Gennum GS1522 Hdtv serial digital serializer Datasheet

HD-LINX ™ GS1522
HDTV Serial Digital Serializer
DATA SHEET
DESCRIPTION
• SMPTE 292M compliant
The GS1522 is a monolithic bipolar integrated circuit
designed to serialize SMPTE 274M and SMPTE 260M bit
parallel digital signals.
• 20:1 parallel to serial conversion
• NRZ(I) encoder & SMPTE scrambler with selectable
bypass
This device performs the following functions:
• NRZ to NRZ(I) serial data conversion
•
Sync word mapping for 8-bit/10-bit operation.
•
Parallel to Serial conversion of Luma & Chroma data
•
Interleaving of Luma and Chroma data
•
9
4
Data Scrambling (using the X +X +1 algorithm)
•
Conversion of NRZ to NRZI serial data (using the (X+1)
algorithm)
•
Selectable DUAL or QUAD 75Ω Cable Driver outputs
•
Lock Detect Output
•
1.485Gb/s or 1.485/1.001Gb/s operation
• 1.485Gb/s and 1.485/1.001Gb/s operation
• lock detect output
• selectable DUAL or QUAD 75Ω cable driver outputs
• 8 bit or 10 bit input data support
• 20 bit wide inputs
• Pb-free and Green
• 3.3V and 5V CMOS/TTL compatible inputs
• single +5.0V power supply
APPLICATIONS
SMPTE 292M Serial Digital Interfaces for Video Cameras,
Camcorders, VTRs, Signal Generators, Portable Equipment, and NLEs.
This device requires a single 5V supply and typically
consumes less than 1000mW of power while driving two
75Ω cables.
The GS1522 uses the GO1515 external VCO connected to
the internal PLL circuitry to achieve ultra low noise PLL
performance.
ORDERING INFORMATION
PART NUMBER
PACKAGE
TEMPERATURE
Pb-FREE AND GREEN
GS1522-CQR
128 pin MQFP
0°C to 70°C
No
GS1522-CQRE3
128 pin MQFP
0°C to 70°C
Yes
RSET0
RESET BYPASS
SYNC_DETECT
_DISABLE
20
DATA_IN[19:0]
20
SYNC DETECT
SDO0
SMPTE
INPUT
LATCH
SCRAMBLER
O/P0
RESET
INTERLEAVER
BYPASS
PCLK_IN
SDO0
PARALLEL
TO SERIAL
CONVERTER
SCLK
PLL
SDO1
O/P1
NRZ TO NRZI
SDO1
PLOAD
MUTE
GO1515
RSET1
SDO1_EN
PLL_LOCK
FUNCTIONAL BLOCK DIAGRAM
Revision Date: June 2004
Document No. 522 - 26 - 03
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
GS1522
FEATURES
ABSOLUTE MAXIMUM RATINGS
PARAMETER
VALUE
Supply Voltage (VS)
5.5V
Input Voltage Range (any input)
VEE – 0.5 < VIN < VCC+ 0.5
TBD
Power Dissipation (VCC = 5.25V)
TBD
Input ESD Voltage
TBD
Die Temperature
GS1522
DC Input Current (any input)
125°C
0°C ≤ TA ≤ 70°C
Operating Temperature Range
-40°C ≤ TS ≤ 150°C
Storage Temperature Range
Lead Temperature (soldering 10 seconds)
260°C
AC ELECTRICAL CHARACTERISTICS
VCC = 5V, VEE = 0V, TA = 0°C to 70°C unless otherwise specified.
PARAMETER
CONDITIONS
SYMBOL
MIN
TYP
MAX
UNITS
BRSDO
-
1.485
-
Gb/s
Serial data bit rate
SMPTE 292M
Digital Serial Data
Outputs
Differential outputs
VSDO
750
800
850
mV p-p
Rise/Fall times, 20-80%
tr, tf
-
150
270
ps
-
0
7
%
15
17
-
dB
Overshoot
Output Return Loss @
1.485GHz
ORL
Lock Time
Worst case
tLOCK
Typical Loop Bandwidth
≤ 0.1dB peaking,
1.485Gb/s
Intrinsic Jitter
Pseudo-random
NOTES
1.485/1.001Gb/s also
With 52.3Ω 1% RSET
Resistor
As per SMPTE292M
(5MHz to clock
frequency), using
Gennum Evaluation
Board, recommended
layout and components.
-
200
250
ms
-
0.200
1.5
MHz
tIJR
-
-
100
ps p-p
tIJP
-
-
100
ps p-p
tIJR
-
-
100
ps p-p
tIJP
-
-
100
ps p-p
23
PRBS (2 -1)
(200kHz LBW)
Pathological
23
PRBS (2 -1)
(200kHz LBW)
Pseudo-random
(1.5 MHz LBW)
Pathological
(1.5 MHz LBW)
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AC ELECTRICAL CHARACTERISTICS - PARALLEL TO SERIAL STAGE
VDD = 5V, TA = 0°C to 70°C unless otherwise specified.
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
VIL
-
-
0.8
V
For compatibility with TTL
voltage levels
VIH
2.0
-
-
V
For compatibility with TTL
voltage levels
Input Capacitance
CIN
-
1
2
pF
Output Voltage Levels
VOL
-
-
0.4
V
For compatibility with TTL
voltage levels
VOH
2.4
-
-
V
For compatibility with TTL
voltage levels
PCLK_IN
-
74.25
-
MHz
Input Clock Pulse Width
LOW
tPWL
5
-
-
ns
Input Clock Pulse Width
HIGH
tPWH
5
-
-
ns
Input Clock Rise/Fall time
tr, tf
-
500
1000
ps
Input Clock Rise/Fall time
Matching
trfm
-
200
-
ps
Input Setup Time
tSU
1.0
-
-
ns
Input Hold Time
tIH
0
-
-
ns
Input Voltage Levels
Parallel Input Clock
Frequency
NOTES
74.25/1.001MHz also
20% to 80%
DC ELECTRICAL CHARACTERISTICS
VCC = 5V, VEE = 0V, TA = 0°C to 70°C unless otherwise specified.
