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GENLINX™ II
GX9533 Serial Digital 8x9 Crosspoint
Data Sheet
8494 - 4 November 2009
GENLINX™ II
GX9533 Serial Digital 8x9 Crosspoint
www.gennum.com
Features
• operation beyond 622Mb/s
•accepts SMPTE and PECL input levels
• fully differential signal path
• on-chip PECL current loads eliminate need for external
pull-down resistors
• capable of driving 100Ω differential loads
• very low 500mW power consumption
• additional expansion port input for construction of
larger matrices
• auxiliary monitoring output
• easy to configure
• double latched address inputs with separate load and
configure
• TTL/CMOS compatible control logic inputs
•single 5V power supply
Applications
• Serial digital video switching
• Datacom or telecom switching
Description
The GX9533 is a high speed 8x9 serial digital crosspoint. An
expansion input port eases the design of larger switching
matrices by reducing PCB layers and eliminating the need
for cascaded secondary switching. Decode logic and
double level latching to configure the matrix are included
on chip. Separate LOAD and CONFIGURE inputs allow for
asynchronous configuration and synchronous switching.
These latches can also be made transparent for
asynchronous switching by pulling the LOAD and
CONFIGURE pins high.
In the power saving (PS) mode, the GX9533 has a very low
power consumption of 500mW. This is accomplished by
driving a 400mV output swing into the on-chip 200Ω
differential load termination in the expansion port of the
next GX9533. This architecture provides a significant
power savings and the elimination of external load
resistors or impedance matching resistors. In applications
where standard PECL levels are necessary, the GX9533 can
be configured in "PECL Mode", to drive 800mVp-p into a
100Ω differential load. The power consumption in this
mode increases to 860mW.
Figure A: GX9533 Functional Block Diagram
IN0 .. 7
EXP0..7
AUX IN
OA0..2
IA0..3 VCC
AUX
VEE
VCCO
STD/PECL1
STD/PECL2
CONFIG
LOAD A
LOAD
CONFIG
LATCH
LOAD
LATCH
16
16
16
16
3
4
22
2
OUT 0..7
DECODE
LOGIC
SWITCHING
MATRIX
INPUT
BUFFER
OUTPUT
BUFFER
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Data Sheet
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Revision History
Contents
Features.................................................................................................................................................................1
Applications.........................................................................................................................................................1
Description...........................................................................................................................................................1
Revision History .................................................................................................................................................2
1. Pin Connections .............................................................................................................................................3
1.1 Pin Connections ................................................................................................................................3
2. Electrical Characteristics ............................................................................................................................6
2.1 Absolute Maximum Ratings ..........................................................................................................6
2.2 DC Electrical Characteristics ........................................................................................................6
2.3 Power Save 1 Mode ..........................................................................................................................7
2.4 Power Save 2 Mode ..........................................................................................................................7
2.5 PECL Mode ..........................................................................................................................................7
2.6 AC Electrical Characteristics ........................................................................................................8
3. Detailed Description.....................................................................................................................................9
3.1 Differential Inputs ............................................................................................................................9
3.2 I/O Address Selection ......................................................................................................................9
3.2.1 Stage One: Loading the Configuration Into Latches .................................................9
3.2.2 Stage Two: Configuring the Matrix.............................................................................. 10
3.3 Output Level Select ....................................................................................................................... 11
4. Using the GX9533 to Expand Larger Matrices.................................................................................. 13
4.1 Bus Through™ Pin Connections ...............................................................................................13
4.2 Expansion Port Input .................................................................................................................... 13
5. Package Dimensions.................................................................................................................................. 14
6. Ordering Information................................................................................................................................ 15
Version Date Changes and/or Modifications
4 November 2009 Updated to latest Gennum template and changed from
document number 52141 to 8494.
3 August 1999 Changes to document format.
2 – Revisions made.
