GENNUM GS9000D

GENLINX II ™ GS9000D
Serial Digital Decoder
DATA SHEET
DEVICE DESCRIPTION
• fully compatible with SMPTE 259M-ABC
The GS9000D is a CMOS integrated circuit specifically
designed to deserialize SMPTE 259M serial digital signals
at data rates up to 270Mb/s. The GS9000D is a pin and
functional equivalent to the GS9000C, with the exception of
SDI input levels which are compatible for direct interfacing
to the GS7025, GS9025A and GS9035A.
• decodes 8 and 10 bit serial digital signals for data rates to
270Mb/s
• recommended alternative to GS9000C for use when
interfacing directly to GS7025, GS9025A or GS9035A
• incorporates automatic standards selection
The device incorporates a descrambler, serial to parallel
convertor, sync processing unit, sync warning unit and
automatic standards select circuitry.
• 325mW power dissipation at 270MHz clock rate
• Pb-free and Green
• operates from single +5 or -5 volt supply
Differential pseudo-ECL inputs for both serial clock and
data are internally level shifted to CMOS levels. Digital
outputs such as parallel data, parallel clock, HSYNC, Sync
Warning and Standard Select are all TTL compatible.
• 28 pin PLCC packaging
APPLICATIONS
•
4ƒSC and 4:2:2 serial digital interfaces
•
Automatic standards select controller for serial routing
and distribution applications
The GS9000D is packaged in a 28 pin PLCC and operates
from a single 5 volt, ±5% power supply.
ORDERING INFORMATION
PART NUMBER
PACKAGE
TEMPERATURE
Pb-FREE AND GREEN
GS9000DCPJ
28 Pin PLCC
0°C to 70°C
No
GS9000DCTJ
28 Pin PLCC Tape
0°C to 70°C
No
GS9000DCPJE3
28 Pin PLCC
0°C to 70°C
Yes
GS9000DCTJE3
28 Pin PLCC Tape
0°C to 70°C
Yes
GS9000D
SERIAL DATA IN
LEVEL
SHIFT
SERIAL DATA IN
SERIAL CLOCK IN
SERIAL CLOCK IN
LEVEL
SHIFT
DESCRAMBLER
30 - BIT
SHIFT REG
SYNC DETECT
(3FF 000 000 HEX)
SCLK
Sync
SYNC CORRECTION
ENABLE
Word
Boundary
SP
PARALLEL
TIMING
GENERATOR
PARALLEL DATA
OUT (10 BITS)
PARALLEL CLOCK
OUT
SYNC CORRECTION
Sync Error
HSYNC OUTPUT
SYNC WARNING
(Schmitt Trigger
Comparator)
SYNC WARNING
CONTROL
SYNC WARNING
FLAG
AUTO STANDARD SELECT
STANDARDS SELECT
CONTROL
OSC
2 BIT
COUNTER
SS0
SS1
Hsync Reset
FUNCTIONAL BLOCK DIAGRAM
Revision Date: June 2004
Document No. 18784 - 3
GENNUM CORPORATION P.O. Box 489, Stn. A, Burlington, Ontario, Canada L7R 3Y3
Tel. +1 (905) 632-2996 Fax. +1 (905) 632-5946 E-mail: [email protected]
www.gennum.com
GS9000D
FEATURES
ABSOLUTE MAXIMUM RATINGS
PARAMETER
VALUE
7V
Input Voltage Range (any input)
-0.3 to (VDD + 0.3)
DC Input Current (any one input)
GS9000D
Supply Voltage (VS = VDD - VSS)
±10µA
Operating Temperature Range
0°C to 70°C
Storage Temperature Range
-65°C to +150C
Lead Temperature (Soldering, 10 seconds)
260°C
DC ELECTRICAL CHARACTERISTICS
VDD = 5V, TA = 0°C to 70°C unless otherwise shown
PARAMETER
SYMBOL
CONDITIONS
NOTES
TEST
LEVEL
MIN
TYP
MAX
UNITS
4.75
5.00
5.25
V
3
Supply Voltage
VS
Operating range
Power Consumption (outputs
unloaded)