PARAMETER
CONDITIONS
SYMBOL
MIN
TYP
MAX
UNITS
NOTES
Positive Supply Voltage
Operating Range
VCC
4.75
5.00
5.25
V
Power (system power)
VCC = 5.00V, T=25°C
PD
-
950
-
mW
(Driving two 75Ω outputs)
VCC = 5.00V, T=25°C
PD
-
1170
-
mW
(Driving four 75Ω outputs)
VCC = 5.25V, T=70°C
-
-
300
mA
(Driving four 75Ω outputs)
VCC = 5.00V, T=25°C
-
234
-
mA
(Driving four 75Ω outputs)
SDO1 disabled
-
-
240
mA
(Driving two 75Ω outputs)
-
190
-
mA
(Driving two 75Ω outputs)
Supply Current
VCC = 5.25V, 70°C
SDO1 disabled
VCC = 5.0V, 25°C
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GS1522
SYMBOL
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
OSC_VEE
A0
NC
NC
NC
VEE2
RSET0
VCC2
NC
SDO0
SDO_NC
SDO0
NC
NC
NC
SDO1
SDO_NC
SDO1
NC
VCC2
RSET1
NC
NC
NC
NC
NC
PIN CONNECTIONS
GS1522
NC
65
38
NC
NC
66
37
NC
NC
67
36
NC
NC
68
35
NC
NC
69
34
NC
NC
70
33
NC
NC
71
32
NC
NC
72
31
SDO1_EN
NC
73
30
VEE2
VCO
74
29
VEE2
VCO
75
28
VEE2
PD_VEE
76
27
VEE2
PDSUB_VEE
77
26
VEE2
IJI
78
25
VCC2
PD_VCC
79
24
VCC2
NC
80
23
VCC2
NC
81
22
VCC2
LFS
82
21
VCC2
NC
83
20
NC
LFS
84
19
NC
PLCAP
85
18
VEE2
DM
86
17
RESET
PLCAP
87
16
BYPASS
DFT_VEE
88
15
PLL_LOCK
LFA_VEE
89
14
NC
LFA
90
13
XDIV20
LBCONT
91
12
NC
LFA_VCC
92
11
NC
NC
93
10
BUF_VEE
VCC3
94
9
NC
VEE3
95
8
NC
SYNC_DETECT_DISABLE
96
7
NC
NC
97
6
NC
NC
98
5
NC
NC
99
4
NC
NC
100
3
NC
NC
101
2
PCLK_IN
NC
102
1
VEE3
DATA_IN[19]
DATA_IN[18]
DATA_IN[17]
DATA_IN[16]
DATA_IN[15]
NC
NC
DATA_IN[14]
DATA_IN[13]
DATA_IN[12]
DATA_IN[11]
DATA_IN[10]
DATA_IN[9]
NC
NC
DATA_IN[8]
DATA_IN[7]
NC
NC
DATA_IN[6]
DATA_IN[5]
DATA_IN[4]
DATA_IN[3]
DATA_IN[2]
DATA_IN[1]
DATA_IN[0]
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
GS1522
TOP
VIEW
NOTE: No Heat Sink Required
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PIN DESCRIPTIONS
NUMBER
1, 95
2
LEVEL
TYPE
DESCRIPTION
VEE3
Power
Input
Negative Supply. Most negative power supply connection, for input
stage.
PCLK_IN
TTL
Input
Parallel Data Clock. 74.25 or 74.25/1.001MHz
NC
No Connect. These pins are not used internally. These pins should
be floating.
10
BUF_VEE
Power
TEST
Negative Supply/Test Pin. Most negative power supply connection.
For buffer for oscillator/divider for test purposes only. Leave
floating for normal operation.
13
XDIV20
TTL
TEST
Test Pin. Test block output. Leave floating for normal operation.
15
PLL_LOCK
TTL
Output
Status Signal Output. Indicates when the GS1522 is phase locked
to the incoming PCLK_IN clock signal. LOGIC HIGH indicates PLL
is in Lock. LOGIC LOW indicates PLL is out of Lock.
16
BYPASS
TTL
Input
Control Signal Input. Used to bypass the scrambling function if
data is already scrambled by GS1501 or if non-SMPTE encoded
data stream such as 8b/10b is to be transmitted. When BYPASS is
LOW, the SMPTE scrambler and NRZ(I) encoder are enabled.
When BYPASS is HIGH, the SMPTE scrambler and NRZ(I) encoder
are bypassed.
17
RESET
TTL
Input
Control Signal Input. Used to reset the SMPTE scrambler. For logic
HIGH; Resets the SMPTE scrambler and NRZ(I) encoder. For logic
LOW: normal SMPTE scrambler and NRZ(I) encoder operation.
18, 26, 27, 28,
29, 30, 59
VEE2
Power
Input
Negative Supply. Most negative power supply connection. For
Cable Driver outputs and all other digital circuitry excluding input
stage and PLL stage.
21, 22, 23, 24,
25, 45, 57
VCC2
Power
Input
Positive Supply. Most positive power supply connection. For Cable
Driver outputs and all other digital circuitry excluding input stage
and PLL stage.
31
SDO1_EN
Power
Input
Control Signal Input. Used to enable or disable the second serial
data output stage. This signal must be tied to GND to enable this
stage. Do not connect to a logic LOW.
44
RSET1
Input
Control Signal Input. External resistor is used to set the data output
amplitude for SDO1 and SDO1. Use a ±1% resistor.
47, 49
SDO1, SDO1
Analog
Output
Serial Data Output Signal. Current mode serial data output #1.
Use 75Ω ±1% pull up resistors to VCC2.
48, 54
SDO_NC
53, 55
SDO0, SDO0
Analog
Output
Serial Data Output Signal. Current mode serial data output #0. Use
75Ω ± 1% pull up resistors to VCC2.
RSET0
Analog
Input
Control Signal Input. External resistor is used to set the data output
amplitude for SDO0 and SDO0. Use a ±1% resistor.