1 April 1995 New document.
GX9533 Serial Digital 8x9 Crosspoint
Data Sheet
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1. Pin Connections
1.1 Pin Connections
Figure 1-1: GX9533 Pin Connections
STD/PECL1
NC
NC
LOAD
NC
NC
LOADA
NC
NC
CNFG
NC
NC
IA0
NC
NC
IA1
NC
NC
IA2
NC
NC
IA3
NC
NC
OA0
OA1
OA2
VEE
AUX_OUT
AUX_OUT
VCC
IN0
IN0
VEE
IN1
IN1
VEE
IN2
IN2
VEE
IN3
IN3
VEE
IN4
IN4
VEE
IN5
IN5
VEE
IN6
IN6
VEE
IN7
IN7
VEE
VEE
VCC
VEE
OUT0
OUT0
OUT1
OUT1
VCCO
OUT2
OUT2
VCCO
OUT3
OUT3
VCCO
OUT4
OUT4
VCCO
OUT5
OUT5
VCCO
OUT6
OUT6
VCCO
OUT7
OUT7
EXP0
EXP0
EXP1
EXP1
EXP2
EXP2
EXP3
EXP3
VCC
EXP4
EXP4
EXP5
EXP5
EXP6
EXP6
EXP7
EXP7
AUX_IN
AUX_IN
STD/PECL2
GX9533
TOP VIEW
GX9533 Serial Digital 8x9 Crosspoint
Data Sheet
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Figure 1-2: Data Flow Diagram
Table 1-1: Pin Descriptions
Symbol Typ e Description
IN0 to IN7, IN0 to IN7 I Differential data inputs.
OUT0 to OUT7, OUT0 to OUT7 O Differential data outputs.
AUX_OUT, AUX_OUT O Auxiliary port output.
AUX_IN, AUX_IN I Auxiliary port input.
OA0 to OA2 I Output address select.
IA0 to IA3 I Input address select.
LOAD I Loads input & output address.
LOADA I Loads auxiliary input address.
STD/ECL1, STD/ECL2 Resistor connection for Power Save mode or PECL
mode. Refer to Table 3-3.
CNFG I Switch configuration.
EXP0 to EXP7, EXP0 to EXP7 I Expansion port inputs.
VCC Positive power supply.
VCCO Positive power supply (PECL outputs).
VEE Negative power supply.
Standard
Inputs
Auxilliary
Input
Auxilliary
Output
Main
Outputs
0
1
2
3
4
5
6
7
8
INPUT BUFFERS
012
3
45
7
6
Expansion
Inputs
01
2
3
45
7
6
4x1
Switch
3x1
Switch
4x1
Switch
4
5
6
7
0
1
2
3
4x1
Switch
45
7
6
0123
4x1
Switch
3x1
Switch
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Data Sheet
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Figure 1-3: Typical Eye Opening vs Bit Rate
700 800 900 1000 1100
100
90
80
70
60
50
BIT RATE (Mb/s)
% OPENING
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2. Electrical Characteristics
2.1 Absolute Maximum Ratings
Table 2-1 lists the absolute maximum ratings for the GX9533. Conditions exceeding the
limits listed may cause permanent damage to the device. This is a stress rating only and
functional operation of the device at these or any other conditions above those listed in
the operational sections of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect device reliability.
2.2 DC Electrical Characteristics
Table 2-2 shows the DC electrical characteristics of the GX9533 where conditions are
VCC = 5V, VEE = 0V, TA = 0 to 70°C, unless otherwise shown.
Table 2-1: Absolute Maximum Ratings
Parameter Value
Supply Voltage (VS = VCC-VEE)5.5V
Input Voltage Range (any input) -0.3 to (VCC+0.3)V
Power Dissipation 975mW
Operating Temperature Range 0°C to 70°C
Storage Temperature Range -65°C to +150°C
Lead Temperature Range (soldering, 10 sec) 260°C
Table 2-2: DC Electrical Characteristics
Parameter Conditions Min Ty p Max Units
Supply Voltage - 4.75 5.0 5.25 V
ECL Input Voltage Swing - 200 800 1200 mV
p-p
ECL Common Mode Input
Voltage Range
with 1200mV
input signal swing
2500 - VCC-600 mV
Logic
Input
Voltage
High - 2.0 - VCC V
Low - 0 - 0.8 V
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2.3 Power Save 1 Mode
Table 2-2 shows the Power Save 1 Mode electrical characteristics of the GX9533 where
conditions are RSET = 4kΩ, unless otherwise shown.
2.4 Power Save 2 Mode
Table 2-2 shows the Power Save 1 Mode electrical characteristics of the GX9533 where
conditions are RSET = 6kΩ, unless otherwise shown.
