AD ADV7192 Video encoder with six 10-bit dacs, 54 mhz oversampling and progressive scan input Datasheet

a
Video Encoder with Six 10-Bit DACs, 54 MHz
Oversampling and Progressive Scan Inputs
ADV7192
APPLICATIONS
DVD Playback Systems
PC Video/Multimedia Playback Systems
Progressive Scan Playback Systems
FEATURES
Six High-Quality 10-Bit Video DACs
10-Bit Internal Digital Video Processing
Multistandard Video Input
Multistandard Video Output
4 Oversampling with Internal 54 MHz PLL
Programmable Video Control Includes:
Digital Noise Reduction
Gamma Correction
Black Burst
LUMA Delay
CHROMA Delay
Multiple Luma and Chroma Filters
Luma SSAF™ (Super Subalias Filter)
Average Brightness Detection
Field Counter
Macrovision Rev. 7.1
CGMS (Copy Generation Management System)
WSS (Wide Screen Signaling)
Closed Captioning Support.
Teletext Insertion Port (PAL-WST)
2-Wire Serial MPU Interface (I 2C®-Compatible
and Fast I2C)
2
I C Interface
Supply Voltage 5 V and 3.3 V Operation
80-Lead LQFP Package
GENERAL DESCRIPTION
The ADV7192 is part of the new generation of video encoders
from Analog Devices. The device builds on the performance of
previous video encoders and provides new features like interfacing progressive scan devices, Digital Noise Reduction, Gamma
Correction, 4× Oversampling and 54 MHz operation, Average
Brightness Detection, Black Burst Signal Generation, Chroma
Delay, an additional Chroma Filter, and other features.
The ADV7192 supports NTSC-M, NTSC-N (Japan), PAL N,
PAL M, PAL-B/D/G/H/I and PAL-60 standards. Input standards
supported include ITU-R.BT656 4:2:2 YCrCb in 8-bit or 16-bit
format and 3× 10-Bit YCrCb progressive scan format.
The ADV7192 can output Composite Video (CVBS), S-Video
(Y/C), Component YUV or RGB and analog progressive scan in
YPrPb format. The analog component output is also compatible
with Betacam, MII, and SMPTE/EBU N10 levels, SMPTE
170 M NTSC, and ITU–R.BT 470 PAL.
Please see Detailed Description of Features for more information about the ADV7192.
SIMPLIFIED FUNCTIONAL BLOCK DIAGRAM
DIGITAL
INPUT
VIDEO
INPUT
PROCESSING
ANALOG
OUTPUT
PLL
AND
54MHz
27MHz
CLOCK
CHROMA
LPF
DEMUX
ITU–R.BT
656/601
8-BIT YCrCb
IN 4:2:2 FORMAT
VIDEO
OUTPUT
PROCESSING
VIDEO
SIGNAL
PROCESSING
AND
YCrCbTOYUV
MATRIX
COLOR CONTROL
DNR
GAMMA
CORRECTION
VBI
TELETEXT
CLOSED CAPTION
CGMS/WSS
10-BIT
DAC
2
OVERSAMPLING
SSAF
LPF
LUMA
LPF
10-BIT
DAC
10-BIT
DAC
OR
10-BIT
DAC
4
OVERSAMPLING
COMPOSITE VIDEO
Y [S-VIDEO]
C [S-VIDEO]
RGB
YUV
YPrPb
TV SCREEN
OR
PROGRESSIVE
SCAN DISPLAY
10-BIT
DAC
10-BIT
DAC
I2C INTERFACE
ADV7192
SSAF is a trademark of Analog Devices Inc.
ITU-R and CCIR are used interchangeably in this document (ITU-R has replaced CCIR recommendations).
I2C is a registered trademark of Philips Corporation.
Throughout the document YUV refers to digital or analog component video.
REV. A
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 2000
ADV7192
MPU PORT DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . 28
REGISTER ACCESSES . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
REGISTER PROGRAMMING . . . . . . . . . . . . . . . . . . . . . 29
MODE REGISTERS 0–9 . . . . . . . . . . . . . . . . . . . . . . . 30–35
TIMING REGISTERS 0–1 . . . . . . . . . . . . . . . . . . . . . . . . 36
SUBCARRIER FREQUENCY AND
PHASE REGISTERS . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
CLOSED CAPTIONING REGISTERS . . . . . . . . . . . . . . . 37
NTSC PEDESTAL/PAL TELETEXT CONTROL
REGISTERS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
TELETEXT REQUEST CONTROL REGISTER . . . . . . 38
CGMS_WSS REGISTERS . . . . . . . . . . . . . . . . . . . . . . . . . 38
CONTRAST CONTROL REGISTER . . . . . . . . . . . . . . . . 39
COLOR CONTROL REGISTERS . . . . . . . . . . . . . . . . . . 39
CC1 AND CC2 BIT DESCRIPTIONS . . . . . . . . . . . . . . . 39
HUE ADJUST CONTROL REGISTER (HCR) . . . . . . . . 40
HCR BIT DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . 40
BRIGHTNESS CONTROL REGISTER (BCR) . . . . . . . . 40
BCR BIT DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . 40
SHARPNESS RESPONSE REGISTER (PR) . . . . . . . . . . . 41
PR BIT DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . 41
DNR REGISTERS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
DNR BIT DESCRIPTIONS . . . . . . . . . . . . . . . . . . . . . . . . 41
GAMMA CORRECTION REGISTERS . . . . . . . . . . . . . . 43
BRIGHTNESS DETECT REGISTER . . . . . . . . . . . . . . . . 44
OUTPUT CLOCK REGISTER . . . . . . . . . . . . . . . . . . . . . 44
OCR BIT DESCRIPTIONS . . . . . . . . . . . . . . . . . . . . . . . . 44
APPENDIX 1
Board Design and Layout Considerations . . . . . . . . . . . . 45
APPENDIX 2
Closed Captioning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
APPENDIX 3
Copy Generation Management System (CGMS) . . . . . . . 48
APPENDIX 4
Wide Screen Signaling . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
APPENDIX 5
Teletext Insertion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
APPENDIX 6
Optional Output Filter . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
APPENDIX 7
DAC Buffering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
APPENDIX 8
Recommended Register Values . . . . . . . . . . . . . . . . . . . . 53
APPENDIX 9
NTSC Waveforms (With Pedestal) . . . . . . . . . . . . . . . . . 57
NTSC Waveforms (Without Pedestal) . . . . . . . . . . . . . . . 58
PAL Waveforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59
Video Measurement Plots . . . . . . . . . . . . . . . . . . . . . . . . 60
UV Waveforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
Output Waveforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
APPENDIX 10
Vector Plots . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
OUTLINE DIMENSIONS . . . . . . . . . . . . . . . . . . . . . . . . . 69
CONTENTS
FEATURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
APPLICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
GENERAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . 1
SIMPLIFIED FUNCTIONAL BLOCK DIAGRAM . . . . . . 1
SPECIFICATIONS
Static Performance 5 V . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Static Performance 3.3 V . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Dynamic Specifications 5 V . . . . . . . . . . . . . . . . . . . . . . . . 5
Dynamic Specifications 3.3 V . . . . . . . . . . . . . . . . . . . . . . . 5
Timing Characteristics 5 V . . . . . . . . . . . . . . . . . . . . . . . . 6
Timing Characteristics 3.3 V . . . . . . . . . . . . . . . . . . . . . . . 7
ABSOLUTE MAXIMUM RATINGS . . . . . . . . . . . . . . . . . 9
PIN CONFIGURATION . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
ORDERING GUIDE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
PACKAGE THERMAL PERFORMANCE . . . . . . . . . . . . . 9
PIN FUNCTION DESCRIPTIONS . . . . . . . . . . . . . . . . . 10
DETAILED DESCRIPTION OF FEATURES . . . . . . . . . 11
GENERAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . 11
DATA PATH DESCRIPTION . . . . . . . . . . . . . . . . . . . . . 12
INTERNAL FILTER RESPONSE . . . . . . . . . . . . . . . . . . . 13
FEATURES: FUNCTIONAL DESCRIPTION . . . . . . . . . 17
BLACK BURST OUTPUT . . . . . . . . . . . . . . . . . . . . . . . . 17
BRIGHTNESS DETECT . . . . . . . . . . . . . . . . . . . . . . . . . . 17
CHROMA/LUMA DELAY . . . . . . . . . . . . . . . . . . . . . . . . 17
CLAMP OUTPUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
CSO, HSO, AND VSO OUTPUTS . . . . . . . . . . . . . . . . . . 17
COLOR BAR GENERATION . . . . . . . . . . . . . . . . . . . . . . 17
COLOR BURST SIGNAL CONTROL . . . . . . . . . . . . . . . 17
COLOR CONTROLS . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
CHROMINANCE CONTROL . . . . . . . . . . . . . . . . . . . . . 17
UNDERSHOOT LIMITER . . . . . . . . . . . . . . . . . . . . . . . . 18
DIGITAL NOISE REDUCTION . . . . . . . . . . . . . . . . . . . . 18
DOUBLE BUFFERING . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
GAMMA CORRECTION CONTROL . . . . . . . . . . . . . . . 18
NTSC PEDESTAL CONTROL . . . . . . . . . . . . . . . . . . . . . 18
POWER-ON RESET . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
PROGRESSIVE SCAN INPUT . . . . . . . . . . . . . . . . . . . . . 18
REAL-TIME CONTROL, SUBCARRIER RESET, AND
TIMING RESET . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
SCH PHASE MODE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
SLEEP MODE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
SQUARE PIXEL MODE . . . . . . . . . . . . . . . . . . . . . . . . . . 19
VERTICAL BLANKING DATA INSERTION
AND BLANK INPUT . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
YUV LEVELS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
16-BIT INTERFACE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
4× OVERSAMPLING AND INTERNAL PLL . . . . . . . . . 20
VIDEO TIMING DESCRIPTION . . . . . . . . . . . . . . . . . . . 20
RESET SEQUENCE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
–2–
REV. A
ADV7192
SPECIFICATIONS
1 (VAA = 5 V, VREF = 1.235 V, RSET1,2 = 1200 unless otherwise noted. All specifications TMIN to TMAX
2
5 V SPECIFICATIONS
unless otherwise noted.)
Parameter
Min
Typ
STATIC PERFORMANCE
Resolution (Each DAC)
Accuracy (Each DAC)
Integral Nonlinearity3
Differential Nonlinearity3
DIGITAL INPUTS
Input High Voltage, VINH
Input Low Voltage, VINL
Input Current, IIN
Input Capacitance, CIN
Input Leakage Current4
Input Leakage Current5
DIGITAL OUTPUTS
Output High Voltage, VOH
Output Low Voltage, VOL
Three-State Leakage Current6
Three-State Leakage Current7
Three-State Output Capacitance
ANALOG OUTPUTS
Output Current (Max)
Output Current (Min)
DAC-to-DAC Matching3
Output Compliance, VOC
Output Impedance, ROUT
Output Capacitance, COUT
VOLTAGE REFERENCE
Reference Range, VREF8
POWER REQUIREMENTS
VAA
Normal Power Mode
IDAC (Max)9
ICCT (2× Oversampling) 10, 11
ICCT (4× Oversampling)10, 11
IPLL
Sleep Mode
IDAC
ICCT
Max
Unit
10
Bits
1.0
1.0
LSB
LSB
2.0
0.8
±1
10
0
6
1
200
4.625
mA
mA
RL = 300 Ω
RL = 600 Ω
RSET1, RSET2 = 2400 Ω
2.5
1.4
%
V
kΩ
pF
0.4
4.33
2.16
0.4
10
100
6
1.112
1.235
1.359
V
4.75
5.0
5.25
V
29
80
120
6
35
120
170
10
mA
mA
mA
mA
µA
µA
0.01
85
NOTES
1
All measurements are made in 4× Oversampling Mode unless otherwise specified.
2
Temperature range T MIN to TMAX: 0°C to 70°C.
3
Guaranteed by characterization.
4
For all inputs but PAL_NTSC and ALSB.
5
For PAL_NTSC and ALSB inputs.
6
For all outputs but VSO/TTX/CLAMP.
7
For VSO/TTX/CLAMP output.
8
Measurement made in 2× Oversampling Mode.
9
IDAC is the total current required to supply all DACs including the V REF Circuitry.
10
All six DACs ON.
11
ICCT or the circuit current, is the continuous current required to drive the digital core without I PLL.
Specifications subject to change without notice.
REV. A
–3–
VIN = 0.4 V or 2.4 V
ISOURCE = 400 µA
ISINK = 3.2 mA
0.8
10
200
6
0
Guaranteed Monotonic
V
V
µA
µA
pF
2.4
4.125
V
V
µA
pF
µA
µA
Test Conditions
IOUT = 0 mA
ADV7192–SPECIFICATIONS
(V = 3.3 V, V = 1.235 V, R
1
3.3 V SPECIFICATIONS
AA
REF
SET1,2 = 1200 unless otherwise noted. All specifications TMIN to TMAX2
unless otherwise noted.)