PC
ƒ = 143MHz
-
235
-
mW
7
ƒ = 270MHz
-
325
-
mW
7
3.4
-
-
V
1
-
-
1.5
V
1
CMOS Input Voltage
VIHMIN
TA = 25°C
VILMAX
Output Voltage
Input Leakage Current
VOHMIN
IOH = 4mA, 25°C
2.4
4.5
-
V
1
VOLMAX
IOL = 4mA, 25°C
-
0.2
0.5
V
1
ΙIN
VIN = VDD or VSS
-
-
±10
µA
3
3.0
-
4.05
V
Serial Clock and Data Inputs
Common Mode Voltage
VCM
TA = 25°C,
VIN = 700 to 1200mVpp
Centre of
Swing
1
TEST LEVELS
1. Production test at room temperature and nominal supply voltage with guardbands for supply and temperature ranges.
2. Production test at room temperature and nominal supply voltage with guardbands for supply and temperature ranges using
correlated test.
3. Production test at room temperature and nominal supply voltage.
4. QA sample test.
5. Calculated result based on Level 1, 2, or 3.
6. Not tested. Guaranteed by design simulations.
7. Not tested. Based on characterization of nominal parts.
8. Not tested. Based on existing design/characterization data of similar product.
9. Indirect test.
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AC ELECTRICAL CHARACTERISTICS
VDD = 5V, TA = 0°C to 70°C unless otherwise shown
PARAMETER
Serial Input Clock Frequency
Serial Input Data Rate
SYMBOL
NOTES
TEST
LEVEL
MIN
TYP
MAX
UNITS
ƒSCI
100
-
270
MHz
1
DRSDI
100
-
270
Mb/s
1
TA = 25°C
Setup
tSU
1.0
-
-
ns
7
Hold
tHOLD
1.0
-
-
ns
7
VIN
700
800
1200
mVpp
1
TA = 25°
-
1.0
-
ns p-p
7
TA = 25°C,
-
3
-
ns
20% to
80%
7
-
-
±3
ns
Rising
edge of
PCLK to bit
period
centre
7
Signal Swing
Parallel Clock: Jitter
tJCLK
Parallel Data: Risetime and Falltime
tR-PDn
CL = 10pF
PDn to PCLK Delay Tolerance
tD
TEST LEVELS
1. Production test at room temperature and nominal supply voltage with guardbands for supply and temperature ranges.
2. Production test at room temperature and nominal supply voltage with guardbands for supply and temperature ranges using
correlated test.
3. Production test at room temperature and nominal supply voltage.
4. QA sample test.
5. Calculated result based on Level 1, 2, or 3.
6. Not tested. Guaranteed by design simulations.
7. Not tested. Based on characterization of nominal parts.
8. Not tested. Based on existing design/characterization data of similar product.
9. Indirect test.
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GS9000D
Serial Data and Clock Inputs:
CONDITIONS
VSS
SWF
4
3
VSS
HSYNC
2
(MSB)
PD9
28
PD8
27
VSS
26
5
25
PD7
SDI
6
24
PD6
SCI
7
23
PD5
SCI
8
22
PD4
SS1
9
21
PD3
SS0
10
20
PD2
SSC
11
19
PD1
GS9000D
SDI
GS9000D
TOP VIEW
12
13
14
15
16
17
18
VDD
VDD
SCE
SWC
PCLK
PD0
VDD
(LSB)
Fig. 1 GS9000D Pin Outs, 28 Pin PLCC Package
PIN DESCRIPTIONS
PIN NO.
SYMBOL
TYPE
DESCRIPTION
1
HSYNC
Output
Horizontal Sync Output. CMOS (TTL compatible) output that toggles for each TRS detected.
2
VSS
3
SWF
4
VSS
5, 6
SDI/SDI
Inputs
Differential, pseudo-ECL serial data inputs. ECL voltage levels with offset of 3.0V to 4.05V for
operation up to 270MHz. See AC Electrical Characteristics Table for details.
7, 8
SCI/SCI
Inputs
Differential, pseudo-ECL serial clock inputs. ECL voltage levels with offset of 3.0V to 4.05V for
operation up to 270MHz. See AC Electrical Characteristics Table for details.
9,10
SS1/SS0
Output
Standard Select Outputs. CMOS (TTL compatible) outputs is generated by a 2-bit internal
binary counter which stops cycling when a valid TRS is detected by the GS9000D.