2.5 PECL Mode
Table 2-2 shows the PECL Mode electrical characteristics of the GX9533 where
conditions are RSET = 6kΩ, unless otherwise shown.
Table 2-3: Power Save 1 Mode
Parameter Conditions Min Ty p Max Units
Supply Current RL = 100Ω- 115 150 mA
Output Common Mode
Voltage
VCC-1200 - VCC-800 mV
Output Voltage Swing 300 450 600 mV
Output
Voltage
High VCC-950 - VCC-600 mV
Low VCC-1400 - VCC-1000 mV
Table 2-4: Power Save 2 Mode
Parameter Conditions Min Ty p Max Units
Supply Current RL = 200Ω- 100 130 mA
Output Common Mode
Voltage
VCC-1200 - VCC-800 mV
Output Voltage Swing 300 450 600 mV
Output
Voltage
High VCC-950 - VCC-600 mV
Low VCC-1400 - VCC-1000 mV
Table 2-5: PECL Mode
Parameter Conditions Min Ty p Max Units
Supply Current RL = 100Ω- 170 185 mA
Output Common Mode
Voltage
VCC-1450 - VCC-1050 mV
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Data Sheet
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2.6 AC Electrical Characteristics
Table 2-2 shows the AC electrical characteristics of the GX9533 where conditions are
VCC = 5V, VEE = 0V, TA = 0 to 70°C, unless otherwise shown.
Output Voltage Swing 700 800 900 mV
Output
Voltage
High VCC-1200 - VCC-650 mV
Low VCC-1850 - VCC-1450 mV
Table 2-5: PECL Mode (Continued)
Parameter Conditions Min Ty p Max Units
Table 2-6: AC Electrical Characteristics
Parameter Symbol Conditions Min Typ Max Units
Maximum Input Data Rate - For 90% eye opening - 850 - Mb/s
Additive
Jitter
See Note 1.
Standard Input - 143 to 622 Mb/s, all
hostile crosstalk
-80-ps p-p
Expansion Input - - 70 - ps p-p
Data In to
Data Out
Delay
Standard Input tDLY Average of all channels - 1.7 - ns
Expansion Input - - 1.1 - ns
Propagation
Delay Match
Standard Input - - - 350 - ps
Expansion Input - - - 250 - ps
CONFIGURE
to Data Out
Delay
Main Out tCD --10-ns
AUX Out - - 11 - ns
LOAD/LOADA Pulse Width tLP -20--ns
CONFIGURE Pulse Width tCP -20--ns
IAN to LOAD/LOADA High Setup
Time
tILS -30--ns
LOAD/LOADA to IAN Low Hold Time tILH -0--ns
OAN to LOAD High Setup Time tOLS -30--ns
LOAD to OAN Low Hold Time tOLH -0--ns
LOAD High to CONFIGURE High tLC -0--ns
Output Rise/Fall Time - - - 700 - ps
NOTE:
1. Use RMS addition to calculate additive jitter through cascaded devices.
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3. Detailed Description
3.1 Differential Inputs
The inputs to the GX9533 will accept both SMPTE 259M as well as PECL input levels. The
fully differential data path provides low jitter data rates of up to 700Mb/s.
The main inputs (IN0..7) and expansion inputs (EXP0..7) are normally connected to a
biased differential data source. The GX9533 inputs are not self biased, so unused inputs
should be connected as shown in Figure 3-1 or Figure 3-2.
Figure 3-1: Preferred Termination Of Unused Inputs
Figure 3-2: Alternate Termination of Unused Inputs
Terminating the inputs as shown in Figure 3-1 will provide the highest noise immunity,
since there is no possibility of noise coupling into the unconnected input pin.
3.2 I/O Address Selection
The GX9533 has a versatile LOAD/CONFIGURE architecture which simplifies IN/OUT
switch configuration.
An output is normally connected to an input by a two stage process:
3.2.1 Stage One: Loading the Configuration Into Latches
1. The output address is selected on the OA pins as shown in Table 3-1.
2. The input address is selected on the IA pins as shown in Table 3-2.
3. A LOAD pulse then transfers the output and input addresses into the GX9533 LOAD
latch.