Parameter
Min
Typ
Max
Unit
10
Bits
1.0
1.0
LSB
LSB
±1
10
V
V
µA
µA
µA
pF
ISOURCE = 400 µA
ISINK = 3.2 mA
10
V
V
µA
µA
pF
RL = 300 Ω
RL = 600 Ω, RSET1,2 = 2400 Ω
100
6
mA
mA
%
V
kΩ
pF
IOUT = 0 mA
1.235
V
IVREFOUT = 20 µA
STATIC PERFORMANCE
Resolution (Each DAC)
Accuracy (Each DAC)
Integral Nonlinearity
Differential Nonlinearity
DIGITAL INPUTS
Input High Voltage, VINH
Input Low Voltage, VINL
Input Leakage Current3
Input Leakage Current4
Input Current, IIN
Input Capacitance, CIN
2
0.8
1
200
6
DIGITAL OUTPUTS
Output High Voltage, VOH
Output Low Voltage, VOL
Three-State Leakage Current5
Three-State Leakage Current6
Three-State Output Capacitance
ANALOG OUTPUTS
Output Current (Max)
Output Current (Min)
DAC-to-DAC Matching
Output Compliance, VOC
Output Impedance, ROUT
Output Capacitance, COUT
2.4
0.4
10
200
6
4.125
VOLTAGE REFERENCE
Reference Range, VREF7
POWER REQUIREMENTS
VAA
Normal Power Mode
IDAC (Max)8
ICCT (2× Oversampling)9, 10
ICCT (4× Oversampling)9, 10
IPLL
Sleep Mode
IDAC10
ICCT
3.15
4.33
2.16
0.4
4.625
2.5
1.4
3.3
3.6
V
29
42
68
6
54
86
mA
mA
mA
mA
Test Conditions
Guaranteed Monotonic
VIN = 0.4 V or 2.4 V
µA
µA
0.01
85
NOTES
1
All measurements are made in 4× Oversampling Mode unless otherwise specified and are guaranteed by characterization. In 2 × Oversampling Mode, power requirement for the ADV7192 is typically 3.0 V.
2
Temperature range T MIN to TMAX: 0°C to 70°C.
3
For all inputs but PAL_NTSC and ALSB.
4
For PAL_NTSC and ALSB inputs.
5
For all outputs but VSO/TTX/CLAMP.
6
For VSO/TTX/CLAMP output.
7
Measurement made in 2× Oversampling Mode.
8
IDAC is the total current required to supply all DACs including the V REF Circuitry.
9
All six DACs ON.
10
ICCT or the circuit current, is the continuous current required to drive the digital core without I PLL.
Specifications subject to change without notice.
–4–
REV. A
ADV7192
1 (VAA = 5 V 250 mV, VREF2 = 1.235 V, RSET1,2 = 1200 unless otherwise noted. All
specifications TMIN to TMAX unless otherwise noted.)
5 V DYNAMIC–SPECIFICATIONS
Parameter
Min
Hue Accuracy
Color Saturation Accuracy
Chroma Nonlinear Gain
Chroma Nonlinear Phase
Chroma/Luma Intermod
Chroma/Luma Gain Ineq
Chroma/Luma Delay Ineq
Luminance Nonlinearity
Chroma AM Noise
Chroma PM Noise
Differential Gain3
Differential Phase3
SNR (Pedestal)3
Typ
0.5
0.7
0.7
0.5
0.1
1.7
2.2
0.6
82
72
0.1
0.4
78.5
78
61.7
62
SNR (Ramp)3
Max
0.9
0.7
(0.4)
(0.15)
(78)
(78)
(61.7)
(63)
0.3 (0.5)
0.5 (0.3)
Unit
Degrees
%
±%
± Degrees
±%
±%
ns
±%
dB
dB
%
Degrees
dB rms
dB p-p
dB rms
dB p-p
Test Conditions
Referenced to 40 IRE
RMS
Peak Periodic
RMS
Peak Periodic
NOTES
1
All measurements are made in 4× Oversampling Mode unless otherwise specified and are guaranteed by characterization.
2
Temperature range T MIN to TMAX: 0°C to 70°C.
3
Values in parentheses apply to 2× Oversampling Mode.
Specifications subject to change without notice.
(VAA = 3.3 V 150 mV, VREF = 1.235 V, RSET1,2 = 1200 unless otherwise noted. All
2
MIN to TMAX unless otherwise noted.)
3.3 V DYNAMIC–SPECIFICATIONS1 specifications T
Parameter
Hue Accuracy
Color Saturation Accuracy
Luminance Nonlinearity
Chroma AM Noise
Chroma PM Noise
Chroma Nonlinear Gain
Chroma Nonlinear Phase
Chroma/Luma Intermod
Differential Gain3
Differential Phase3
SNR (Pedestal)3
SNR (Ramp)3
Min
Typ
0.5
0.8
0.6
83
71
0.7
0.5
0.1
0.2
0.5
78.5
78
62.3
61
Max
(0.5)
(0.2)
(78)
(78)
(62)
(62.5)
Unit
Degrees
%
±%
dB
dB
±%
± Degrees
±%
%
Degrees
dB rms
dB p-p
dB rms
dB p-p
NOTES
1
All measurements are made in 4× Oversampling Mode unless otherwise specified and are guaranteed by characterization.
2
Temperature range T MIN to TMAX: 0°C to 70°C.
3
Values in parentheses apply to 2× Oversampling Mode.
Specifications subject to change without notice.
REV. A
–5–
Test Conditions
Referenced to 40 IRE
RMS
Peak Periodic
RMS
Peak Periodic
ADV7192
(V = 5 V 250 mV, V
5 V TIMING CHARACTERISTICS specifications T to T
AA
MIN
Parameter
Min
Typ
REF =
1
MAX
1.235 V, RSET1,2 = 1200 V unless otherwise noted. All
unless otherwise noted.)
Max
Unit
400
kHz
µs
µs
µs
µs
ns
ns
ns
µs
Test Conditions
2
MPU PORT
SCLOCK Frequency
SCLOCK High Pulsewidth, t1
SCLOCK Low Pulsewidth, t2
Hold Time (Start Condition), t3
Setup Time (Start Condition), t4
Data Setup Time, t5
SDATA, SCLOCK Rise Time, t6
SDATA, SCLOCK Fall Time, t7
Setup Time (Stop Condition), t8
0
0.6
1.3
0.6
0.6
100
300
300
0.6
After This Period the First Clock Is Generated
Relevant for Repeated Start Condition
2
ANALOG OUTPUTS
Analog Output Delay
DAC Analog Output Skew
8
0.1
ns
ns
27
2
3
2.5
2.0
13
12
57
67
MHz
ns
ns
ns
ns
ns
ns
ns
ns
Clock Cycles
Clock Cycles
TELETEXT PORT4
Digital Output Access Time, t16
Data Setup Time, t17
Data Hold Time, t18
11
3
6
ns
ns
ns
RESET CONTROL
RESET Low Time
3
CLOCK CONTROL AND PIXEL
PORT3
fCLOCK
Clock High Time, t9
Clock Low Time, t10
Data Setup Time, t11
Data Hold Time, t12
Control Setup Time, t11
Control Hold Time, t12
Digital Output Access Time, t13
Digital Output Hold Time, t14
Pipeline Delay, t15 (2× Oversampling)
Pipeline Delay, t15 (4× Oversampling)
8
8
6
5
6
4
20
ns
2
PLL
PLL Output Frequency
54
MHz
NOTES
1
Temperature range T MIN to TMAX: 0°C to 70°C.
2
Guaranteed by characterization.
3
Pixel Port consists of:
Data: P7–P0, Y0/P8–Y7/P15 Pixel Inputs
Control: HSYNC, VSYNC, BLANK
Clock: CLKIN
4
Teletext Port consists of:
Digital Output: TTXREQ
Data: TTX
Specifications subject to change without notice.
–6–
REV. A
ADV7192
(VAA = 3.3 V 150 mV, VREF = 1.235 V, RSET1,2 = 1200 unless otherwise noted. All
1
2
MIN to TMAX unless otherwise noted.)
3.3 V TIMING CHARACTERISTICS specifications T
Parameter
Max
Unit
400
2
kHz
µs
µs
µs
µs
ns
ns
ns
µs
8
0.1
ns
ns
27
2
3
4
2.0
13
12
37
MHz
ns
ns
ns
ns
ns
ns
ns
ns
Clock Cycles
TELETEXT PORT4
Digital Output Access Time, t16
Data Setup Time, t17
Data Hold Time, t18
11
3
6
ns
ns
ns
RESET CONTROL
RESET Low Time
3
PLL
PLL Output Frequency
54
MPU PORT
SCLOCK Frequency
SCLOCK High Pulsewidth, t1
SCLOCK Low Pulsewidth, t2
Hold Time (Start Condition), t3
Setup Time (Start Condition), t4
Data Setup Time, t5
SDATA, SCLOCK Rise Time, t6
SDATA, SCLOCK Fall Time, t7
Setup Time (Stop Condition), t8
Min
0
0.6
1.3
0.6
0.6
100
300
300
0.6
ANALOG OUTPUTS
Analog Output Delay
DAC Analog Output Skew
CLOCK CONTROL AND PIXEL
PORT 3
fCLOCK
Clock High Time, t9
Clock Low Time, t10
Data Setup Time, t11
Data Hold Time, t12
Control Setup Time, t11
Control Hold Time, t12
Digital Output Access Time, t13
Digital Output Hold Time, t14
Pipeline Delay, t15 (2× Oversampling)
Typ
8
8
6
4
2, 5
3
20
ns
MHz
NOTES
1
Temperature range T MIN to TMAX: 0°C to 70°C.
2
Guaranteed by characterization.
3
Pixel Port consists of:
Data: P7–P0, Y0/P8–Y7/P15 Pixel Inputs
Control: HSYNC, VSYNC, BLANK
Clock: CLKIN
4
Teletext Port consists of:
Digital Output: TTXREQ
Data: TTX
Specifications subject to change without notice.
REV. A
–7–
Test Conditions
After This Period the First Clock Is Generated
Relevant for Repeated Start Condition
ADV7192
t5
t3
t3
SDA
t6
t1
SCL
t2
t7
t4
t8
Figure 1. MPU Port Timing Diagram
CLOCK
t9
CONTROL
I/PS
PIXEL INPUT
DATA
CONTROL
O/PS
t12
t10
HSYNC,
VSYNC,
BLANK
Cb
Y
Cr
Y
Cb
t11
HSYNC,
VSYNC,
BLANK,
CSO_HSO,
VSO, CLAMP
Y
t13
t14
Figure 2. Pixel and Control Data Timing Diagram
TTXREQ
t16
CLOCK
t17
t18
TTX
4 CLOCK
CYCLES
4 CLOCK
CYCLES
4 CLOCK
CYCLES
3 CLOCK
CYCLES
4 CLOCK
CYCLES
Figure 3. Teletext Timing Diagram
CLOCK
PROGRESSIVE
SCAN INPUT
Y0–Y9
INCLUDING
SYNC
INFORMATION
t9
t 12
t 10
Y0
Y1
Y2
Y3
Y4
Y5
Cb0–Cb9
Cb0
Cb1
Cb2
Cb3
Cb4
Cb5
Cr0–Cr9
Cr0
Cr1
Cr2
Cr3
Cr4
Cr5
t 11
Figure 4. Progressive Scan Input Timing
–8–
REV. A
ADV7192
ABSOLUTE MAXIMUM RATINGS 1
PACKAGE THERMAL PERFORMANCE
VAA to GND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 V
Voltage on any Digital Input Pin . . GND – 0.5 V to VAA + 0.5 V
Storage Temperature (TS) . . . . . . . . . . . . . . –65°C to +150°C
Junction Temperature (TJ) . . . . . . . . . . . . . . . . . . . . . . 150°C
Body Temperature (Soldering, 10 secs) . . . . . . . . . . . . . 220°C
Analog Outputs to GND2 . . . . . . . . . . . . GND – 0.5 V to VAA
The 80-lead package is used for this device. The junction-toambient (θJA) thermal resistance in still air on a four-layer PCB
is 24.7°C.
To reduce power consumption when using this part the user
can run the part on a 3.3 V supply, turn off any unused DACs.
The user must at all times stay below the maximum junction
temperature of 110°C. The following equation shows how to
calculate this junction temperature:
NOTES
1
Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; 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
Analog Output Short Circuit to any Power Supply or Common can be of an
indefinite duration.