58
No Connect. Not used internally. This pin must be left floating.
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GS1522
3, 4, 5, 6, 7, 8,
9, 11, 12, 14,
19, 20, 32, 33,
34, 35, 36, 37,
38, 39, 40, 41,
42, 43,46, 50,
51, 52, 56, 60,
61, 62, 65, 66,
67, 68, 69, 70,
71, 72, 73, 80,
81, 83, 93, 97,
98, 99, 100,
101, 102, 108,
109, 116, 117,
120, 121
SYMBOL
PIN DESCRIPTIONS (Continued)
NUMBER
LEVEL
TYPE
DESCRIPTION
63
A0
TTL
TEST
Test Signal. Used for manufacturing test purposes only. This pin
must be tied low for normal operation.
64
OSC_VEE
Power
Input
Negative Supply. Ground for ring oscillator. This pin must be
floating for normal operation.
74
VCO
Analog
Input
Control Signal Input. Input pin is AC coupled to ground using a
50Ω transmission line.
75
VCO
Analog
Input
Control Signal Input. Voltage controlled oscillator input. This pin is
connected to the output pin of the GO1515 VCO. This pin must be
connected to the GO1515 VCO output pin via a 50Ω transmission
line.
76
PD_VEE
Power
Input
Negative Supply. Most negative power supply connection. For
phase detector stage.
77
PDSUB_VEE
Power
Input
Guard Ring. Ground guard ring connection to isolate phase
detector in PLL stage.
78
IJI
Analog
Output
79
PD_VCC
Power
Input
Positive Supply. Most positive power supply connection. For phase
detector stage.
82, 84
LFS, LFS
Analog
Input
Loop Filter Connections.
85, 87
PLCAP, PLCAP
Analog
Input
Control Signal Input. Phase lock detect time constant capacitor.
Status Signal Output. Indicates the amount of excessive jitter on
the incoming SDI and SDI input.
86
DM
88
DFT_VEE
Power
Input
Most Negative Power Supply Connection . Enables the jitter
demodulator functionality. This pin should be connected to
ground. If left floating, the DM function is disabled resulting in a
current saving of 340µA.
89
LFA_VEE
Power
Input
Negative Supply. Most negative power supply connection. For loop
filter stage.
90
LFA
Analog
Output
91
LBCONT
Analog
Input
Control Signal Input. Used to provide electronic control of Loop
Bandwidth.
92
LFA_VCC
Power
Input
Positive Supply. Most positive power supply connection. For loop
filter stage.
94
VCC3
Power
Input
Positive Supply. Most positive power supply connection. For input
stage.
96
SYNC_DETECT_DISABLE
TTL
Input
Control Signal Input. Used to disable the sync detection function.
Logic HIGH disables sync detection. Logic LOW: 000-003 is
mapped into 000 and 3FC-3FF is mapped into 3FF for 8-bit
operation.
DATA_IN[19:0]
TTL
Input
Input Data Bus. The device receives a 20 bits data stream running
at 74.25 or 74.25/1.001 MHz from the GS1501 HDTV Formatter or
GS1511 HDTV Formatter. Input data can be in SMPTE292M
scrambled or unscrambled format. DATA_IN[19] is the MSB (pin
103). DATA_IN[0] is the LSB (pin 128).
103, 104, 105,
106, 107, 110,
111, 112, 113,
114, 115, 118,
119, 122, 123,
124, 125, 126,
127, 128
Test Signal. Used for manufacturing test only. This pin must be left
floating in normal operation.
Control Signal Output. Control voltage for GO1515 VCO.
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GS1522
SYMBOL
INPUT/OUTPUT CIRCUITS
PD_VCC
LFA_VCC
5k
5k
500
GS1522
LFA
10k
10k
40
31p
40
5mA
100µA
PD_VEE
50
LFA_VEE
VCO
VCO
Fig. 4 LFA Circuit
Fig. 1 VCO/VCO Input Circuit
LFA_VCC
PD_VCC
25k
10k
10k
DM
LFS
400µA
85µA
LFA_VEE
DFT_VEE
Fig. 5 LFS Output Circuit
Fig. 2 DM Output Circuit
LFA_VCC
PD_VCC
20k
10k
10k
PLCAP
5k
PLCAP
LFS
100µA
100µA
100µA
PD_VEE
100µA
100µA
LFA_VEE
Fig. 3 PLCAP/PLCAP Output Circuit
Fig. 6 LFS Input Circuit
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VCC3
2k
BIAS
PD_VCC
10k
GS1522
10k
D0 - D19,
SYNC_DETECT_DISABLE
PLL_LOCK
PD_VEE
VEE3
All on-chip resistors have ±20% tolerance at room temperature.
Fig. 7 PLL_LOCK Output Circuit
Fig. 10 Data Input and SYNC_DETECT_DISABLE Circuit
VCC
1k
PD_VCC
10k
BIAS
IJI
PCLK_IN
5k
5k
VCC
30k A
VEE
PD_VEE
Fig. 8 IJI Output Circuit
Fig. 11 PCLK_IN Circuit
VCC
20k
SDO
SDO
BIAS
RESET
10k
+
CD_VEE
VEE
RSET
Fig. 9 SDO/SDO Output Circuit
Fig. 12 RESET Circuit
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VCC
5k
5k
BIAS
GS1522
BYPASS
10k
VEE
Fig. 13 BYPASS Circuit
DETAILED DESCRIPTION
The GS1522 HDTV Serializer is a bipolar integrated circuit
used to convert parallel data into serial format according to
the SMPTE 292M standard. The device encodes both 8-bit
and 10-bit TTL compatible parallel signals producing a
serial data rate of 1.485Gb/s. The device operates from a
single 5V supply and is available in a 128 pin MQFP
package.
The functional blocks within the device include the input
latches, interleaver, sync detector, parallel to serial
converter, SMPTE scrambler, NRZ to NRZ(I) converter, two
internal cable drivers, PLL for 20x parallel clock
multiplication and lock detect circuitry.