The above three steps can be repeated up to eight times in order to configure the latch
for all eight outputs.
INx
INx
GX9533
VCC
1k
IN
X
IN
X
GX9533
V
CC
NC
Table 3-1: Output Address Selection
Table 3-2: Input Source Address Selection
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During step 3 above, if the LOADA pulse is also strobed, the latch is configured to
connect the selected input to the ninth, auxiliary output.
Note that a QUIET mode is available as shown in Table 3-2. In QUIET mode, the outputs
are latched in a DC state with OUTX = 1 and OUTX = 0.
3.2.2 Stage Two: Configuring the Matrix
A CONFIGURE strobe is applied to transfer the contents of the LOAD latch into the
CONFIG latch. This action will cause the data flow through the GX9533 to be switched
to the new configuration. Refer to Figure 3-4 for detailed timing information.
Note that any single output can be asynchronously switched by having LOAD (or
LOADA if desired) held high while CONFIG is strobed.
OA2 0A1 0A0 OUTPUT PORT
0000
0011
0102
0113
1004
1015
1106
1117
IA3 IA2 IA1 IA0 INPUT PORT
00000
00011
00102
00113
01004
01015
01106
01117
10XXEXP
11XXQuiet Mode
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Data Sheet
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3.3 Output Level Select
A single resistor, RSET, is used to set the amplitude of all differential outputs. Table 3-3
shows the value of RSET vs output drive capability.
Figure 3-3: GX9533 Data Latency
Figure 3-4: LOAD/LOADA and Configure Timing
Figure 3-5: Configure to Data Out Delay
Table 3-3: RSET vs VOUT
RSET VOUT (mV) OUTPUT RLMODE
2k 800 100 PECL
4k 450 100 Power Save 1
6k 450 200 Power Save 2
IN0 to IN7
IN0 to IN7
OUT0 to OUT7
OUT0 to OUT7
tDLY
OA
N
, IA
N
t
ILS
t
OLS
t
LP
t
ILH
t
OCH
t
LC
t
CP
LOAD/LOADA
CONFIGURE
CONFIGURE
tCD
OUT 0 TO OUT 7
OUT 0 TO OUT 7
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Data Sheet
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Figure 3-6: GX9533 RSET Connection
RSET
STD/ECL2
STD/ECL1
GX9533
GX9533 Serial Digital 8x9 Crosspoint
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4. Using the GX9533 to Expand Larger Matrices
The GX9533 pin-out and architecture provides a number of advantages over other
crosspoint switches in the area of switching matrix board layout.
Figure 4-1: Crosspoint Matrix Expansion - 16x16 Crosspoint Matrix
4.1 Bus Through™ Pin Connections
To easily facilitate a switching matrix design where inputs can be bussed across a matrix
of crosspoint devices, Gennum's crosspoint device has "NC" pins opposite the input pins
as shown by the dotted lines in the pin-out diagram above. This design allows bussing of
inputs without having to use "vias" to get below the top layer of the printed circuit board.
4.2 Expansion Port Input
The expansion inputs provide the following benefits:
• by not having to run traces from the outputs of the crosspoint switch to a common
output bus, crosstalk between output channels can be greatly reduced.
• fewer circuit board layers are required because the outputs of each device simply
line up
• there are no transmission line effects caused by connecting High-Z outputs to an
output bus
• because the output signal is being routed from the top of the switching matrix to the
bottom through the devices, inputs can be simply bussed across the board without
having to worry about input/output crosstalk.