Junction Temperature = (VAA × (IDAC + ICCT)) × θJA + 70°C TAMB
IDAC = 10 mA + (sum of the average currents consumed by
each powered-on DAC)
Average current consumed by each powered-on DAC =
(VREF × K )/RSET
VREF = 1.235 V
K = 4.2146
CSO_HSO
VSO/ TTX/CLAMP
Cr[0]
Cr[3]
Cr[2]
Cr[1]
DGND
VDD
Cr[4]
Cr[5]
Cr[6]
Cr[8]
Cr[7]
Cb[0]
Cr[9]
Cb[2]
Cb[1]
VDD
Cb[3]
DGND
PIN CONFIGURATION
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
NC 1
NC 2
60 RESET
PIN 1
IDENTIFIER
59 PAL_NTSC
P0 3
P1 4
58 RSET1
57 V
REF
56 COMP 1
P2 5
P3 6
P4 7
55 DAC A
54 DAC B
P5 8
53 VAA
52 AGND
ADV7192
LQFP
P6 9
P7 10
Y[0]/P8 11
51 DAC C
TOP VIEW
(Not to Scale)
50 DAC D
Y[1]/P9 12
Y[2]/P10 13
49 AGND
48 VAA
47 DAC E
Y[3]/P11 14
Y[4]/P12 15
Y[5]/P13 16
46 DAC F
Y[6]/P14 17
44 RSET2
43 DGND
45 COMP 2
Y[7]/P15 18
Y[8] 19
42 ALSB
Y[9] 20
41 SCRESET/RTC/TR
SCL
SDA
AGND
CLKIN
CLKOUT
VAA
DGND
VDD
TTXREQ
Cb[9]
Cb[8]
Cb[7]
Cb[6]
Cb[5]
VSYNC
BLANK
Cb[4]
HSYNC
VDD
NC = NO CONNECT
DGND
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
ORDERING GUIDE
Model
Temperature Range
Package Description
Package Option
ADV7192KST
0°C to 70°C
80-Lead Quad Flatpack
ST-80
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection. Although
the ADV7192 features proprietary ESD protection circuitry, permanent damage may occur on
devices subjected to high-energy electrostatic discharges. Therefore, proper ESD precautions are
recommended to avoid performance degradation or loss of functionality.
REV. A
–9–
WARNING!
ESD SENSITIVE DEVICE
ADV7192
PIN FUNCTION DESCRIPTIONS
Pin
No.
Mnemonic
Input/
Output
1, 2
3–10
NC
P0–P7
I
11–18
Y0/P8–Y7/P15
I
19, 20
21, 34, 68, 79
22, 33, 43, 69,
80
23
Y8–Y9
VDD
DGND
P
G
HSYNC
I/O
24
VSYNC
I/O
25
BLANK
I/O
26–31, 75–78
32
35, 49, 52
36
Cb4–Cb9, Cb0–Cb3 I
TTXREQ
O
AGND
G
CLKIN
I
37
38, 48, 53
39
40
41
42
44
CLKOUT
VAA
SCL
SDA
SCRESET/
RTC/TR
ALSB
RSET2
I
I
45
COMP 2
O
46
47
50
DAC F
DAC E
DAC D
O
O
O
51
54
55
DAC C
DAC B
DAC A
O
O
O
56
57
COMP 1
VREF
O
I/O
58
RSET1
I
59
60
PAL_NTSC
RESET
I
I
61
62
CSO_HSO
VSO/TTX/CLAMP
O
I/O
63–67, 70–74
Cr0–Cr4, Cr5–Cr9
I
O
P
I
I/O
I
Function
No Connect.
8-Bit 4:2:2 Multiplexed YCrCb Pixel Port. The LSB of the input data is set up on Pin P0
(Pin Number 3).
16-Bit 4:2:2 Multiplexed YCrCb Pixel Port (Bits 8–15). 1 × 10-Bit Progressive Scan Input for
Ydata (Bits 0–7).
1 × 10-Bit Progressive Scan Input Is Ydata (Bits 8 and 9).
Digital Power Supply (3.3 V to 5 V).
Digital Ground.
HSYNC (Modes 1, 2, and 3) Control Signal. This pin may be configured to be an output
(Master Mode) or an input (Slave Mode) and accept Sync Signals.
VSYNC Control Signal. This pin may be configured as an output (Master Mode) or as an
input (Slave Mode) and accept VSYNC as a Control Signal.
Video Blanking Control Signal. This signal is optional. For further information see
Vertical Blanking and Data Insertion Blanking Input section.
1 × 10-Bit Progressive Scan Input Port for Cb Data.
Teletext Data Request Output Signal, used to control teletext data transfer.
Analog Ground.
TTL Clock Input. Requires a stable 27 MHz reference clock for standard operation.
Alternatively, a 24.5454 MHz (NTSC) or 29.5 MHz (PAL) can be used for square pixel
operation.
Clock Output Pin.
Analog Power Supply (3.3 V to 5 V).
MPU Port Serial Interface Clock Input.
MPU Port Serial Data Input/Output.
Multifunctional Input: Real Time Control (RTC) input, Timing Reset input, Subcarrier
Reset input.
TTL Address Input. This signal sets up the LSB of the MPU address.
A 1200 Ω resistor connected from this pin to AGND is used to control full-scale amplitudes
of the Video Signals from the DAC D, E, F.
Compensation Pin for DACs D, E, and F. Connect a 0.1 µF Capacitor from COMP2
to VAA.
S-Video C/Pr/V/RED Analog Output. This DAC is capable of providing 4.33 mA output.
S-Video Y/Pb/U/BLUE Analog Output. This DAC is capable of providing 4.33 mA output.
Composite/Y (Progressive Scan)/Y/Green Analog Output. This DAC is capable of providing
4.33 mA output.
S-Video C/Pr/V/RED Analog Output. This DAC is capable of providing 4.33 mA output.
S-Video Y/Pb/U/BLUE Analog Output. This DAC is capable of providing 4.33 mA output.
Composite/Y(Progressive Scan)/Y/Green Analog Output. This DAC is capable of providing
4.33 mA output.
Compensation Pin for DACs A, B, and C. Connect a 0.1 µF Capacitor from COMP1 to VAA.
Voltage Reference Input for DACs or Voltage Reference Output (1.235 V). An external
VREF cannot be used in 4× Oversampling Mode.
A 1200 Ω resistor connected from this pin to AGND is used to control full-scale amplitudes
of the Video Signals from the DAC A, B, C.
Input signal to select PAL or NTSC mode of operation, pin set to Logic 1 selects PAL.
The input resets the on-chip timing generator and sets the ADV7192 into default mode.
See Appendix 8 for Default Register settings.
Dual function CSO or HSO Output Sync Signal at TTL Level.
Multifunctional Pin. VSO Output Sync Signal at TTL level. Teletext Data Input pin.
CLAMP TTL output signals can be used to drive external circuitry to enable clamping
of all video signals.
1 × 10-Bit Progressive Scan Input Port for Cr Data.
–10–
REV. A
ADV7192
to input video data in 3⫻ 10-bit YCrCb progressive scan format
to facilitate interfacing devices such as progressive scan systems.
DETAILED DESCRIPTION OF FEATURES
Clocking:
Single 27 MHz Clock Required to Run the Device
4 Oversampling with Internal 54 MHz PLL
Square Pixel Operation
Advanced Power Management
Programmable Video Control Features:
Digital Noise Reduction
Black Burst Signal Generation
Pedestal Level
Hue, Brightness, Contrast, and Saturation
Clamping Output Signal
VBI (Vertical Blanking Interval)
Subcarrier Frequency and Phase
LUMA Delay
CHROMA Delay
Gamma Correction
Luma And Chroma Filters
Luma SSAF (Super Subalias Filter)
Average Brightness Detection
Field Counter
Interlaced/Noninterlaced Operation
Complete On-Chip Video Timing Generator
Programmable Multimode Master/Slave Operation
Macrovision Rev 7.1
CGMS (Copy Generation Management System)
WSS (Wide Screen Signaling)
Closed Captioning Support
Teletext Insertion Port (PAL-WST)
2-Wire Serial MPU Interface
(I2C-Compatible and Fast I2C)
I2C Registers Synchronized to VSYNC
Six DACs are available on the ADV7192, each of which is capable
of providing 4.33 mA of current. In addition to the composite
output signal there is the facility to output S-Video (Y/C Video),
RGB Video and YUV Video. All YUV formats (SMPTE/EBU
N10, MII or Betacam) are supported.
The on-board SSAF (Super Subalias Filter) with extended luminance frequency response and sharp stopband attenuation
enables studio quality video playback on modern TVs, giving
optimal horizontal line resolution. An additional sharpness
control feature allows high-frequency enhancement on the
luminance signal.
DNR MODE
DNR CONTROL
NOISE SIGNAL PATH
HSYNC
VSYNC
BLANK
DNR CONTROL
10
10
YCrCb- Y
TO10
YUV
U
MATRIX 10
DNR
Y
AND
10
GAMMA
U
CORRECTION 10
V
V
10 10 10
P0
BRIGHTNESS
CONTROL
AND
ADD SYNC
AND
INTERPOLATOR
SATURATION
CONTROL
AND
ADD BURST
AND
INTERPOLATOR
INPUT FILTER
BLOCK
FILTER OUTPUT
>THRESHOLD?
Y DATA
INPUT
FILTER OUTPUT<
THRESHOLD
MAIN SIGNAL PATH
ADV7192
SCL
SDA ALSB
Cr0–Cr9
I2C MPU PORT
PROGRAMMABLE
LUMA FILTER
AND
SHARPNESS
FILTER
PROGRAMMABLE
CHROMA
FILTER
YUV-TO-RGB
MATRIX
AND
YUV LEVEL
CONTROL
BLOCK
MODULATOR
AND
HUE CONTROL
REAL-TIME
CONTROL
CIRCUIT
SIN/COS
DDS
BLOCK
CLKOUT
SCRESET/RTC/TR
REV. A
DNR OUT
Figure 6. Block Diagram for DNR Mode and DNR Sharpness
Mode
DEMUX
PLL
ADD SIGNAL ABOVE THRESHOLD
RANGE TO ORIGINAL SIGNAL
NOISE SIGNAL PATH
P15
CLKIN
GAIN
BLOCK SIZE CONTROL CORING GAIN DATA
BORDER AREA
CORING GAIN BORDER
BLOCK OFFSET
CGMS/WSS
AND
CLOSED CAPTIONING
CONTROL
TELETEXT
INSERTION
BLOCK
TTX
DNR OUT
DNR SHARPNESS MODE
RESET
TTXREQ
FILTER OUTPUT>
THRESHOLD
MAIN SIGNAL PATH
CSO_HSO
VIDEO TIMING
GENERATOR
FILTER OUTPUT
<THRESHOLD?
Y DATA
INPUT
The ADV7192 is an integrated Digital Video Encoder that
converts digital CCIR-601/656 4:2:2 8-bit or 16-bit component
video data into a standard analog baseband television signal
compatible with worldwide standards. Additionally, it is possible
VSO/CLAMP
SUBTRACT SIGNAL IN THRESHOLD
RANGE FROM ORIGINAL SIGNAL
INPUT FILTER
BLOCK
GENERAL DESCRIPTION
PAL_NTSC
GAIN
BLOCK SIZE CONTROL CORING GAIN DATA
BORDER AREA
CORING GAIN BORDER
BLOCK OFFSET
Figure 5. Detailed Functional Block Diagram
–11–
Cb0–Cb9 Y0–Y9
M
U
L
T
I
P
L
E
X
E
R
I
N
T
E
R
P
O
L
A
T
O
R
I
N
T
E
R
P
O
L
A
T
O
R
10-BIT
DAC
DAC A
10-BIT
DAC
DAC B
10-BIT
DAC
DAC C
DAC
CONTROL
BLOCK
VREF
RSET2
COMP2
10-BIT
DAC
DAC D
10-BIT
DAC
DAC F
10-BIT
DAC
DAC E
DAC
CONTROL
BLOCK
RSET1
COMP1
ADV7192
Digital Noise Reduction allows improved picture quality in removing low amplitude, high frequency noise. Figure 6 shows the DNR
functionality in the two modes available.
Programmable gamma correction is also available. The figure below
shows the response of different gamma values to a ramp signal.
HSO/CSO and VSO TTL outputs are also available and are timed
to the analog output video.
300
GAMMA-CORRECTED AMPLITUDE
GAMMA CORRECTION BLOCK OUTPUT
TO A RAMP INPUT FOR VARIOUS GAMMA VALUES
A separate teletext port enables the user to directly input teletext
data during the vertical blanking interval.
250
SIGNAL OUTPUTS
The ADV7192 also incorporates WSS and CGMS-A data control
generation.
200
0.3
0.5
The ADV7192 modes are set up over a 2-wire serial bidirectional
port (I2C-compatible) with two slave addresses, and the device
is register-compatible with the ADV7172.