1. INPUT LATCHES
The 20-bit input latch accepts either 3.3V or 5V CMOS/TTL
inputs. The input data is buffered and then latched on the
rising edge of the PCLK_IN pin (2). The output of the latch
is a differential signal for increased noise immunity. Further
noise isolation is provided by the use of separate power
supplies.
2. INTERLEAVER
The interleaver takes the 20-bit wide parallel data (Y and C)
and reduces it internally to a 10-bit wide word by alternating
the Y and C data words according to SMPTE 292M, section
6.1.
3. SYNC DETECTOR
The sync detector looks for the reserved words 000-003
and 3FC-3FF in 10-bit hexadecimal, or 00-03 and FC-FF in
8-bit hexadecimal used in the TRS-ID sync word. When
there is an occurrence of all zeros or all ones in the eight
higher order bits, the lower two bits are forced to zeros or
ones respectively. This allows the system to be compatible
with 8-bit and 10-bit data. For non-SMPTE standard parallel
data, a logic input Sync Detect Disable pin (96) is available
to disable this feature.
4. SCRAMBLER
The scrambler is a linear feedback shift register used to
pseudo-randomize the incoming data according to the fixed
polynomial (X9+X4+1). This minimizes the DC component in
the output serial stream. The NRZ to NRZ(I) converter uses
another polynomial (X+1) to convert a long sequence of
ones to a series of transitions, minimizing polarity effects. To
disable these features, set the BYPASS pin (16) HIGH.
5. SLEW PHASE LOCK LOOP (S-PLL)
An innovative feature of the GS1522 is the slew phase lock
loop (S-PLL). When a step phase change is applied to the
PLL, the output phase gains constant rate of change with
respect to time. This behavior is termed slew. Figure 14
shows an example of input and output phase variation over
time for slew and linear (conventional) PLLs. Since the
slewing is a non-linear behavior, the small signal analysis
cannot be done in the same way as it is for the standard
PLL. However, it is still possible to plot input jitter transfer
characteristics at a constant input jitter modulation.
Slew PLLs offer several advantages such as excellent noise
immunity. The loop corrects small input jitter modulation
immediately because of the infinite bandwidth. Therefore,
the small signal noise of the VCO is cancelled immediately.
The GS1522 uses a very clean, external VCO called the
GO1515 (refer to the GO1515 Data Sheet for details).
Another advantage is the bi-level digital phase detector
which provides constant loop bandwidth that is
predominantly independent of the data transition density.
The loop bandwidth of a conventional tri-stable charge
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pump drops with reducing data transitions. During
pathological signals, the data transition density reduces
from 0.5 to 0.05 but the slew PLL’s performance does not
change significantly.
PHASE ALIGNMENT
EDGE
IN-PHASE CLOCK
Because most of the PLL circuitry is digital, it is very robust
as digital systems are generally more robust than their
analog counterparts. Signals which represent the internal
functionality, like DM (86), can be generated without adding
additional artifacts. Thus, system debugging is possible
with these features.
PHASE (UI)
0.2
INPUT
0.1
INPUT CLOCK
WITH JITTER
OUTPUT DATA
Fig. 15 Phase Detector Characteristics
During pathological signals, the amount of jitter that the
phase detector will add can be calculated. By choosing the
proper loop bandwidth, the amount of phase detector
induced jitter can also be limited. Typically, for a 1.41MHz
loop bandwidth at 0.2UI input jitter modulation, the phase
detector induced jitter is about 0.015UIp-p. This is not
significant, even in the presence of pathological signals.
OUTPUT
5.2. Charge Pump
The charge pump in a slew PLL is different from the charge
pump in a linear PLL. There are two main functions of the
charge pump: to hold the frequency information of the input
data and to provide a binary control voltage to the VCO.
0.0
SLEW PLL RESPONSE
The charge pump holds the frequency information of the
input data. This information is held by CCP1 which is
connected between LFS (82) and LFS (84). CCP2, which is
connected between LFS and LFA_VEE (89), is used to
remove common mode noise. Both CCP1 and CCP2 should
have the same value.
0.2
PHASE (UI)
0.8UI
GS1522
The complete slew PLL is made up of several blocks
including the phase detector, the charge pump and an
external Voltage Controlled Oscillator (VCO) which are
described in the following sections. Phase lock loop
frequency synthesis and lock logic are also described.
RE-TIMING
EDGE
INPUT
0.1
OUTPUT
0.0
LINEAR (CONVENTIONAL) PLL RESPONSE
Fig. 14 PLL Characteristics
5.1. Phase Detector
The phase detector portion of the slew PLL used in the
GS1522 is a bi-level digital phase detector. It indicates
whether the data transition occurred before or after with
respect to the falling edge of the internal clock. When the
phase detector is locked, the data transition edges are
aligned to the falling edge of the clock. The input data is
then sampled by the rising edge of the clock, as shown in
Figure 15. In this manner, the allowed input jitter is 1UI p-p
in an ideal situation. However, due to setup and hold time,
the GS1522 typically achieves 0.8UI p-p input jitter
tolerance without causing any errors in this block. When the
signal is locked to the internal clock, the control output from
the phase detector is refreshed at the transition of each
rising edge of the data input. During this time, the phase of
the clock drifts in one direction.
The charge pump provides a binary control voltage to the
VCO depending upon the phase detector output. The
output pin LFA (90) controls the VCO. Internally there is a
500Ω pull-up resistor which is driven with a 100µA current
called ΙP. Another analog current ΙF, with 5mA maximum
drive proportional to the voltage across the CCP1, is applied
at the same node. The voltage at the LFA node is
VLFA_VCC - 500(ΙP+ΙF) at any time.
Because of the integrator, ΙF changes very slowly whereas
ΙP can change at the positive edge of the data transition as
often as a clock period. In the locked position, the average
voltage at LFA (VLFA_VCC – 500(ΙP/2+ΙF) is such that VCO
generates frequency ƒ equal to the data rate clock
frequency. Since ΙP is changing all the time between 0A and
100µA, there are two levels generated at the LFA output.
