a heat sink. See Semtech’s Crosspoint Design Guide.
Junction to Board Thermal Resistance, θj-b
2.1°C/W
Pb-free and RoHS Compliant
Yes
6.3 Marking Diagram Pin 1 Indicator
GX3190 ZZZZZZE3 XXXXXX-YYWW
Instructions: GX3190 ZZZZZZ E3 XXXXXX YYWW
Package Mark Marking batch work order information Pb-free & Green indicator Assembly batch work order information Date Code
Figure 6-2: Marking Diagram
GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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6.4 Solder Reflow Profile The GX3190 is available in a Pb-free package. It is recommended that the Pb-free package be soldered with Pb-free paste using the reflow profile shown in Figure 6-3. Device Surface Temperature (°C)
Peak 245°C
250
230°C
1.0 - 2.0°C/s
200 180°C
150
Pre Heating Zone Soldering Zone
150°C 60 - 120s
100 10 - 15s
1.5 - 2.0°C/s
50 1.0 - 2.0°C/s
Heating Time
Figure 6-3: Maximum Pb-free Solder Reflow Profile
6.5 Ordering Information Table 6-2: Ordering Information Part Number
Package
Temperature Range
GX3190-CBE3
50x50mm HFC-BGA
0°C to 85°C
Appendix - Relevant Documentation Table 6-3: Relevant Documentation Document Description
Document Identification
EB-GX3290 Schematics, PCB Layout and Bill of Materials
GENDOC-056057
GX3290 Host Control Software User Manual
GENDOC-055970
Using the Monitoring Features of the GX3290 Application Note
GENDOC-058329
GX3290 (and family) Crosspoint Ball Guide
GENDOC-056697
Crosspoint Design Guide
GENDOC-056004
Crosspoint (GX3290 and family) Reference Manual (for CSRs)
GENDOC-056832
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DOCUMENT IDENTIFICATION
CAUTION
FINAL DATA SHEET
ELECTROSTATIC SENSITIVE DEVICES
Information relating to this product and the application or design described herein is believed to be reliable, however such information is provided as a guide only and Semtech assumes no liability for any errors in this document, or for the application or design described herein. Semtech reserves the right to make changes to the product or this document at any time without notice.
DO NOT OPEN PACKAGES OR HANDLE EXCEPT AT A STATIC-FREE WORKSTATION
© Semtech 2012 All rights reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent or other industrial or intellectual property rights. Semtech assumes no responsibility or liability whatsoever for any failure or unexpected operation resulting from misuse, neglect improper installation, repair or improper handling or unusual physical or electrical stress including, but not limited to, exposure to parameters beyond the specified maximum ratings or operation outside the specified range. SEMTECH PRODUCTS ARE NOT DESIGNED, INTENDED, AUTHORIZED OR WARRANTED TO BE SUITABLE FOR USE IN LIFE-SUPPORT APPLICATIONS, DEVICES OR SYSTEMS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF SEMTECH PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD TO BE UNDERTAKEN SOLELY AT THE CUSTOMER’S OWN RISK. Should a customer purchase or use Semtech products for any such unauthorized application, the customer shall indemnify and hold Semtech and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs damages and attorney fees which could arise. Notice: All referenced brands, product names, service names and trademarks are the property of their respective owners.
Contact Information Semtech Corporation Gennum Products Division 200 Flynn Road, Camarillo, CA 93012 Phone: (805) 498-2111, Fax: (805) 498-3804 www.semtech.com GX3190 146 x 290 3.5Gb/s Crosspoint Final Data Sheet Rev. 2 GENDOC-056076 March 2013
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