150
T
PU
IN
AL
1.5
N
G
SI
100
The ADV7192 is packaged in an 80-lead LQFP package.
1.8
50
0
DATA PATH DESCRIPTION
0
50
100
150
LOCATION
200
For PAL B, D, G, H, I, M, N, and NTSCM, N modes, YCrCb
4:2:2 data is input via the CCIR-656/601-compatible Pixel Port
at a 27 MHz Data Rate. The Pixel Data is demultiplexed to form
three data paths. Y typically has a range of 16 to 235, Cr and Cb
typically have a range of 128⫾112; however, it is possible to
input data from 1 to 254 on both Y, Cb, and Cr. The ADV7192
supports PAL (B, D, G, H, I, N, M) and NTSCM, N (with
and without Pedestal) and PAL60 standards.
250
Figure 7. Signal Input (Ramp) and Selectable Gamma
Output Curves
The device is driven by a 27 MHz clock. Data can be output at
27 MHz or 54 MHz (on-board PLL) when 4⫻ oversampling is
enabled. Also, the output filter requirements in 4⫻ oversampling
and 2⫻ oversampling differ, as can be seen in Figure 8.
Digital noise reduction can be applied to the Y signal. Programmable gamma correction can also be applied to the Y
signal if required.
2 FILTER
REQUIREMENTS
0dB
The Y data can be manipulated for contrast control and a setup
level can be added for brightness control. The Cr, Cb data can
be scaled to achieve color saturation control. All settings become
effective at the start of the next field when double buffering is
enabled.
4 FILTER
REQUIREMENTS
–30dB
6.75MHz
13.5MHz
27.0MHz
40.5MHz
54.0MHz
Figure 8. Output Filter Requirements in 4× Oversampling
Mode
2
ADV7192
MPEG2
The Output Video Frames are synchronized with the incoming
data Timing Reference Codes. Optionally, the Encoder accepts
(and can generate) HSYNC, VSYNC, and FIELD timing signals.
These timing signals can be adjusted to change pulsewidth and
position while the part is in master mode.
PIXEL BUS
27MHz
ENCODER
CORE
54MHz
PLL
I
N
T
E
R
P
O
L
A
T
I
O
N
The U and V signals are modulated by the appropriate Subcarrier
Sine/Cosine waveforms and a phase offset may be added onto
the color subcarrier during active video to allow hue adjustment.
The resulting U and V signals are added together to make up
the Chrominance signal. The Luma (Y) signal can be delayed
by up to six clock cycles (at 27 MHz) and the Chroma signal
can be delayed by up to eight clock cycles (at 27 MHz).
6
D
A
C
O
U
T
P
U
T
S
The appropriate sync, blank, and burst levels are added to the
YCrCb data. Macrovision antitaping, closed-captioning and
teletext levels are also added to Y and the resultant data is interpolated to 54 MHz (4⫻ Oversampling Mode). The interpolated
data is filtered and scaled by three digital FIR filters.
54MHz
OUTPUT
RATE
The Luma and Chroma signals are added together to make up
the Composite Video Signal. All timing signals are controlled.
The YCrCb data is also used to generate RGB data with appropriate sync and blank levels. The YUV levels are scaled to output
the suitable SMPTE/EBU N10, MII, or Betacam levels.
Figure 9. PLL and 4× Oversampling Block Diagram
The ADV7192 also supports both PAL and NTSC square pixel
operation. In this case the encoder requires a 24.5454 MHz Clock
for NTSC or 29.5 MHz Clock for PAL square pixel mode operation. All internal timing is generated on-chip.
Each DAC can be individually powered off if not required. A
complete description of DAC output configurations is given in
the Mode Register 2 section.
An advanced power management circuit enables optimal control
of power consumption in normal operating modes or sleep modes.
Video output levels are illustrated in Appendix 9.
–12–
REV. A
ADV7192
When to used to interface progressive scan systems, the ADV7192
allows to input YCrCb signals in Progressive Scan format
(3 ⫻ 10-bit) before these signals are routed to the interpolation
filters and the DACs.
several different frequency responses including five low-pass
responses, a CIF response, and a QCIF response, as can be seen in
the following figures. All filter plots show the 4⫻ Oversampling
responses.
INTERNAL FILTER RESPONSE
In Extended Mode there is the option of 12 responses in the range
from –4 dB to +4 dB. The desired response can be chosen by the
user by programming the correct value via the I2C. The variation
of frequency responses can be seen in the Tables I and II. For
more detailed filter plots refer to Analog Devices’ Application
Note AN-562.
The Y Filter supports several different frequency responses
including two low-pass responses, two notch responses, an
Extended (SSAF) response with or without gain boost/attenuation,
a CIF response, and a QCIF response. The UV filters support
Table I. Luminance Internal Filter Specifications (4 Oversampling)
Filter Type
Low-Pass (NTSC)
Low-Pass (PAL)
Notch (NTSC)
Notch (PAL)
Extended (SSAF)
CIF
QCIF
Filter Selection
MR04
0
0
0
0
1
1
1
MR03
0
0
1
1
0
0
1
MR02
0
1
0
1
0
1
0
Passband
Ripple1 (dB)
3 dB Bandwidth2
(MHz)
0.16
0.1
0.09
0.1
0.04
0.127
Monotonic
4.24
4.81
2.3/4.9/6.6
3.1/5.6/6.4
6.45
3.02
1.5
NOTES
1
Passband Ripple is defined as the fluctuations from the 0 dB response in the passband, measured in (dB). The
passband is defined to have 0–fc frequency limits for a low-pass filter, 0–f1 and f2–infinity for a notch filter,
where fc, f1, f2 are the –3 dB points.
2
3 dB bandwidth refers to the –3 dB cutoff frequency.
Table II. Chrominance Internal Filter Specifications (4 Oversampling)
Filter Type
1.3 MHz Low-Pass
0.65 MHz Low-Pass
1.0 MHz Low-Pass
2.0 MHz Low-Pass
3.0 MHz Low-Pass
CIF
QCIF
Filter Selection
MR07
0
0
0
0
1
1
1
MR06
0
0
1
1
1
0
1
MR05
0
1
0
1
1
1
0
Passband
Ripple1 (dB)
3 dB Bandwidth2
(MHz)
0.09
Monotonic
Monotonic
0.048
Monotonic
Monotonic
Monotonic
1.395
0.65
1.0
2.2
3.2
0.65
0.5
NOTES
1
Passband Ripple is defined as the fluctuations from the 0 dB response in the passband, measured in (dB). The
passband is defined to have 0–fc frequency limits for a low-pass filter, 0–f1 and f2–infinity for a notch filter,
where fc, f1, f2 are the –3 dB points.
2
3 dB bandwidth refers to the –3 dB cutoff frequency.
REV. A
–13–
0
0
–10
–10
–20
–20
MAGNITUDE – dB
MAGNITUDE – dB
ADV7192–Typical Performance Characteristics
–30
–40
–30
–40
–50
–50
–60
–60
–70
0
2
4
6
8
FREQUENCY – MHz
10
–70
12
0
0
0
–10
–10
–20
–20
–30
–40
–60
–60
2
4
6
8
FREQUENCY – MHz
10
–70
12
TPC 2. PAL Low-Pass Luma Filter
12
0
2
4
6
8
FREQUENCY – MHz
10
12
TPC 5. Extended Mode (SSAF) Luma Filter
0
4
–10
2
0
–20
MAGNITUDE – dB
MAGNITUDE – dB
10
–40
–50
0
6
8
FREQUENCY – MHz
–30
–50
–70
4
TPC 4. PAL Notch Luma Filter
MAGNITUDE – dB
MAGNITUDE – dB
TPC 1. NTSC Low-Pass Luma Filter
2
–30
–40
–2
–4
–6
–50
–8
–60
–70
–10
0
2
4
6
8
FREQUENCY – MHz
10
–12
12
TPC 3. NTSC Notch Luma Filter
0
1
2
4
3
FREQUENCY – MHz
5
6
7
TPC 6. Extended SSAF Luma Filter and Programmable
Gain/Attenuation Showing +4 dB/–12 dB Range
–14–
REV. A
ADV7192
1
0
–10
MAGNITUDE – dB
MAGNITUDE – dB
0
–1
–2
–3
–20
–30
–40
–50
–4
–5
–60
0
1
4
3
FREQUENCY – MHz
2
5
6
–70
7
0
TPC 7. Extended SSAF and Programmable Attenuation,
Showing Range 0 dB/–4 dB
2
4
6
8
FREQUENCY – MHz
10
12
10
12
TPC 10. Luma QCIF Filter
5
0
MAGNITUDE – dB
4
–10
MAGNITUDE – dB
3
2
1
–20
–30
–40
–50
0
–60
–1
0
1
4
3
FREQUENCY – MHz
2
5
6
–70
7
0
0
–10
–10
–20
–20
–30
–40
–60
–60
2
4
6
8
FREQUENCY – MHz
10
–70
12
TPC 9. Luma CIF Filter
REV. A
6
8
FREQUENCY – MHz
–40
–50
0
4
–30
–50
–70
2
TPC 11. Chroma 0.65 MHz Low-Pass Filter
MAGNITUDE – dB
MAGNITUDE – dB
TPC 8. Extended SSAF and Programmable Gain, Showing
Range 0 dB/+4 dB
0
0
2
4
6
8
FREQUENCY – MHz
10
TPC 12. Chroma 1.0 MHz Low-Pass Filter
–15–
12
0
0
–10
–10
–20
–20
MAGNITUDE – dB
MAGNITUDE – dB
ADV7192
–30
–40
–30
–40
–50
–50
–60
–60
–70
0
2
4
6
8
FREQUENCY – MHz
10
–70
12
0
0
0
–10
–10
–20
–20
–30
–40
–60
–60
2
4
6
8
FREQUENCY – MHz
10
10
12
10
12
–40
–50
0
6
8
FREQUENCY – MHz
–30
–50
–70
4
TPC 16. Chroma CIF Filter
MAGNITUDE – dB
MAGNITUDE – dB
TPC 13. Chroma 1.3 MHz Low-Pass Filter
2
–70
12
TPC 14. Chroma 2 MHz Low-Pass Filter
0
2
4
6
8
FREQUENCY – MHz
TPC 17. Chroma QCIF Filter
0
MAGNITUDE – dB
–10
–20
–30
–40
–50
–60
–70
0
2
4
6
8
FREQUENCY – MHz
10
12
TPC 15. Chroma 3 MHz Low-Pass Filter
–16–
REV. A
ADV7192
FEATURES: FUNCTIONAL DESCRIPTION
CSO, HSO, AND VSO OUTPUTS
BLACK BURST OUTPUT
The ADV7192 supports three output timing signals, CSO
(composite sync signal), HSO (Horizontal Sync Signal) and
VSO (Vertical Sync Signal). These output TTL signals are aligned
with the analog video outputs. See Figure 14 for an example
of these waveforms. (Mode Register 7.)
It is possible to output a black burst signal from two DACs. This
signal output is very useful for professional video equipment
since it enables two video sources to be locked together. (Mode
Register 9.)
EXAMPLE:- NTSC
DIGITAL DATA
GENERATOR
ADV7192
525
1
2
3
4
5
6
7
8
9
10
11–19
OUTPUT
VIDEO
CVBS
BLACK BURST OUTPUT
CSO
CVBS
DIGITAL DATA
GENERATOR
HSO
ADV7192
VSO
Figure 10. Possible Application for the Black Burst Output
Signal
Figure 14. CSO, HSO, VSO Timing Diagram
COLOR BAR GENERATION
BRIGHTNESS DETECT
This feature is used to monitor the average brightness of the
incoming Y video signal on a field by field basis. The information
is read from the I2C and based on this information the color
saturation, contrast and brightness controls can be adjusted (for
example to compensate for very dark pictures). (Brightness Detect
Register.)
The ADV7192 can be configured to generate 100/7.5/75/7.5
color bars for NTSC or 100/0/75/0 color bars for PAL. (Mode
Register 4.)
COLOR BURST SIGNAL CONTROL
The burst information can be switched on and off the composite
and chroma video output. (Mode Register 4.)
CHROMA/LUMA DELAY
COLOR CONTROLS
The luminance data can be delayed by maximum of six clock
cycles. Additionally the Chroma can be delayed by a maximum
of eight clock cycles (one clock cycle at 27 MHz). (Timing Register 0 and Mode Register 9.)
The ADV7192 allows the user to control the brightness, contrast,
hue and saturation of the color. The control registers may be
double-buffered, meaning that any modification to the registers
will be done outside the active video region and, therefore, changes
made will not be visible during active video.
Contrast Control
Contrast adjustment is achieved by scaling the Y input data by a
factor programmed by the user. This factor allows the data to be
scaled between 0% and 150%. (Contrast Control Register.)