5.3. VCO
The GO1515 is an external hybrid VCO which has a centre
frequency of 1.485GHz. It is guaranteed to provide
1.485/1.001GHz within the control voltage (3.1V – 4.65V) of
the GS1522 over process, power supply and temperature.
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The GO1515 is a very clean frequency source and,
because of the internal high Q resonator, is an order of
magnitude more immune to external noise as compared to
on-chip VCOs.
The LBCONT pin (91) is used to adjust the loop bandwidth
by externally changing the internal charge pump current.
For maximum loop bandwidth, connect LBCONT to the
most positive power supply. For medium loop bandwidth,
connect LBCONT through a pull-up resistor (RPULL-UP). For
low loop bandwidth, leave LBCONT floating. The formula
below shows the change in the loop bandwidth using
RPULL-UP.
5.4. Phase Lock Loop Frequency Synthesis
The GS1522 requires the HDTV parallel clock (74.25 or
74.25/1.001MHz) to synthesize a serial clock which is 20
times the parallel clock frequency (1.485MHz) using a
phase locked loop (PLL). This serial clock is then used to
strobe the output serial data. Figure 16 illustrates this
operation. The VCO is normally free-running at a frequency
close to the serial data rate. A divide-by-20 circuit converts
the free running serial clock frequency to approximately that
of the parallel clock. Within the phase detector, the dividedby-20 serial clock is then compared to the reference
parallel clock from the PCLK_IN pin (2). Based on the
leading or lagging alignment of the divided clock to the
input reference clock, the serial data output is synchronized
to the incoming parallel clock.
where LBWNOMINAL is the loop bandwidth when LBCONT is
left floating.
7. LOOP BANDWIDTH OPTIMIZATION
Since the feed back loop has only digital circuits, the small
signal analysis does not apply to the system. The effective
loop bandwidth scales with the amount of input jitter
modulation index. The following table summarizes the
relationship between input jitter modulation index and
bandwidth when RCP1 and CCP3 are not used. See the
Typical Application Circuit for the location of RCP1 and CCP3 .
TABLE 1: Relationship Between Input Jitter Modulation Index and
Bandwidth
GS1522 PLL
PCLK_IN
( 25kΩ + R PULL – UP )
LBW = LBW NOMINAL × -----------------------------------------------------( 5kΩ + R PULL – UP )
PHASE
DETECTOR
DIVIDE-BY-20
GO1515
VCO
INPUT JITTER
MODULATION
INDEX
BANDWIDTH
BW JITTER FACTOR
(jitter modulation x BW)
0.05
5.657MHz
282.9kHzUI
0.10
2.828MHz
282.9kHzUI
0.20
1.414MHz
282.9kHzUI
0.50
565.7kHz
282.9kHzUI
Fig. 16 Phase Lock Loop Frequency Synthesis
5.5. Lock Logic
Logic is used to produce the PLL_LOCK (15) signal which
is based on the LFS signal and phase lock signal. When
there is no data input, the integrator charges and eventually
saturates at either end. By sensing the saturation of the
integrator, it is determined that no data is present. If there is
no data present or phase lock is low, the lock signal is
made LOW. Logic signals are used to acquire the
frequency by sweeping the integrator. Injecting a current
into the summing node of the integrator achieves the
sweep. The sweep is disabled when phase lock is
asserted. The direction of the sweep is changed when LFS
saturates at either end.
The product of the input jitter modulation (IJM) and the
bandwidth (BW) is a constant. In this case, it is 282.9kHzUI.
The loop bandwidth automatically reduces with increasing
input jitter, which results in the cleanest signal possible.
Using a series combination of RCP1 and CCP3 in parallel to
an on-chip resistor (see the Typical Application Circuit) can
reduce the loop bandwidth of the GS1522. The parallel
combination of the resistors is directly proportional to the
bandwidth factor. For example, the on-chip 500Ω resistor
yields 282.9kHzUI. If a 50Ω resistor is connected in parallel,
the effective resistance will be (50:500) 45.45Ω. This
resistance yields a bandwidth factor of
[282.9 x (45.45/500)] = 25.72kHzUI
The capacitance CCP3 in series with the RCP1 should be
chosen such that the RC factor is 50µF. For example,
RCP1=50Ω requires CCP3=1µF.
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GS1522
The VCO gain, Kƒ, is nominally 16MHz/V. The control
voltage around the average LFA voltage is 500 x ΙP/2. This
produces two frequencies off from the centre by
ƒ = Kƒ x 500 x ΙP/2.
6. LBCONT
The Kƒ of the VCO (GO1515) is specified with a minimum of
11MHz/V and maximum of 21MHz/V which is about ±32%
variation. The 500 x ΙP/2 varies about ±10%. The resulting
bandwidth factor varies by approximately ±45% when no
RCP1 and CCP3 are used. ΙP by itself may vary by 30% so the
variability for lower bandwidths increases by an additional
±30%.
The CCP1 and CCP2 capacitors should be changed with
reduced bandwidths. Smaller CCP1 and CCP2 capacitors
result in jitter peaking, lower stability, less probability of
locking but at the same time lowering the asynchronous
lock time. Therefore, there is a trade-off between
asynchronous lock time and jitter peaking/stability. These
capacitors should be as large as possible for the allowable
lock time and should be no smaller than the allowed value.
With the recommended values, jitter peaking of less than
0.1dB has been measured at the lower loop bandwidth as
shown in Figure 17. At higher loop bandwidths, it is difficult
to measure jitter peaking because of the limitation of the
measurement unit.
It has been determined that for 282.9kHzUI, the minimum
value of the CCP1 and CCP2 capacitors should be no less
than 0.5µF. For added margin, 1µF capacitors are
recommended. The 1µF value gives a lock time of about
60ms in one attempt. For 25.72kHzUI, these capacitors
should be no less than 5.6µF. This results in 340ms of lock
time. If necessary, extra margin can be built by increasing
these capacitors at the expense of a longer asynchronous
lock time.