11
SSC
Input
12
VDD
Power Supply. Most positive power supply connection.
13
VDD
Power Supply. Most positive power supply connection.
14
SCE
Power Supply. Most negative power supply connection.
Output
Sync Error Warning Flag. CMOS (TTL compatible) active high output that indicates the
preselected HSYNC Error Rate (HER). The HER is set with an RC time constant on the SWC
input.
Power Supply. Most negative power supply connection.
Input
Standards Select Control. Analog input used to set a time constant for the standards select
hunt period. An external RC sets the time constant.
Sync Correction Enable. Active high CMOS input which enables sync correction by not
resetting the GS9000D’s internal parallel timing on the first sync error. If the next incoming
sync is in error, internal parallel timing will be reset. This is to guard against spurious HSYNC
errors. When SCE is low, a valid sync will always reset the GS9000D’s parallel timing generator
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PIN DESCRIPTIONS
PIN NO.
SYMBOL
TYPE
DESCRIPTION
15
SWC
Input
16
PCLK
Output
Parallel Clock Output. CMOS (TTL compatible) clock output where the rising edge of the
clock is located at the centre of the parallel data window within a given tolerance. See Fig. 7.
17
PD0
Output
Parallel Data Output - Bit 0 (LSB). CMOS (TTL compatible) descrambled parallel data output
from the serial to parallel convertor representing the least significant bit (LSB).
18
VDD
19-25
PD1 - PD7
26
VSS
27
PD8
Output
Parallel Data Output. CMOS (TTL compatible) descrambled parallel data output from the
serial to parallel convertor representing data bit 8.
28
PD9
Output
Parallel Data Output - Bit 9 (MSB). CMOS (TTL compatible) descrambled data output from
the serial to parallel convertor representing the most significant bit (MSB).
Sync Warning Control. Analog input used to set the HSYNC Error Rate (HER). This is
accomplished by an external RC time constant connected to this pin.
Outputs
Parallel Data Outputs - Bit 1 to Bit 7. CMOS (TTL compatible) descrambled parallel data
outputs from the serial to parallel convertor representing data bit 1 through data bit 7.
Power Supply. Most negative power supply connection.
INPUT/OUTPUT CIRCUITS
VDD
VDD
VDD
REXT
SDI
SSC
SCI
BIAS
EXTERNAL
COMPONENTS
VDD
Fig. 2 Pin 11 SSC
SDI
SCI
VDD
VDD
Fig. 4 Pins 5 - 8 SDI - SCI
SCE
Fig. 3 Pin 14 SCE
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GS9000D
Power Supply. Most positive power supply connection.
VDD
VDD
VDD
REXT
SWC
6k8
GS9000D
OUTPUT
CEXT
EXTERNAL
COMPONENTS
GND
Fig. 5 Pin 15 SWC
Fig. 6 Pins 3, 16, 17, 19 - 25, 27, 28
SWF, HSYNC, SSI, SSD, PCLK, PD0-9
1/ T
2
tCLKL = tCLKH
2 T
PARALLEL
DATA
(PDn)
50%
SERIAL
CLOCK
(SCI)
1/
PARALLEL
CLOCK
(PCLK)
SERIAL
DATA
(SDI)
tSU
tHOLD
50%
tD
Fig. 7 Waveforms
TEST SET-UP & APPLICATION INFORMATION
Figure 8 shows the test set-up for the GS9000D operating
from a VDD supply of +5 volts. The differential pseudo ECL
inputs for DATA and CLOCK (pins 5,6,7 and 8) must be
biased between +3.0 and +4.05 volts. In the application
circuit shown in Figure 11, these inputs can be directly
driven from the outputs of the GS7025 Reclocking Receiver
with their resistor values set as shown.
If the automatic standard select function is not used, the
Standard Select bits (pins 9 and 10) do not need to be
connected, however the control input (pin 11) should be
grounded.
In other cases, such as true ECL level driver outputs, two
biasing resistors are needed on the DATA and CLOCK
inputs and the signals must be AC coupled.
It is critical that the decoupling capacitors connected to
pins 12,13 and 18 are chip types and are located as close
as possible to the device pins.
The critical high speed inputs, such as Serial Data
(pins 5 and 6) and Serial Clock (pins 7 and 8), are located
along one side of the device package to maintain very short
interconnections when interfacing with the GS7025
Receiver.