CHROMA DELAY
Figure 11. Chroma Delay
LUMA DELAY
Figure 12. Luma Delay
Brightness Control
The brightness is controlled by adding a programmable setup level
onto the scaled Y data. This brightness level may be added onto
the Y data. For NTSC with pedestal, the setup can vary from
0 IRE to 22.5 IRE. For NTSC without pedestal and PAL, the
setup can vary from –7.5 IRE to +15 IRE. (Brightness Control
Register.)
Color Saturation
CLAMP OUTPUT
The ADV7192 has a programmable clamp TTL output signal.
This clamp signal is programmable to the front and back porch.
The clamp signal can be varied by one to three clock cycles in a
positive and negative direction from the default position.
(Mode Register 5, Mode Register 7.)
CLAMP O/P SIGNALS
CVBS
OUTPUT PIN
MR57 = 1
CLAMP
OUTPUT PIN
MR57 = 0
Figure 13. Clamp Output Timing
REV. A
Color adjustment is achieved by scaling the Cr and Cb input
data by a factor programmed by the user. This factor allows the
data to be scaled between 0% and 200%. (U Scale Register and
V Scale Register.)
Hue Adjust Control
The hue adjustment is achieved on the composite and chroma
outputs by adding a phase offset onto the color subcarrier in the
active video but leaving the color burst unmodified, i.e., only
the phase between the video and the colorburst is modified and
hence the hue is shifted. The ADV7192 provides a range of
± 22° in increments of 0.17578125°. (Hue Adjust Register.)
CHROMINANCE CONTROL
The color information can be switched on and off the composite, chroma and color component video outputs. (Mode
Register 4.)
–17–
ADV7192
UNDERSHOOT LIMITER
POWER-ON RESET
A limiter is placed after the digital filters. This prevents any
synchronization problems for TVs. The level of undershoot is
programmable between –1.5 IRE, –6 IRE, –11 IRE when operating in 4× Oversampling Mode. In 2× Oversampling Mode the
limits are –7.5 IRE and 0 IRE. (Mode Register 9 and Timing
Register 0.)
After power-up, it is necessary to execute a RESET operation. A
reset occurs on the falling edge of a high-to-low transition on the
RESET pin. This initializes the pixel port such that the data on
the pixel inputs pins is ignored. See Appendix 8 for the register
settings after RESET is applied.
PROGRESSIVE SCAN INPUT
DIGITAL NOISE REDUCTION
DNR is applied to the Y data only. A filter block selects the
high frequency, low amplitude components of the incoming
signal (DNR Input Select). The absolute value of the filter output
is compared to a programmable threshold value (DNR Threshold Control). There are two DNR modes available: DNR Mode
and DNR Sharpness Mode.
It is possible to input data to the ADV7192 in progressive scan
format. For this purpose the input pins Y0/P8–Y7/P15, Y8–Y9,
Cr0–Cr9 and Cb0–Cb9 accept 10-bit Y data, 10-bit Cb data
and 10-bit Cr data. The data is clocked into the part at 27 MHz.
The data is then filtered and sinc corrected in an 2⫻ Interpolation filter and then output to three video DACs at 54 MHz
(to interface to a progressive scan monitor).
In DNR Mode, if the absolute value of the filter output is smaller
than the threshold, it is assumed to be noise. A programmable
amount (Coring Gain Control) of this noise signal will be subtracted from the original signal.
0
–10
In DNR Sharpness Mode, if the absolute value of the filter output
is less than the programmed threshold, it is assumed to be noise,
as before. Otherwise, if the level exceeds the threshold, now
being identified as a valid signal, a fraction of the signal (Coring
Gain Control) will be added to the original signal in order to boost
high frequency components and to sharpen the video image.
AMPLITUDE – dB
–20
–30
–40
–50
In MPEG systems it is common to process the video information
in blocks of 8 × 8 pixels for MPEG2 systems, or 16 × 16 pixels
for MPEG1 systems ('Block Size Control'). DNR can be applied
to the resulting block transition areas that are known to contain
noise. Generally the block transition area contains two pixels. It
is possible to define this area to contain four pixels (Border Area
Control).
–60
–70
0
–10
DOUBLE BUFFERING
–20
30
AMPLITUDE – dB
–30
–40
–50
–60
–70
0
GAMMA CORRECTION CONTROL
In NTSC mode it is possible to have the pedestal signal generated on the output video signal. (Mode Register 2.)
25
0
Double buffering can be enabled or disabled on the following
registers: Closed Captioning Registers, Brightness Control Register, V-Scale, U-Scale Contrast Control Register, Hue Adjust
Register, Macrovision Registers, and the Gamma Curve Select
bit. These registers are updated once per field on the falling
edge of the VSYNC signal. Double Buffering improves the overall
performance of the ADV7192, since modifications to register
settings will not be made during active video, but take effect on
the start of the active video. (Mode Register 8.)
NTSC PEDESTAL CONTROL
10
15
20
FREQUENCY – MHz
Figure 15. Plot of the Interpolation Filter for the Y Data
It is also possible to compensate for variable block positioning or
differences in YCrCb pixel timing with the use of the Block Offset
Control. (Mode Register 8, DNR Registers 0–2.)
Gamma correction may be performed on the luma data. The
user has the choice to use either of two different gamma curves,
A or B. At any one time one of these curves is operational if
gamma correction is enabled. Gamma correction allows the
mapping of the luma data to a user-defined function. (Mode
Register 8, Gamma Correction Registers 0–13.)
5
5
10
15
20
FREQUENCY – MHz
25
30
Figure 16. Plot of the Interpolation Filter for the CrCb Data
It is assumed that there is no color space conversion or any other
such operation to be performed on the incoming data. Thus if
these DAC outputs are to drive a TV, all relevant timing and
synchronization data should be contained in the incoming digital
Y data. An FPGA can be used to achieve this,
The block diagram below shows a possible configuration for
progressive scan mode using the ADV7192.
–18–
REV. A
ADV7192
error would be maintained forever, but in reality, this is impossible to achieve due to clock frequency variations. This effect is
reduced by the use of a 32-bit DDS, which generates this SCH.
ENCODER
ADV7192
54MHz
PLL
27MHz
MPEG2
PIXEL BUS
PROGRESSIVE
SCAN
DECODER
ENCODER
CORE
30-BIT INTERFACE
I
N
T
E
R
P
2 O
L
A
T
I
O
N
6
D
A
C
O
U
T
P
U
T
S
Figure 17. Block Diagram Using the ADV7192 in Progressive Scan Mode
The progressive scan decoder deinterlaces the data from the
MPEG2 decoder. This now means that there are 525 video lines
per field in NTSC mode and 625 video lines per field in PAL
mode. The duration of the video line is now 32 µs.
It is important to note that the data from the MPEG2 decoder
is in 4:2:2 format. The data output from the progressive scan
decoder is in 4:4:4 format. Thus it is assumed that some form of
interpolation on the color component data is performed in the
progressive scan decoder IC. (Mode Register 8.)
REAL-TIME CONTROL, SUBCARRIER RESET, AND
TIMING RESET
Together with the SCRESET/RTC/TR pin and Mode Register 4
(Genlock Control), the ADV7192 can be used in (a) Timing
Reset Mode, (b) Subcarrier Phase Reset Mode or (c) RTC Mode.
(a) A TIMING RESET is achieved in holding this pin high. In
this state the horizontal and vertical counters will remain reset.
On releasing this pin (set to low), the internal counters will
commence counting again. The minimum time the pin has
to be held high is 37 ns (1 clock cycle at 27 MHz), otherwise
the reset signal might not be recognized.
(b) The SUBCARRIER PHASE will reset to that of Field 0 at
the start of the following field when a low to high transition
occurs on this input pin.
(c) In RTC MODE, the ADV7192 can be used to lock to an
external video source.
The real-time control mode allows the ADV7192 to automatically alter the subcarrier frequency to compensate for line
length variations. When the part is connected to a device
that outputs a digital datastream in the RTC format (such as
a ADV7185 video decoder, see Figure 21), the part will
automatically change to the compensated subcarrier frequency
on a line-by-line basis. This digital datastream is 67 bits
wide and the subcarrier is contained in Bits 0 to 21. Each bit
is two clock cycles long. 00Hex should be written into all four
Subcarrier Frequency registers when using this mode. (Mode
Register 4.)
Resetting the SCH phase every four or eight fields avoids the
accumulation of SCH phase error, and results in very minor SCH
phase jumps at the start of the four or eight field sequence.
Resetting the SCH phase should not be done if the video source
does not have stable timing or the ADV7192 is configured in RTC
mode. Under these conditions (unstable video) the Subcarrier
Phase Reset should be enabled but no reset applied. In this
configuration the SCH Phase will never be reset; this means that
the output video will now track the unstable input video. The Subcarrier Phase Reset when applied will reset the SCH phase to Field
0 at the start of the next field (e.g., Subcarrier Phase Reset applied
in Field 5 (PAL) on the start of the next field SCH phase will be
reset to Field 0). (Mode Register 4.)
SLEEP MODE
If, after RESET, the SCRESET/RTC/TR and NTSC_PAL pins
are both set high, the ADV7192 will power up in Sleep Mode to
facilitate low power consumption before all registers have been
initialized.
If Power-up in Sleep Mode is disabled, Sleep Mode control
passes to the Sleep Mode control in Mode Register 2 (i.e., control via I2C). (Mode Register 2 and Mode Register 6.)
SQUARE PIXEL MODE
The ADV7192 can be used to operate in square pixel mode. For
NTSC operation an input clock of 24.5454 MHz is required.
Alternatively, for PAL operation, an input clock of 29.5 MHz
is required. The internal timing logic adjusts accordingly for
square pixel mode operation. Square pixel mode is not available
in 4× Oversampling mode. (Mode Register 2.)
VERTICAL BLANKING DATA INSERTION AND BLANK
INPUT
It is possible to allow encoding of incoming YCbCr data on
those lines of VBI that do not have line sync or pre-/post-equalization pulses . This mode of operation is called Partial Blanking. It
allows the insertion of any VBI data (Opened VBI) into the
encoded output waveform, this data is present in digitized
incoming YCbCr data stream (e.g., WSS data, CGMS, VPS
etc.). Alternatively the entire VBI may be blanked (no VBI data
inserted) on these lines. VBI is available in all timing modes.
It is possible to allow control over the BLANK signal using
Timing Register 0. When the BLANK input is enabled (TR03 =
0 and input pin tied low), the BLANK input can be used to
input externally generated blank signals in Slave Mode 1, 2, or
3. When the BLANK input is disabled (TR03 = 1 and input pin
tied low or tied high) the BLANK input is not used and the
ADV7192 automatically blanks all normally blank lines as per
CCIR-624. (Timing Register 0.)
SCH PHASE MODE
The SCH phase is configured in default mode to reset every
four (NTSC) or eight (PAL) fields to avoid an accumulation of
SCH phase error over time. In an ideal system, zero SCH phase
REV. A
–19–
ADV7192
YUV LEVELS
Betacam
SMPTE
MII
Sync
286 mV
300 mV
300 mV
–30dB
6.75MHz
As the data path is branched at the output of the filters, the luma
signal relating to the CVBS or S-Video Y/C output is unaltered.
Only the Y output of the YCrCb outputs is scaled. This control
allows color component levels to have a peak-peak amplitude of
700 mV, 1000 mV or the default values of 934 mV in NTSC and
700 mV in PAL. (Mode Register 5.)
16-BIT INTERFACE
It is possible to input data in 16-bit format. In this case, the
interface only operates if the data is accompanied by separate
HSYNC/VSYNC/BLANK signals. Sixteen-bit mode is not
available in Slave Mode 0 since EAV/SAV timing codes are
used. (Mode Register 8.)
4 OVERSAMPLING AND INTERNAL PLL
It is possible to operate all six DACs at 27 MHz (2× Oversampling) or 54 MHz (4× Oversampling).
The ADV7192 is supplied with a 27 MHz clock synced with the
incoming data. Two options are available: to run the device
throughout at 27 MHz or to enable the PLL. In the latter case,
even if the incoming data runs at 27 MHz, 4× Oversampling and
the internal PLL will output the data at 54 MHz.
NOTE
In 4× Oversampling Mode the requirements for the optional
output filters are different from those in 2× Oversampling. (Mode
Register 1, Mode Register 6.) See Appendix 6.
MPEG2
PIXEL BUS
27MHz
4 FILTER
REQUIREMENTS
Video
714 mV
700 mV
700 mV
2
ENCODE
ADV7192
ENCODER
CORE
54MHz
PLL
I
N
T
E
R
P
O
L
A
T
I
O
N
2 FILTER
REQUIREMENTS
0dB
This functionality allows the ADV7192 to output SMPTE levels
or Betacam levels on the Y output when configured in PAL or
NTSC mode.