Bandwidths lower than 129kHz at 0.2UI modulation have
not been characterized, but it is believed that the
bandwidth could be further lowered (contact Gennum’s
Video Products Applications for further details). Since a
lower bandwidth has less correction for noise, extra care
should be taken to minimize board noise. Figures 18 and 19
show the two measured loop bandwidths at these two
settings. Table 2 summarizes the two bandwidth settings.
Fig. 18 Typical Jitter Transfer Curve at Setting A in Table 2
Fig. 17 Typical Jitter Peaking
However, because relatively larger CCP1 and CCP2
capacitors can be used, over-damping of the loop response
occurs. An accurate jitter peaking measurement of 0.1dB
for the GS1522 requires the modulation source to have a
constant amount of jitter modulation index (within 0.1dB or
1.2%) over the frequency range beyond the loop
bandwidth.
Fig. 19 Typical Jitter Transfer Curve at Setting B in Table 2
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GS1522
The synchronous lock time increases with reduced
bandwidth. Nominal synchronous lock time is equal to
[ 0.25 × 2 /Bandwidth factor]. That is, the default
bandwidth factor (282.9kHzUI) yields 1.25µs. For
25.72kHzUI,
the
synchronous
lock
time
is
0.3535/25.72k = 13.75µs. Since the CCP1, CCP2 and CCP3 are
also charged, it is measured to be about 11µs which is
slightly less than the calculated value of 13.75µs.
TABLE 2: Loop Bandwidth Setting Options
RCP1
CCP3
CCP1
CCP2
BW
FACTOR
BW at 0.2 UI JITTER
MODULATION
INDEX
ASYNCHRONOUS
SYNCHRONOUS
A
Open
Open
1.0
1.0
282.9kHz
1.41MHz
60ms
1.25µs
B
50
1.0
5.6
5.6
25.72kHz
129kHz
340ms
11.0µs
9. INPUT JITTER INDICATOR (IJI)
The phase lock circuit is used to determine the phase
locked condition. It is done by generating a quadrature
clock by delaying the in-phase clock by 166ps (0.25UI at
1.5GHz) with the tolerance of 0.05UI. The in-phase clock is
the clock whose falling edge is aligned to the data
transition. When the PLL is locked, the falling edge of the inphase clock is aligned with the data edges as shown in
Figure 20. The quadrature clock is in a logic HIGH state in
the vicinity of input data transitions. The quadrature clock is
sampled and latched by positive edges of the data
transitions. The generated signal is low pass filtered with an
RC network. The R is an on-chip 6.67kΩ resistor and CPL is
an internal capacitor (31pF). The time constant is about
200ns.
This signal indicates the amount of excessive jitter which
occurs beyond the quadrature clock window (greater than
0.5UI, see Figure 19). All the input data transitions
occurring outside the quadrature clock window are
captured and filtered by the low pass filter as mentioned in
section 8, Phase Lock. The running time average of the
ratio of the transitions inside the quadrature clock and
outside the quadrature is available at the PLCAP/PLCAP
pins (87 and 85). IJI, which is the buffered signal available
at the PLCAP, is provided so that loading does not effect
the filter circuit. The signal at IJI is referenced with the
power supply such that the factor VIJI /V CC is a constant over
process and power supply for a given input jitter
modulation. The IJI signal has 10kΩ output impedance.
Figure 21 shows the relationship of the IJI signal with
respect to the sine wave modulated input jitter.
PHASE ALIGNMENT
EDGE
RE-TIMING
EDGE
TABLE 3: IJI Voltage as a Function of Sinusoidal Jitter
IN-PHASE CLOCK
0.8UI
INPUT CLOCK
WITH JITTER
0.25UI
QUADERATURE
CLOCK
PLCAP SIGNAL
PLCAP SIGNAL
P-P SINE WAVE JITTER IN UI
IJI VOLTAGE
0.00
4.75
0.15
4.75
0.30
4.75
0.39
4.70
0.45
4.60
0.48
4.50
0.52
4.40
0.55
4.30
0.58
4.20
0.60
4.10
0.63
3.95
Fig. 20 PLL Circuit Principles
If the signal is not locked, the data transition phase could
be anywhere with respect to the internal clock or the
quadrature clock. In this case, the normalized filtered
sample of the quadrature clock is 0.5. When VCO is locked
to the incoming data, data will only sample the quadrature
clock when it is logic HIGH. The normalized filtered sample
quadrature clock is 1.0. We chose a threshold of 0.66 to
generate the phase lock signal. Because the threshold is
lower than 1, it allows jitter to be greater than 0.5UI before
the phase lock circuit reads it as “not phase locked”.
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GS1522
8. PHASE LOCK
5.0
IJI SIGNAL (V)
4.8
4.6
4.4
4.2
GS1522
4.0
3.8
3.6
0.00
0.20
0.40
0.60
0.80
INPUT JITTER (UI)
Fig. 21 Input Jitter Indicator (Typical at TA = 25°C)
10. JITTER DEMODULATION (DM)
Fig. 22 Jitter Demodulation Signal
The differential jitter demodulation (DM) signal is available
at the DM pin (86). This signal is the phase correction signal
of the PLL loop, which is amplified and buffered. If the input
jitter is modulated, the PLL tracks the jitter if it is within loop
bandwidth. To track the input jitter, the VCO has to be
adjusted by the phase detector via the charge pump. Thus,
the signal which controls the VCO contains the information
of the input jitter modulation. The jitter demodulation signal
is only valid if the input jitter is less than 0.5UIp-p. The DM
signal has a 10kΩ output impedance, which can be low
pass filtered with appropriate capacitors to eliminate high
frequency noise. DFT_VEE (88) should be connected to
GND to activate the DM signal.
The DM signal can be used as a diagnostic tool. Assume
there is an HDTV SDI source which contains excessive
noise during the horizontal blanking because of the
transient current flowing in the power supply. To discover
the source of the noise, probe around the source board with
a low frequency oscilloscope (Bandwidth < 20MHz) that is
triggered with an appropriately filtered DM signal. The true
cause of the modulation is synchronous and appears as a
stationary signal with respect to the DM signal.