INPUTS 8-15
INPUTS 0-7
OUTPUTS 8-15
OUTPUTS 0-7
GX9533
GX9533 GX9533
GX9533
GX9533 Serial Digital 8x9 Crosspoint
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5. Package Dimensions
Figure 5-1: Package Dimensions
23.90
±0.25
20.0
±0.10
18.85
REF
17.90
±0.25
14.0
±0.10
12.35
REF
3.30 MAX
2.80
±0.25
1.95
REF
0.30 MAX RADIUS
0.13 MIN.
RADIUS 0.80
±0.10
0.75 MIN
12° TYP
0°- 7°
0°-7°
0.30
±0.08
0.65
BSC
100 pin MQFP
Dimensions in millimeters
OTTAWA
232 Herzberg Road, Suite 101
Kanata, Ontario K2K 2A1
Canada
Phone: +1 (613) 270-0458
Fax: +1 (613) 270-0429
CALGARY
3553 - 31st St. N.W., Suite 210
Calgary, Alberta T2L 2K7
Canada
Phone: +1 (403) 284-2672
UNITED KINGDOM
North Building, Walden Court
Parsonage Lane,
Bishop’s Stortford Hertfordshire, CM23 5DB
United Kingdom
Phone: +44 1279 714170
Fax: +44 1279 714171
INDIA
#208(A), Nirmala Plaza,
Airport Road, Forest Park Square
Bhubaneswar 751009
India
Phone: +91 (674) 653-4815
Fax: +91 (674) 259-5733
SNOWBUSH IP - A DIVISION OF GENNUM
439 University Ave. Suite 1700
Toronto, Ontario M5G 1Y8
Canada
Phone: +1 (416) 925-5643
Fax: +1 (416) 925-0581
E-mail: sales@snowbush.com
Web Site: http://www.snowbush.com
MEXICO
288-A Paseo de Maravillas
Jesus Ma., Aguascalientes
Mexico 20900
Phone: +1 (416) 848-0328
JAPAN KK
Shinjuku Green Tower Building 27F
6-14-1, Nishi Shinjuku
Shinjuku-ku, Tokyo, 160-0023
Japan
Phone: +81 (03) 3349-5501
Fax: +81 (03) 3349-5505
E-mail: gennum-japan@gennum.com
Web Site: http://www.gennum.co.jp
TAI W A N
6F-4, No.51, Sec.2, Keelung Rd.
Sinyi District, Taipei City 11502
Taiwan R.O.C.
Phone: (886) 2-8732-8879
Fax: (886) 2-8732-8870
E-mail: gennum-taiwan@gennum.com
GERMANY
Hainbuchenstraße 2
80935 Muenchen (Munich), Germany
Phone: +49-89-35831696
Fax: +49-89-35804653
E-mail: gennum-germany@gennum.com
NORTH AMERICA WESTERN REGION
691 South Milpitas Blvd., Suite #200
Milpitas, CA 95035
United States
Phone: +1 (408) 934-1301
Fax: +1 (408) 934-1029
E-mail: naw_sales@gennum.com
NORTH AMERICA EASTERN REGION
4281 Harvester Road
Burlington, Ontario L7L 5M4
Canada
Phone: +1 (905) 632-2996
Fax: +1 (905) 632-2055
E-mail: nae_sales@gennum.com
KOREA
8F Jinnex Lakeview Bldg.
65-2, Bangidong, Songpagu
Seoul, Korea 138-828
Phone: +82-2-414-2991
Fax: +82-2-414-2998
E-mail: gennum-korea@gennum.com
DOCUMENT IDENTIFICATION
DATA SHEET
The product is in production. Gennum reserves the right to make changes to
the product at any time without notice to improve reliability, function or
design, in order to provide the best product possible.
GX9533 Serial Digital 8x9 Crosspoint
Data Sheet
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Gennum Corporation assumes no liability for any errors or omissions in this document, or for the use of the circuits or devices described herein. The sale of
the circuit or device described herein does not imply any patent license, and Gennum makes no representation that the circuit or device is free from patent
infringement.
All other trademarks mentioned are the properties of their respective owners.
GENNUM and the Gennum logo are registered trademarks of Gennum Corporation.
© Copyright 1995 Gennum Corporation. All rights reserved.
www.gennum.com
GENNUM CORPORATE HEADQUARTERS
4281 Harvester Road, Burlington, Ontario L7L 5M4 Canada
Phone: +1 (905) 632-2996 Fax: +1 (905) 632-2055
E-mail: corporate@gennum.com www.gennum.com
CAUTION
ELECTROSTATIC SENSITIVE DEVICES
DO NOT OPEN PACKAGES OR HANDLE EXCEPT AT A
STATIC-FREE WORKSTATION
6. Ordering Information
Table 6-1: Ordering Information
Part Number Package Temperature Range
GX9533-CQY 100-Pin MQFP Tray 0°C to 70°C
GX9533-CTY 100-Pin MQFP Tape 0°C to 70°C