6
27.0MHz
40.5MHz
54.0MHz
Figure 19. Output Filter Requirements in 2 × and 4 × Oversampling Mode
VIDEO TIMING DESCRIPTION
The ADV7192 is intended to interface to off-the-shelf MPEG1
and MPEG2 Decoders. As a consequence, the ADV7192 accepts
4:2:2 YCrCb Pixel Data via a CCIR-656 Pixel Port and has
several Video Timing Modes of operation that allow it to be
configured as either System Master Video Timing Generator or
a Slave to the System Video Timing Generator. The ADV7192
generates all of the required horizontal and vertical timing periods
and levels for the analog video outputs.
The ADV7192 calculates the width and placement of analog
sync pulses, blanking levels, and color burst envelopes. Color
bursts are disabled on appropriate lines and serration and equalization pulses are inserted where required.
In addition the ADV7192 supports a PAL or NTSC square pixel
operation. The part requires an input pixel clock of 24.5454 MHz
for NTSC square pixel operation and an input pixel clock of
29.5 MHz for PAL square pixel operation. The internal horizontal
line counters place the various video waveform sections in the correct location for the new clock frequencies.
The ADV7192 has four distinct Master and four distinct Slave
timing configurations. Timing Control is established with
the bidirectional HSYNC, BLANK and VSYNC pins. Timing Register 1 can also be used to vary the timing pulsewidths
and where they occur in relation to each other. (Mode Register 2, Timing Register 0, 1.)
RESET SEQUENCE
D
A
C
O
U
T
P
U
T
S
13.5MHz
54MHz
OUTPUT
Figure 18. PLL and 4× Oversampling Block Diagram
When RESET becomes active the ADV7192 reverts to the default
output configuration (see Appendix 8 for register settings). The
ADV7192 internal timing is under the control of the logic level
on the NTSC_PAL pin.
When RESET is released Y, Cr, Cb values corresponding to a
black screen are input to the ADV7192. Output timing signals
are still suppressed at this stage. DACs A, B, C are switched off
and DACs D, E, F are switched on.
When the user requires valid data, Pixel Data Valid Control is
enabled (MR26 = 1) to allow the valid pixel data to pass through
the encoder. Digital output timing signals become active and the
encoder timing is now under the control of the Timing Registers. If at this stage, the user wishes to select a different video
standard to that on the NTSC_PAL pin, Standard I2C Control
should be enabled (MR25 = 1) and the video standard required
is selected by programming Mode Register 0 (Output Video Standard Selection). Figure 20 illustrates the RESET sequence timing.
–20–
REV. A
ADV7192
RESET
DAC D,
DAC E
XXXXXXX
XXXXXXX
BLACK VALUE WITH SYNC
VALID VIDEO
DAC F
XXXXXXX
XXXXXXX
BLACK VALUE
VALID VIDEO
DAC A,
DAC B,
DAC C
XXXXXXX
VALID VIDEO
OFF
MR26
PIXEL_DATA_VALID
XXXXXXX
DIGITAL TIMING
XXXXXXX
0
1
DIGITAL TIMING SIGNALS SUPPRESSED
TIMING ACTIVE
Figure 20. RESET Sequence Timing Diagram
ADV7192
CLOCK
COMPOSITE
VIDEO
e.g., VCR
OR CABLE
LCC1
SCRESET/RTC/TR
GLL
GREEN/COMPOSITE/Y
BLUE/LUMA/U
VIDEO
DECODER
P7–P0
P19–P12
ADV7185
RED/CHROMA/V
GREEN/COMPOSITE/Y
BLUE/LUMA/U
RED/CHROMA/V
H/L TRANSITION
COUNT START
14 BITS
LOW
RESERVED
128
13
4 BITS
RESERVED
0
FSCPLL INCREMENT1
21
SEQUENCE
BIT2
5 BITS
RESET
RESERVED
BIT3
RESERVED
0
RTC
TIME SLOT: 01
14
NOT USED IN
ADV7192
67 68
19
VALID
SAMPLE
INVALID
SAMPLE
8/LINE
LOCKED CLOCK
NOTES:
1F
SC PLL INCREMENT IS 22 BITS LONG, VALUE LOADED INTO ADV7192 FSC DDS REGISTER IS FSC PLL INCREMENTS
BITS 21:0 PLUS BITS 0:9 OF SUBCARRIER FREQUENCY REGISTERS. ALL ZEROS SHOULD BE WRITTEN TO THE
SUBCARRIER FREQUENCY REGISTERS OF THE ADV7192.
2SEQUENCE BIT
PAL: 0 = LINE NORMAL, 1 = LINE INVERTED
NTSC: 0 = NO CHANGE
3RESET BIT
RESET ADV7192’s DDS
Figure 21. RTC Timing and Connections
REV. A
–21–
ADV7192
Mode 0 (CCIR–656): Slave Option
(Timing Register 0 TR0 = X X X X X 0 0 0)
The ADV7192 is controlled by the SAV (Start Active Video) and EAV (End Active Video) Time Codes in the Pixel Data. All timing
information is transmitted using a 4-byte Synchronization Pattern. A synchronization pattern is sent immediately before and after each line
during active picture and retrace. Mode 0 is illustrated in Figure 22. The HSYNC, VSYNC and BLANK (if not used) pins should be
tied high during this mode. Blank output is available.
ANALOG
VIDEO
EAV CODE
SAV CODE
C
F 0 0 X 8 1 8 1
Y r Y F 0 0 Y 0 0 0 0
INPUT PIXELS
0 F F A A A
0 F F B B B
ANCILLARY DATA
(HANC)
4 CLOCK
NTSC/PAL M SYSTEM
(525 LlNES/60Hz)
8 1 8 1 F 0 0 X C
C
C
C
C
0 0 0 0 F 0 0 Y b Y r Y b Y r Y b
4 CLOCK
268 CLOCK
1440 CLOCK
4 CLOCK
4 CLOCK
PAL SYSTEM
(625 LINES/50Hz)
280 CLOCK
1440 CLOCK
END OF ACTIVE
VIDEO LINE
START OF ACTIVE
VIDEO LINE
Figure 22. Timing Mode 0, Slave Mode
Mode 0 (CCIR–656): Master Option
(Timing Register 0 TR0 = X X X X X 0 0 1)
The ADV7192 generates H, V, and F signals required for the SAV (Start Active Video) and EAV (End Active Video) Time Codes in the
CCIR656 standard. The H bit is output on the HSYNC pin, the V bit is output on the BLANK pin and the F bit is output on the
VSYNC pin. Mode 0 is illustrated in Figure 23 (NTSC) and Figure 24 (PAL). The H, V, and F transitions relative to the video waveform
are illustrated in Figure 25.
DISPLAY
DISPLAY
VERTICAL BLANK
522
523
524
525
1
2
3
4
5
6
7
8
9
10
11
20
21
22
H
V
F
EVEN FIELD
ODD FIELD
DISPLAY
DISPLAY
VERTICAL BLANK
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
283
284
285
H
V
F
ODD FIELD
EVEN FIELD
Figure 23. Timing Mode 0, NTSC Master Mode
–22–
REV. A
ADV7192
DISPLAY
DISPLAY
622
623
VERTICAL BLANK
624
625
1
2
3
4
5
6
7
21
22
23
H
V
F
EVEN FIELD
ODD FIELD
DISPLAY
DISPLAY
VERTICAL BLANK
309
310
311
312
313
314
315
316
317
318
319
320
H
V
F
ODD FIELD
EVEN FIELD
Figure 24. Timing Mode 0, PAL Master Mode
ANALOG
VIDEO
H
F
V
Figure 25. Timing Mode 0 Data Transitions, Master Mode
REV. A
–23–
334
335
336
ADV7192
Mode 1: Slave Option HSYNC, BLANK, FIELD
(Timing Register 0 TR0 = X X X X X 0 1 0)
In this mode the ADV7192 accepts Horizontal SYNC and Odd/ Even FIELD signals. A transition of the FIELD input when HSYNC
is low indicates a new frame, i.e., Vertical Retrace. The BLANK signal is optional. When the BLANK input is disabled the ADV7192
automatically blanks all normally blank lines as per CCIR-624. Mode 1 is illustrated in Figure 26 (NTSC) and Figure 27 (PAL).
DISPLAY
DISPLAY
522
523
524
VERTICAL BLANK
525
1
2
3
4
6
5
7
8
9
10
20
11
21
22
HSYNC
BLANK
EVEN FIELD
FIELD
ODD FIELD
DISPLAY
DISPLAY
260
261
262
VERTICAL BLANK
263
264
265
266
267
268
269
270
271
272
273
283
274
284
285
HSYNC
BLANK
ODD FIELD
FIELD
EVEN FIELD
Figure 26. Timing Mode 1, NTSC
DISPLAY
622
623
DISPLAY
VERTICAL BLANK
624
625
1
2
3
4
5
6
7
21
22
23
HSYNC
BLANK
FIELD
EVEN FIELD
ODD FIELD
DISPLAY
DISPLAY
309
310
VERTICAL BLANK
311
312
313
314
315
316
317
318
319
320
334
335
336
HSYNC
BLANK
FIELD
ODD FIELD
EVEN FIELD
Figure 27. Timing Mode 1, PAL
–24–
REV. A
ADV7192
Mode 1: Master Option HSYNC, BLANK, FIELD
(Timing Register 0 TR0 = X X X X X 0 1 1)
In this mode the ADV7192 can generate Horizontal SYNC and Odd/Even FIELD signals. A transition of the FIELD input when
HSYNC is low indicates a new frame i.e., Vertical Retrace. The BLANK signal is optional. When the BLANK input is disabled the
ADV7192 automatically blanks all normally blank lines as per CCIR-624. Pixel data is latched on the rising clock edge following the
timing signal transitions. Mode 1 is illustrated in Figure 26 (NTSC) and Figure 27 (PAL). Figure 28 illustrates the HSYNC, BLANK and
FIELD for an odd or even field transition relative to the pixel data.
HSYNC
FIELD
PAL = 12 CLOCK/2
NTSC = 16 CLOCK/2
BLANK
PIXEL
DATA
Cb
Y
Cr
Y
PAL = 132 CLOCK/2
NTSC = 122 CLOCK/2
Figure 28. Timing Mode 1 Odd/Even Field Transitions Master/Slave
Mode 2: Slave Option HSYNC, VSYNC, BLANK
(Timing Register 0 TR0 = X X X X X 1 0 0)
In this mode the ADV7192 accepts Horizontal and Vertical SYNC signals. A coincident low transition of both HSYNC and VSYNC
inputs indicates the start of an Odd Field. A VSYNC low transition when HSYNC is high indicates the start of an Even Field.
The BLANK signal is optional. When the BLANK input is disabled the ADV7192 automatically blanks all normally blank lines
as per CCIR-624. Mode 2 is illustrated in Figure 29 (NTSC) and Figure 30 (PAL).
DISPLAY
522
523
524
DISPLAY
VERTICAL BLANK
525
1
2
3
4
6
5
7
8
10
9
11
20
21
22
HSYNC
BLANK
EVEN FIELD
VSYNC
ODD FIELD
DISPLAY
DISPLAY
260
261
262
263
VERTICAL BLANK
264
265
266
267
268
269
270
271
HSYNC
BLANK
VSYNC
ODD FIELD
EVEN FIELD
Figure 29. Timing Mode 2, NTSC
REV. A
–25–
272
273
274
283
284
285
ADV7192
DISPLAY
622
623
DISPLAY
VERTICAL BLANK
624
625
1
2
3
4
6
5
7
21
22
23
HSYNC
BLANK
VSYNC
EVEN FIELD
ODD FIELD
DISPLAY
DISPLAY
309
310
VERTICAL BLANK
311
312
313
314
315
316
318
317
319
320
334
335
336
HSYNC
BLANK
VSYNC
ODD FIELD
EVEN FIELD
Figure 30. Timing Mode 2, PAL
Mode 2: Master Option HSYNC, VSYNC, BLANK
(Timing Register 0 TR0 = X X X X X 1 0 1)
In this mode the ADV7192 can generate Horizontal and Vertical SYNC signals. A coincident low transition of both HSYNC and
VSYNC inputs indicates the start of an Odd Field. A VSYNC low transition when HSYNC is high indicates the start of an Even
Field. The BLANK signal is optional. When the BLANK input is disabled the ADV7192 automatically blanks all normally blank lines as
per CCIR-624. Mode 2 is illustrated in Figure 29 (NTSC) and Figure 30 (PAL). Figure 31 illustrates the HSYNC, BLANK and
VSYNC for an even-to-odd field transition relative to the pixel data. Figure 32 illustrates the HSYNC, BLANK and VSYNC for
an odd-to-even field transition relative to the pixel data.