Figure 22 shows an example of such a situation. An HDTV
SDI signal is modulated with a signal causing about 0.2UI
jitter (Channel 1). The GS1522 receives this signal and
locks to it. Figure 22 (Channel 2) shows the DM signal.
Notice the wave shape of the DM signal, which is
synchronous to the modulating signal. The DM signal can
also be used to compare the output jitter of the HDTV signal
source.
11. MUTE
The logic controls the mute block when the PLL_LOCK (15)
signal has a LOW logic state. When the mute signal is
asserted, the previous state of the output is latched.
12. CABLE DRIVER
The outputs of the GS1522 are complementary current
mode cable driver stages. The output swing and
impedance can be varied. Use Table 4 to select the RSET
resistor for the desired output voltage level. Linear
interpolation can be used to determine the specific value of
the resistor for a given output swing at the load impedance.
For linear interpolation, use either Figure 23 or the
information in Table 4. Find the admittance and then, by
inverting the admittance, a resistor value for the RSET can be
found.
The output can be used as dual 0.8V 75Ω cable drivers. It
can also be used as a differential transmission line driver. In
this case, the pull-up resistor should match the impedance
of the transmission line because the pull-up resistor acts as
the source impedance. To reduce the swing and save
power, use a higher value of RSET resistor. There are
HD-LINX™ products that can handle such low input swings.
NOTE: For reliability, the minimum RSET resistor cannot be
less than 50Ω because of higher current density.
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0.8
0.6
75Ω
0.4
GS1522
SOURCE/END TERMINATED
OUTPUT SWING (V)
1.0
50Ω
0.2
0.0
0.00
0.01
0.02
0.03
1/RSET (Ω)
Fig. 23 Signal Swing for Various R SET Admittances
When the outputs are used to differentially drive another
device such as the GS1508, use 50Ω transmission lines
with the smallest possible signal swing while allowing 10%
variation at the output swing to select the correct RSET
resistor. To drive the GS1508, the recommended RSET
resistor is 150Ω. There is no need to compensate for the
return-loss in this situation. The uncompensated waveform at
the output is shown in Figure 24.
Fig. 24 Uncompensated Output Eye Waveform
Fig. 25 Compensated Output Eye Waveform
NOTE: Figures 24 and 25 show the waveforms on an
oscilloscope using a 75Ω to 50Ω pad.
TABLE 4: RSET Values for Various Output Load Conditions
OUTPUT CURRENT
TRANSMISSION LINE,
TERMINATED AT THE
END. (PULL-UP
RESISTOR AT THE
SOURCE = 75Ω)
TRANSMISSION LINE,
TERMINATED AT THE
END. (PULL-UP
RESISTOR AT THE
SOURCE = 50Ω)
0.0020
2.506mA
0.094V
0.063V
150.0Ω
0.0067
7.896mA
0.296V
0.197V
75.0Ω
0.0133
15.161mA
0.569V
0.379V
53.6Ω
0.0187
20.702mA
0.776V
0.517V
52.3Ω
0.0192
21.216mA
0.796V
0.530V
49.9Ω
0.0200
22.032mA
0.826V
-
RSET RESISTOR
ADMITTANCE (g) OF
THE RSET RESISTOR
(= 1/RSET RESISTOR)
500.0Ω
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12. RETURN LOSS
Unless the artwork is an exact copy of the recommended
layout, verify every design for output return loss. Tweak the
layout until a return loss of 25dB is attained while the
GS1522 is not mounted and L1 is shorted. When the device
is mounted, use different inductors to match the parasitic
capacitance of the IC. When the correct inductor is used,
maximum return loss of 5MHz to 800MHz is achievable. To
increase the return loss 800MHz to 1.5GHz, use a shunt
capacitor of 0.5pF to 1.5pF. The larger inductor causes
slower rise/fall time. The larger shunt capacitor causes a
kink in the output waveform. Therefore, the waveform must
be verified to meet SMPTE 292M specifications.
There are two levels at the output depending upon the
output state (logic HIGH or LOW). When taking
measurements, latch the outputs in both states. An
interpolation is necessary because the actual output node
voltages are different when a stream of data is passing as
compared to the static situation created when measuring
return loss. See the GS1508 Preliminary Data Sheet for
more information.
GS1522
In an application where the GS1522 directly drives a cable,
it is possible to achieve an output return loss (ORL) of about
17dB to 1.485GHz. PCB layout is very important. Use the
EB1522 as a reference layout (see Figures 28 to 31). When
designing high frequency circuits, use very small ‘0608’
surface mount components with short distances between
the components. To reduce PCB parasitic capacitance,
provide openings in the ground plane. For best matching, a
12nH inductor in parallel with a 75Ω resistor and a 1.5pF
capacitor matches the 75Ω cable impedance. The inductor
and resistor cancel the parasitic capacitance while the
capacitor cancels the inductive effect of the bond wire. To
verify the performance of any layout, measure the return
loss by shorting the inductor with a piece of wire without the
GS1522 installed.
Fig. 26 Compensated Output Return Loss at Logic HIGH
Fig. 27 Compensated Output Return Loss at Logic LOW
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PCLK
D1_0
D1_1
D1_2
D1_3
D1_4
D1_5
D1_6
D1_7
D1_8
D1_9
D1_10
D1_11
D1_12
D1_13
D1_14
D1_15
D1_16
D1_17
D1_18
D1_19
C19
10µ
100n
C20
VCC
SYNC_DETECT_DISABLE
10µ
C17
0
C21
R6
124
DATA_IN[4]
125 DATA_IN[3]
126
DATA_IN[2]
127 DATA_IN[1]
128 DATA_IN[0]
118 DATA_IN[8]
119 DATA_IN[7]
120 nc
121
nc
122
DATA_IN[6]
123 DATA_IN[5]
116 nc
117 nc
109 nc
110 DATA_IN[14]
111 DATA_IN[13]
112
DATA_IN[12]
113 DATA_IN[11]
114 DATA_IN[10]
115 DATA_IN[9]
106 DATA_IN[16]
107 DATA_IN[15]
108 nc
103 DATA_IN[19]
104 DATA_IN[18]
105 DATA_IN[17]
L8
L5
All resistors in ohms,
all capacitors in farads,
unless otherwise shown.