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** Locate the three 0.10µF decoupling
capacitors as close as possible to the
corresponding pins on the GS9000D.
Chip capacitors are recommended.
+5V
22µ
3 x 100n
HSYNC OUTPUT
**
12
SDIIN
SCIIN
SCIIN
STANDARDS SELECT BIT 1
STANDARDS SELECT BIT 0
+5V
100k
820p
18
1
VDD VDD VDD HSYNC
17
PD0
DECODER
19
PDI
5 SDI GS9000D
20
PD2
6 SDI
21
PD3
7 SCI
PD4 22
8 SCI
23
PD5
9 SS1
24
PD6
10 SS0
PD7 25
11 SSC
PD8 27
PARALLEL DATA BIT 0
PARALLEL DATA BIT 1
PARALLEL DATA BIT 2
PARALLEL DATA BIT 3
PARALLEL DATA BIT 4
PARALLEL DATA BIT 5
PARALLEL DATA BIT 6
PARALLEL DATA BIT 7
PARALLEL DATA BIT 8
PD9 28
PCLK
SCE
VSS VSS VSS SWC SWF
2
4 26 15
3
GS9000D
SDIIN
13
PARALLEL DATA BIT 9
16
PARALLEL CLOCK OUT
14
SYNC CORRECTION ENABLE
10p
SYNC WARNING FLAG
13 x 425
39k
All resistors in ohms,
all capacitors in farads,
unless otherwise specified.
+5V
Fig. 8 GS9000D Test Set-Up
With synchronized serial data and clock connected to the
GS9000D, the HSYNC output (pin 1) will toggle for each
HSYNC detected. The Parallel Data bits PD0 through PD9
and the Parallel Clock can be observed on an oscilloscope
or fed to a logic analyzer. To directly drive parallel inputs to
receiving equipment, such as monitors or digital to analog
converters, these outputs can be fed through a suitable TTL
to ECL converter.
The HSYNC output toggles to indicate the presence of the
TRS on the falling edge of PCLK, one data symbol prior to
the output of the first word in the TRS. In the following
diagram, data is indicated in 10-bit Hex.
PCLK
PDN
In operation, the HSYNC output from the GS9000D decoder
toggles on each occurrence of the timing reference signal
(TRS). The state of the HSYNC output is not significant, but
the time at which it toggles is significant.
4ƒSC
DATA
STREAM
T
R
S
ACTIVE VIDEO
& H BLANKING
E
A
V
H
BLNK
T
R
S
ACTIVE VIDEO
& H BLANKING
XXX 3FF 000 000 XXX
XXX 3FF 000 000 XXX
HSYNC
Fig. 10 Operation of HSYNC with Respect to PCLK
T
R
S
HSYNC
OUT
4:2:2
DATA
STREAM
S
A
V
ACTIVE
VIDEO
E
A
V
H
BLNK
S
A
V
HSYNC
OUT
Fig. 9 Operation of HSYNC Output
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TYPICAL APPLICATION CIRCUIT - Adjustment Free Multi-standard Serial To Parallel Convertor
Vcc
8.2nH
100nF
Vcc
1uF
Serial Data
Output
1uF
100nF
75
5
VEE
GS9000D
6
SDI
90.9
SDI
90.9
VCC
7
GS9028
4
RSET
3
100nF
VEE
2
SDO
1
SDO
37.5
8
75
Vcc
59
Vcc
LOCK
Vcc
Vcc
Vcc
22k
CD
Vcc
4.75k
150
150
CLK_EN
150
CLK_EN
Vcc
Vcc
100nF
SSC
Vcc
8
22
9
21
10
20
11
NC
19
12
13
14
15
16
17
PD6
100
PD5
100
PD4
100
PD3
100
PD2
100
PD1
100
Vcc
100nF
NC
100
PD7
100
18
VDD
Vcc
270
Vcc
VSS
22
NC
GS9000D
100
21
Vcc
68k
22nF
100nF
100nF
VCC
RVCO 365
Vcc
20
CBG
VEE
15nF
RVCO_RTN
LFS
LF-
VEE
1.8k
19
SS0
23
PCLK
18
VEE
24
PD0
17
SS1
PD9
16
LF+
AGC+
100nF
100pF
VCC
100k
15
SCO
PD8
23
14
SCI
100
26
6
100nF
11
SCO
27
7
SCE
24
SCI
28
SWC
10
VEE
1
25
VDD
25
SDI
2
100
5
VDD
26
9
SDO
3
HSYNC
27
13
3k3
28
SDI
VSS
29
GS7025
(2)
4
SDO
SWF
30
12
Pot
100
31
4
VSS
3
VEE
90.9
32
90.9
100nF
AGC-
33
8
VEE
Vcc
34
7
VCC
CD_ADJ
35
VEE