HSYNC
VSYNC
PAL = 12 CLOCK/2
NTSC = 16 CLOCK/2
BLANK
PIXEL
DATA
Cb
Y
Cr
Y
PAL = 132 CLOCK/2
NTSC = 122 CLOCK/2
Figure 31. Timing Mode 2, Even-to-Odd Field Transition Master/Slave
HSYNC
VSYNC
PAL = 12 CLOCK/2
NTSC = 16 CLOCK/2
PAL = 864 CLOCK/2
NTSC = 858 CLOCK/2
BLANK
Cb
PIXEL
DATA
Y
Cr
Y
Cb
PAL = 132 CLOCK/2
NTSC = 122 CLOCK/2
Figure 32. Timing Mode 2, Odd-to-Even Field Transition Master/Slave
–26–
REV. A
ADV7192
Mode 3: Master/Slave Option HSYNC, BLANK, FIELD
(Timing Register 0 TR0 = X X X X X 1 1 0 or X X X X X 1 1 1)
In this mode the ADV7192 accepts or generates Horizontal SYNC and Odd/Even FIELD signals. A transition of the FIELD input when
HSYNC is high indicates a new frame i.e., Vertical Retrace. The BLANK signal is optional. When the BLANK input is disabled the
ADV7192 automatically blanks all normally blank lines as per CCIR-624. Mode 3 is illustrated in Figure 33 (NTSC) and
Figure 34 (PAL).
DISPLAY
522
523
524
DISPLAY
VERTICAL BLANK
525
1
2
3
4
6
5
7
8
9
10
20
11
21
22
HSYNC
BLANK
FIELD
EVEN FIELD
ODD FIELD
DISPLAY
DISPLAY
260
261
262
263
VERTICAL BLANK
264
265
266
267
268
269
270
271
272
273
283
274
284
285
HSYNC
BLANK
FIELD
ODD FIELD
EVEN FIELD
Figure 33. Timing Mode 3, NTSC
DISPLAY
622
623
DISPLAY
VERTICAL BLANK
624
625
1
2
3
4
5
6
7
21
22
23
HSYNC
BLANK
FIELD
EVEN FIELD
ODD FIELD
DISPLAY
DISPLAY
309
310
VERTICAL BLANK
311
312
313
314
315
316
317
318
HSYNC
BLANK
FIELD
EVEN FIELD
ODD FIELD
Figure 34. Timing Mode 3, PAL
REV. A
–27–
319
320
334
335
336
ADV7192
MPU PORT DESCRIPTION
The ADV7192 acts as a standard slave device on the bus. The
data on the SDA pin is eight bits long supporting the 7-bit
addresses plus the R/W bit. It interprets the first byte as the device
address and the second byte as the starting subaddress. The
subaddresses autoincrement allowing data to be written to or read
from the starting subaddress. A data transfer is always terminated
by a stop condition. The user can also access any unique subaddress
register on a one-by-one basis without having to update all the
registers. There is one exception. The Subcarrier Frequency
Registers should be updated in sequence, starting with Subcarrier
Frequency Register 0. The autoincrement function should be
then used to increment and access Subcarrier Frequency Registers
1, 2, and 3. The Subcarrier Frequency Registers should not be
accessed independently.
The ADV7192 support a two-wire serial (I2 C-compatible)
microprocessor bus driving multiple peripherals. Two inputs,
Serial Data (SDA) and Serial Clock (SCL), carry information
between any device connected to the bus. Each slave device is
recognized by a unique address. The ADV7192 has four possible
slave addresses for both read and write operations. These are
unique addresses for each device and are illustrated in Figure 35
and Figure 37. The LSB sets either a read or write operation.
Logic Level 1 corresponds to a read operation while Logic Level
0 corresponds to a write operation. A1 is set by setting the ALSB
pin of the ADV7192 to Logic Level 0 or Logic Level 1. When
ALSB is set to 0, there is greater input bandwidth on the I2C
lines, which allows high speed data transfers on this bus. When
ALSB is set to 1, there is reduced input bandwidth on the I2C
lines, which means that pulses of less than 50 ns will not pass
into the I2C internal controller. This mode is recommended for
noisy systems.
1
1
0
1
0
1
A1
Stop and start conditions can be detected at any stage during
the data transfer. If these conditions are asserted out of sequence
with normal read and write operations, then, these cause an
immediate jump to the idle condition. During a given SCL high
period the user should issue only one start condition, one stop
condition, or a single stop condition followed by a single start
condition. If an invalid subaddress is issued by the user, the
ADV7192 will not issue an acknowledge and will return to the
idle condition. If, in autoincrement mode, the user exceeds the
highest subaddress, then the following action will be taken:
X
ADDRESS
CONTROL
SETUP BY
ALSB
READ/WRITE
CONTROL
0
WRITE
1
READ
1. In Read Mode, the highest subaddress register contents
will continue to be output until the master device issues
a no-acknowledge. This indicates the end of a read. A
no-acknowledge condition is where the SDA line is not pulled
low on the ninth pulse.
Figure 35. Slave Address
To control the various devices on the bus the following protocol
must be followed. First, the master initiates a data transfer by
establishing a start condition, defined by a high-to-low transition
on SDA while SCL remains high. This indicates that an address/
data stream will follow. All peripherals respond to the start condition and shift the next eight bits (7-bit address + R/W bit). The
bits are transferred from MSB down to LSB. The peripheral that
recognizes the transmitted address responds by pulling the data
line low during the ninth clock pulse. This is known as an acknowledge bit. All other devices withdraw from the bus at this point
and maintain an idle condition. The idle condition is where
the device monitors the SDA and SCL lines waiting for the
start condition and the correct transmitted address. The R/W bit
determines the direction of the data.
2. In Write Mode, the data for the invalid byte will be not be
loaded into any subaddress register, a no-acknowledge will
be issued by the ADV7192 and the part will return to the
idle condition.
SDATA
SCLOCK
S
SLAVE ADDR A(S)
SUB ADDR
S
SLAVE ADDR A(S)
S = START BIT
P = STOP BIT
8
9
1 7
8
9
1 7
DATA
8
9
P
ACK
STOP
Figure 36 illustrates an example of data transfer for a read
sequence and the start and stop conditions.
Figure 37 shows bus write and read sequences.
DATA
A(S)
DATA
A(S) P
LSB = 1
LSB = 0
READ
SEQUENCE
A(S)
1 7
Figure 36. Bus Data Transfer
A Logic 0 on the LSB of the first byte means that the master
will write information to the peripheral. A Logic 1 on the LSB
of the first byte means that the master will read information
from the peripheral.
WRITE
SEQUENCE
S
START ADDR R/W ACK SUBADDRESS ACK
SUB ADDR
A(S) S SLAVE ADDR
A(S) = ACKNOWLEDGE BY SLAVE
A(M) = ACKNOWLEDGE BY MASTER
A(S)
DATA
A(M)
DATA
A(M) P
A(S) = NO ACKNOWLEDGE BY SLAVE
A(M) = NO ACKNOWLEDGE BY MASTER
Figure 37. Write and Read Sequences
–28–
REV. A
ADV7192
REGISTER ACCESSES
Subaddress Register (SR7–SR0)
The MPU can write to or read from all of the registers of the
ADV7192 with the exception of the Subaddress Registers which
are write only registers. The Subaddress Register determines
which register the next read or write operation accesses. All communications with the part through the bus start with an access
to the Subaddress Register. Then a read/write operation is performed from/to the target address which then increments to
the next address until a stop command on the bus is performed.
The Communications Register is an eight bit write-only register.
After the part has been accessed over the bus and a read/write
operation is selected, the subaddress is set up. The Subaddress Register determines to/from which register the operation takes place.
Figure 38 shows the various operations under the control of the
Subaddress Register 0 should always be written to SR7.
Register Select (SR6–SR0)
These bits are set up to point to the required starting address.
REGISTER PROGRAMMING
The following section describes each register. All registers can
be read from as well as written to.
SR7
SR7
ZERO SHOULD
BE WRITTEN
HERE
SR6
SR5
SR4
SR3
SR2
SR1
SR0
ADV7192 SUBADDRESS REGISTER
ADDRESS
00H
01H
02H
03H
04H
05H
06H
07H
08H
09H
0AH
0BH
0CH
0DH
0EH
0FH
10H
11H
12H
13H
14H
15H
16H
17H
18H
19H
1AH
1BH
1CH
1DH
1EH
1FH
20H
21H
22H
23H
24H
25H
26H
27H
28H
29H
2AH
2BH
2CH
2DH
2EH
2FH
30H
31H
32H
33H
34H
35H
36H
37H
38H
39H
3AH
3BH
3CH
3DH
3EH
3FH
40H
41H
42H
43H
44H
45H
46H
47H
48H
49H
4AH
4BH
SR6 SR5 SR4
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
0
1
1
1
1
1
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
1
0
0
SR3
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
1
1
1
1
1
SR2
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
SR1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
1
0
0
1
SR0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
MODE REGISTER 0
MODE REGISTER 1
MODE REGISTER 2
MODE REGISTER 3
MODE REGISTER 4
MODE REGISTER 5
MODE REGISTER 6
MODE REGISTER 7
MODE REGISTER 8
MODE REGISTER 9
TIMING REGISTER 0
TIMING REGISTER 1
SUBCARRIER FREQUENCY REGISTER 0
SUBCARRIER FREQUENCY REGISTER 1
SUBCARRIER FREQUENCY REGISTER 2
SUBCARRIER FREQUENCY REGISTER 3
SUBCARRIER PHASE REGISTER
CLOSED CAPTIONING EXTENDED DATA BYTE 0
CLOSED CAPTIONING EXTENDED DATA BYTE 1
CLOSED CAPTIONING DATA BYTE 0
CLOSED CAPTIONING DATA BYTE 1
NTSC PEDESTAL/TELETEXT CONTROL REGISTER 0
NTSC PEDESTAL/TELETEXT CONTROL REGISTER 1
NTSC PEDESTAL/TELETEXT CONTROL REGISTER 2
NTSC PEDESTAL/TELETEXT CONTROL REGISTER 3
CGMS/WSS 0
CGMS/WSS 1
CGMS/WSS 2
TELETEXT REQUEST CONTROL REGISTER
CONTRAST CONTROL REGISTER
U SCALE REGISTER
V SCALE REGISTER
HUE ADJUST CONTROL REGISTER
BRIGHTNESS CONTROL REGISTER
SHARPNESS RESPONSE REGISTER
DNR REGISTER 0
DNR REGISTER 1
DNR REGISTER 2
GAMMA CORRECTION REGISTER 0
GAMMA CORRECTION REGISTER 1
GAMMA CORRECTION REGISTER 2
GAMMA CORRECTION REGISTER 3
GAMMA CORRECTION REGISTER 4
GAMMA CORRECTION REGISTER 5
GAMMA CORRECTION REGISTER 6
GAMMA CORRECTION REGISTER 7
GAMMA CORRECTION REGISTER 8
GAMMA CORRECTION REGISTER 9
GAMMA CORRECTION REGISTER 10
GAMMA CORRECTION REGISTER 11
GAMMA CORRECTION REGISTER 12
GAMMA CORRECTION REGISTER 13
BRIGHTNESS DETECT REGISTER
OUTPUT CLOCK REGISTER
RESERVED
RESERVED
RESERVED
RESERVED
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
MACROVISION REGISTER
Figure 38. Subaddress Register for the ADV7192
REV. A
–29–
ADV7192
MODE REGISTER 0
MR0 (MR07–MR00)
(Address (SR4–SR0) = 00H)
MODE REGISTER 1
MR1 (MR17–MR10)
(Address (SR4–SR0) = 01H)
Figure 39 shows the various operations under the control of
Mode Register 0.
Figure 40 shows the various operations under the control of
Mode Register 1.
MR0 BIT DESCRIPTION
Output Video Standard Selection Control (MR00–MR01)
MR1 BIT DESCRIPTION
DAC Control (MR10–MR15)
These bits are used to set up the encoder mode. The ADV7192
can be set up to output NTSC, PAL (B, D, G, H, I), PAL M or
PAL N standard video.
Bits MR15–MR10 can be used to power-down the DACs. This are
used to reduce the power consumption of the ADV7192 or if any
of the DACs are not required in the application.
Luminance Filter Select (MR02–MR04)
4 Oversampling Control (MR16)
These bits specify which luma filter is to be selected. The filter
selection is made independent of whether PAL or NTSC is
selected.
To enable 4× Oversampling this bit has to be set to 1. When
enabled, the data is output at a frequency of 54 MHz.
Note that PLL Enable Control has to be enabled (MR61 = 0) in
4× Oversampling mode. An external VREF is not recommended
in that mode.
Chrominance Filter Select (MR05–MR07)
These bits select the chrominance filter. A low-pass filter can be
selected with a choice of cutoff frequencies (0.65 MHz, 1.0 MHz,
1.3 MHz, 2 MHz, or 3 MHz) along with a choice of CIF or
QCIF filters.