C18
100n
VCC
C46
100n
C5
10n
C47
10µ
VCC
VCC
L7
10µ
C45
10n
C1
LBCONT
LOOP
FILTER
COMPONENTS
1µ
CCP2
+
100n
C48
VCC
JMP
NOTE: R35 IS AN OPTIONAL 1k RESISTOR.
LEAVE FLOATING.
R35
OPTIONAL
1µ
CCP1
+
10n
VCC
C4
10n
C6
NOTE: L3 to L8 are 0Ω RESISTORS.
USE 12nH INDUCTORS IN
NOISY ENVIRONMENTS.
GS1522
JMP
R36
NOTE: R36 IS AN OPTIONAL 0Ω RESISTOR.
LEAVE FLOATING.
VCC
nc 83
L6
LFS 82
81
nc
nc 80
79
VCC
4 nc
5 nc
nc 102
1 V
EE3
nc 99
98
nc
nc 97
96
SYNC_DETECT_DISABLE
VEE3 95
VCC3 94
93
nc
LFA
LFA 90
VCO
PDSUB_VEE 77
PD_VEE 76
VCO 75
VCO 74
TYPICAL APPLICATION CIRCUIT
3 nc
PCLK_IN
IJI
nc 101
nc 100
2
LFS
DM 86
PLCAP 85
84
LBCONT
92
LFA_VCC
6 nc
7
nc
8 nc
9 nc
10 BUF_VEE
11 nc
IJI
78
PD_VCC
91
LBCONT
12 nc
13 XDIV20
nc 70
nc 69
VCC
470n
10n
C16
C12
33 nc
34 nc
LFA_VEE 89
DFT_VEE 88
PLCAP 87
BYPASS
14 nc
15 PLL_LOCK
16 BYPASS
PLL_LOCK
nc 73
nc 72
nc 71
17 RESET
18
VEE2
19 nc
20
nc
21
VCC2
22
VCC2
23
VCC2
24
VCC2
25
V
CC2
26 V
EE2
27
VEE2
28
V
EE2
29 V
EE2
30 V
EE2
31 SDO1_EN
32 nc
RESET
nc 68
nc 67
35 nc
36 nc
C13
100n
VCC
C40
10µ
59
60
61
62
RSET
L4
L3
C7
12nH
R4
1p5
L1
42
43
41
nc
nc 40
nc 39
nc
nc
SET1
nc 50
49
SDO1
48
SDO_nc
47
SDO1
46
nc
VCC2 45
44
R
VCC
1p5
12nH
C11
75
L2
C8
10n
nc 52
nc 51
R2
75
VCC
100n
R3
75
VCC
C15
75
R5
10µ
C14
SDO_nc 54
SDO0 53
RSET0 58
VCC2 57 V 52.3
CC
56
nc
SDO0 55
VEE2
nc
nc
nc
OSC_VEE 64
A0 63
nc 66
nc 65
37 nc
38 nc
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J4
BNC_ANCHOR
J2
J1
BNC_ANCHOR
SECOND PAIR OF
BNC SHOWN IS FOR
DUAL FOOTPRINT
OPTION ON INPUT
CONNECTORS
C9
+
4µ7
C10
+
4µ7
J3
TYPICAL APPLICATION CIRCUIT (continued)
GO1515 VCO
POWER CONNECT
LFA
VCC
C37
C41
+
100n
VCC
10µ
C38
+
C44
RCP1
VCTR 1
GND
50
8
CCP3 +
1µ
GS1522 LOCK DETECT
7 nc
2
GND
6 GND
U2
GND GO1515
5 O/P
4
100n
GS1522
VCC 3
10µ
VCC
R22
R25
LOCK
VCO
GS1522 SYNC DETECT DISABLE
(10BIT/8BIT)
LED1
22k
VCC
VCC
BYPASS
HDR1
HDR5
S1
SYNC_DETECT_DISABLE
150
GS1522 RESET CIRCUIT
GS1522 SCRAMBLER BYPASS
VCC
Q1
RESET
1
2
3
4
R20
4k7
All resistors in ohms,
all capacitors in farads,
unless otherwise shown.
The figures above show the recommended application
circuit for the GS1522. The external VCO is the GO1515
and is specifically designed to be used with the GS1522.
Figures 28 through 31 show an example PC board layout of
the GS1522 IC and the GO1515 VCO. This application
board layout does not reflect every detail of the typical
application circuit. It is provided as a general guide to the
location of the critical parts.
Fig. 28 Top Layer of EB1522 PCB Layout
Fig. 29 Ground Layer of EB1522 PCB Layout
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GS1522
Fig. 31 Bottom Layer of EB1522 PCB Layout
Fig. 30 Power Layer of EB1522 PCB Layout
APPLICATION INFORMATION
Please refer to the EBHDTX documentation for more
detailed application and circuit information on using the
GS1522 with the GS1501 and GS1511 Formatters.
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PACKAGE DIMENSIONS
23.20 ±0.25
20.0 ±0.10
18.50 REF
GS1522
12 TYP
0.75 MIN
17.20 ±0.25
12.50 REF
0 -7
0.30 MAX RADIUS
14.0 ±0.10
0-7
0.13 MIN.
RADIUS
0.88 ±0.15
1.6
REF
3.00 MAX
0.50 BSC
2.80 ±0.25
128 pin MQFP
All dimensions are in millimetres.
0.27 ±0.08
CAUTION
ELECTROSTATIC
SENSITIVE DEVICES
DO NOT OPEN PACKAGES OR HANDLE
EXCEPT AT A STATIC-FREE WORKSTATION
DOCUMENT IDENTIFICATION
REVISION NOTES:
Added Pb-free and green information.
For latest product information, visit www.gennum.com
DATA SHEET
The product is in production. Gennum reserves the right to make
changes at any time to improve reliability, function or design, in order to
provide the best product possible.
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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