10n
VCC
75
Vcc
37.5
36
2
6
SDI
37
1
5
SDI
38
CLK_EN
10n
39
VEE
75
40
COSC
15nH (1)
100nF
VEE
4.7nF
75
VCC
41
LOCK
VCC_75
SSI/CD
100nF
Serial Data Input
DDI
42
A/D
DDI
Vcc
43
MOD
VCC
44
OEM_TEST
Vcc
Vcc
*
3.3pF
NOTE: Value of SDO and SCO
pull-up resistors is 90.9Ω ± 1%
(1) Typical value for input return loss matching
(2) The GS7025 can be replaced by either the GS9025A or GS9035A for
applications at data rates less then 270Mb/s or when equalization is not required
Fig. 11
GS9000D and GS7025 INTERCONNECTIONS
Figure 11 shows an application of the GS9000D in a
270Mb/s serial to parallel converter. This circuit uses the
GS7025 Serial Digital Receiver. For datarates below 270Mb/s
the GS9025A can be used. If cable equalization is not
required the GS7025 or GS9025A may be replaced with a
GS9035A Reclocker IC.
The GS9028 Cable Equalizer allows a serial loop through
after the reclocker.
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SYNC WARNING FLAG OPERATION
GS9000D
Each time HSYNC is not correctly detected, the Sync
Warning Flag output (pin 3 ) will go HIGH. The RC network
connected to the Sync Warning Control input (pin 15) sets
the number of sync errors that will cause the SWF pin to go
HIGH. The component values of the RC network shown in
Figure 12 set the SWF error rate to approximately one
HSYNC error in 10 lines. These component values are
chosen for optimum performance of the SWF pin, and
should not be adjusted.
Typically, HSYNC errors become visible on a monitor before
the SWF provides an indication of HSYNC errors. As a
result, the SWF function can be used in applications where
the detection of significant signal degradation is desired.
A high SWF goes low when the input error rate decreases
below the set rate. A small amount of hysteris in the
comparator ensures noise immunity.
VDD
COMPARATOR
15
VDD
SYNC
WARNING
CONTROL
6k8
+
3
SYNC
WARNING
FLAG
(SWF)
SYNC
ERROR
Fig. 12 Sync Warning Flag Circuit
CAUTION
ELECTROSTATIC
SENSITIVE DEVICES
DO NOT OPEN PACKAGES OR HANDLE
EXCEPT AT A STATIC-FREE WORKSTATION
DOCUMENT IDENTIFICATION
REVISION NOTES:
Added lead-free and green information.
PRELIMINARY DATA SHEET
The product is in a preproduction phase and specifications
are subject to change without notice.
GENNUM CORPORATION
MAILING ADDRESS:
P.O. Box 489, Stn. A, Burlington, Ontario, Canada L7R 3Y3
Tel. +1 (905) 632-2996 Fax. +1 (905) 632-5946
SHIPPING ADDRESS:
970 Fraser Drive, Burlington, Ontario, Canada L7L 5P5
GENNUM JAPAN CORPORATION
Shinjuku Green Tower Building 27F 6-14-1, Nishi Shinjuku Shinjuku-ku,
Tokyo 160-0023 Japan
Tel: +81 (03) 3349-5501 Fax: +81 (03) 3349-5505
GENNUM UK LIMITED
25 Long Garden Walk, Farnham, Surrey, England GU9 7HX
Tel. +44 (0)1252 747 000 Fax +44 (0)1252 726 523
Gennum Corporation assumes no responsibility for the use of any circuits described herein and makes no representations that they are free from patent infringement.
© Copyright May 2000 Gennum Corporation. All rights reserved. Printed in Canada.
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