MR07
MR06
MR05
Reserved (MR17)
A Logical 0 must be written to this bit.
MR04
MR03
MR02
MR01
OUTPUT VIDEO
STANDARD SELECTION
CHROMA FILTER SELECT
MR07 MR06 MR05
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
MR00
MR01 MR00
1.3 MHz LOW-PASS FILTER
0.65 MHz LOW-PASS FILTER
1.0 MHz LOW-PASS FILTER
2.0 MHz LOW-PASS FILTER
RESERVED
CIF
QCIF
3.0 MHz LOW-PASS FILTER
0
0
1
1
0
1
0
1
NTSC
PAL (B, D, G, H, I)
PAL (M)
PAL (N)
LUMA FILTER SELECT
MR04 MR03 MR02
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
LOW-PASS FILTER (NTSC)
LOW-PASS FILTER (PAL)
NOTCH FILTER (NTSC)
NOTCH FILTER (PAL)
EXTENDED MODE
CIF
QCIF
RESERVED
Figure 39. Mode Register 0, MR0
MR17
MR17
ZERO MUST
BE WRITTEN
TO THIS BIT
MR16
MR15
MR13
DAC A
DAC CONTROL
0
1
MR12
0
1
MR11
POWER-DOWN
NORMAL
DAC B
DAC CONTROL
MR14
0
1
MR10
DAC E
DAC CONTROL
MR13
POWER-DOWN
NORMAL
2 OVERSAMPLING
4 OVERSAMPLING
MR11
DAC C
DAC CONTROL
MR15
4 OVERSAMPLING
CONTROL
MR16
0
1
MR14
0
1
POWER-DOWN
NORMAL
DAC D
DAC CONTROL
MR12
POWER-DOWN
NORMAL
0
1
DAC F
DAC CONTROL
MR10
POWER-DOWN
NORMAL
0
1
POWER-DOWN
NORMAL
Figure 40. Mode Register 1, MR1
–30–
REV. A
ADV7192
Standard I2C Control (MR25)
MODE REGISTER 2
MR2 (MR27–MR20)
(Address (SR4–SR0) = 02H)
This bit controls the video standard used by the ADV7192.
When this bit is set to 1 the video standard is as programmed in
Mode Register 0 (Output Video Standard Selection). When it is
set to 0, the ADV7192 is forced into the standard selected by
the NTSC_PAL pin. When NTSC_PAL is low, the standard is
NTSC, when the NTSC_PAL pin is high, the standard is PAL.
Mode Register 2 is an 8-bit-wide register.
Figure 41 shows the various operations under the control of Mode
Register 2.
MR2 BIT DESCRIPTION—RGB/YUV Control (MR20)
Pixel Data Valid Control (MR26)
This bit enables the output from the DACs to be set to YUV or
RGB output video standard.
After resetting the device this bit has the value 0 and the pixel
data input to the encoder is blanked such that a black screen is
output from the DACs. The ADV7192 will be set to Master Mode
timing. When this bit is set to 1 by the user (via the I2C), pixel
data passes to the pins and the encoder reverts to the timing mode
defined by Timing Register 0.
DAC Output Control (MR21)
This bit controls the output from DACs A, B, and C. When this
bit is set to 1, Composite, Luma and Chroma Signals are output
from DACs A, B, and C (respectively). When this bit is set to 0,
RGB or YUV may be output from these DACs.
Sleep Mode Control (MR27)
SCART Enable Control (MR22)
When this bit is set (1), Sleep Mode is enabled. With this mode
enabled, the ADV7192 current consumption is reduced to typically 0.1 µA. The I2C registers can be written to and read from
when the ADV7192 is in Sleep Mode.
This bit is used to switch the DAC outputs from SCART to a
EUROSCART configuration. A complete table of all DAC output configurations is shown below.
Pedestal Control (MR23)
When the device is in Sleep Mode and 0 is written to MR27, the
ADV7192 will come out of Sleep Mode and resume normal
operation. Also, if a RESET is applied during Sleep Mode the
ADV7192 will come out of Sleep Mode and resume normal
operation.
This bit specifies whether a pedestal is to be generated on the
NTSC composite video signal. This bit is invalid when the device
is configured in PAL mode.
Square Pixel Control (MR24)
This bit is used to set up square pixel mode. This is available in
Slave Mode only. For NTSC, a 24.54 MHz clock must be supplied. For PAL, a 29.5 MHz clock must be supplied. Square
pixel operation is not available in 4× Oversampling mode.
MR27
MR26
MR25
PIXEL DATA
VALID CONTROL
MR26
0
DISABLE
1
ENABLE
MR27
0
DISABLE
1
ENABLE
MR24
MR23
SQUARE PIXEL
CONTROL
MR25
0
DISABLE
1
ENABLE
MR22
MR21
SCART ENABLE
CONTROL
MR24
0
DISABLE
1
ENABLE
STANDARD I2C
CONTROL
SLEEP MODE
CONTROL
For this to operate Power up in Sleep Mode control has to be
enabled (MR60 is set to a Logic 0), otherwise Sleep Mode is
controlled by the PAL_NTSC and SCRESET/RTC/TR pins.
MR22
0
DISABLE
1
ENABLE
MR20
RGB/YUV
CONTROL
MR20
0
RGB OUTPUT
1
YUV OUTPUT
PEDESTAL
CONTROL
DAC OUTPUT
CONTROL
MR23
0
PEDESTAL OFF
1
PEDESTAL ON
MR21
0
RGB/YUV/COMP
1
COMP/LUMA/CHROMA
Figure 41. Mode Register 2, MR2
Table III. DAC Output Configuration
MR22
MR21
MR20
DAC A
DAC B
DAC C
DAC D
DAC E
DAC F
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
G (Y)
Y (Y)
CVBS
CVBS
CVBS
CVBS
CVBS
CVBS
B (Pb)
U (Pb)
LUMA
LUMA
B (Pb)
U (Pb)
LUMA
LUMA
R (Pr)
V (Pr)
CHROMA
CHROMA
R (Pr)
V (Pr)
CHROMA
CHROMA
CVBS
CVBS
G (Y)
Y (Y)
G (Y)
Y (Y)
G (Y)
Y (Y)
LUMA
LUMA
B (Pb)
U (Pb)
LUMA
LUMA
B (Pb)
U (Pb)
CHROMA
CHROMA
R (Pr)
V (Pr)
CHROMA
CHROMA
R (Pr)
V (Pr)
NOTE
In Progressive Scan Mode (MR80 = 1) the DAC output configuration is stated in the brackets.
REV. A
–31–
ADV7192
MODE REGISTER 3
MR3 (MR37–MR30)
(Address (SR4–SR0) = 03H)
Genlock Control (MR41–MR42)
These bits control the Genlock feature and timing reset of the
ADV7192. Setting MR41 and MR42 to Logic 0 disables the
SCRESET/RTC/TR pin and allows the ADV7192 to operate
in normal mode.
Mode Register 3 is an 8-bit-wide register. Figure 42 shows the
various operations under the control of Mode Register 3.
1. By setting MR41 to zero and MR42 to one, a timing reset is
applied, resetting the horizontal and vertical counters. This
has the effect of resetting the Field Count to Field 0.
MR3 BIT DESCRIPTION
Revision Code (MR30–MR31)
This bit is read only and indicates the revision of the device.
If the SCRESET/RTC/TR pin is held high, the counters
will remain reset. Once the pin is released the counters will
commence counting again. For correct counter reset, the
SCRESET/RTC/TR pin has to remain high for at least
37 ns (one clock cycle at 27 MHz).
VBI Open (MR32)
This bit determines whether or not data in the Vertical Blanking
Interval (VBI) is output to the analog outputs or blanked. Note
that this condition is also valid in Timing Slave Mode 0. For
further information see Vertical Blanking Data Insertion and
BLANK Input section.
2. If MR41 is set to one and MR42 is set to zero, the SCRESET/
RTC/TR pin is configured as a subcarrier reset input and
the subcarrier phase will reset to Field 0 whenever a low-tohigh transition is detected on the SCRESET/RTC/TR pin
(SCH phase resets at the start of the next field).
Teletext Enable (MR33)
This bit must be set to 1 to enable teletext data insertion on the
TTX pin. Note: TTX functionality is shared with VSO and
CLAMP on Pin 62. CLAMP/VSO Select (MR77) and TTX
Input/CLAMP–VSO Output (MR76) have to be set accordingly.
3. If MR41 is set to one and MR42 is set to one, the SCRESET/
RTC/TR pin is configured as a real time control input and
the ADV7192 can be used to lock to an external video source
working in RTC mode. See Real-Time Control, Subcarrier
Reset and Timing Reset section.
Teletext Bit Request Mode Control (MR34)
This bit enables switching of the teletext request signal from a
continuous high signal (MR34 = 0) to a bitwise request signal
(MR34 = 1).
Active Video Line Duration (MR43)
Closed Captioning Field Selection (MR35–MR36)
This bit switches between two active video line durations. A zero
selects CCIR Rec. 601 (720 pixels PAL/NTSC) and a one
selects ITU-R BT. 470 standard for active video duration (710
pixels NTSC, 702 pixels PAL).
These bits control the fields that closed captioning data is displayed on, closed captioning information can be displayed on
an odd field, even field or both fields.
Reserved (MR37)
Chrominance Control (MR44)
A Logic 0 must be written to this bit.
This bit enables the color information to be switched on and off
the chroma, composite and color component outputs.
MODE REGISTER 4
MR4 (MR47–MR40)
(Address (SR4–SR0) = 04H)
Burst Control (MR45)
This bit enables the color burst to be switched on and off the
chroma and composite outputs.
Mode Register 4 is an 8-bit-wide register. Figure 43 shows the
various operations under the control of Mode Register 4.
Color Bar Control (MR46)
This bit can be used to generate and output an internal color
bar test pattern. The color bar configuration is 100/7.5/75/7.5
for NTSC and 100/0/75/0 for PAL. It is important to note that
when color bars are enabled the ADV7192 is configured in a
Master Timing mode. The output pins VSYNC, HSYNC and
BLANK are three-state during color bar mode.
MR4 BIT DESCRIPTION
VSYNC_3H Control (MR40)
When this bit is enabled (1) in Slave Mode, it is possible to
drive the VSYNC input low for 2.5 lines in PAL mode and
three lines in NTSC mode. When this bit is enabled in Master
Mode the ADV7192 outputs an active low VSYNC signal for three
lines in NTSC mode and 2.5 lines in PAL mode.
MR37
MR36
MR35
Interlaced Mode Control (MR47)
This bit is used to setup the output to interlaced or noninterlaced mode.
MR34
MR33
MR32
TTX BIT REQUEST
MODE CONTROL
MR37
MR34
0
DISABLE
1
ENABLE
ZERO MUST BE
WRITTEN TO
THIS BIT
CLOSED CAPTIONING
FIELD SELECTION
MR36 MR35
0
0
0
1
1
0
1
1
NO DATA OUT
ODD FIELD ONLY
EVEN FIELD ONLY
DATA OUT
(BOTH FIELDS)
VBI OPEN
MR32
0
DISABLE
1
ENABLE
MR31
MR30
MR31 MR30
RESERVED FOR
REVISION CODE
TELETEXT
ENABLE
MR33
0
DISABLE
1
ENABLE
Figure 42. Mode Register 3, MR3
–32–
REV. A
ADV7192
MR47
MR46
MR45
COLOR BAR
CONTROL
MR46
0
DISABLE
1
ENABLE
INTERLACE MODE
CONTROL
MR47
0
INTERLACED
1
NONINTERLACED
MR44
MR43
CHROMINANCE
CONTROL
MR44
0
ENABLE COLOR
1
DISABLE COLOR
MR42
MR41
MR40
GENLOCK CONTROL
MR42 MR41
0
0
0
1
1
1
0
1
DISABLE GENLOCK
ENABLE SUBCARRIER
RESET PIN
TIMING RESET
ENABLE RTC PIN
BURST
CONTROL
ACTIVE VIDEO
LINE DURATION
MR45
0
ENABLE BURST
1
DISABLE BURST
MR43
0
720 PIXELS
1
710 PIXELS/702 PIXELS
VSYNC 3H
CONTROL
MR40
0
DISABLE
1
ENABLE
Figure 43. Mode Register 4, MR4
MODE REGISTER 5
MR5 (MR57–MR50)
(Address (SR4–SR0) = 05H)
RGB Sync (MR53)
This bit is used to set up the RGB outputs with the sync information encoded on all RGB outputs.
Mode Register 5 is a 8-bit-wide register. Figure 44 shows the
various operations under the control of Mode Register 5.
Clamp Delay (MR54–MR55)
These bits control the delay or advance of the CLAMP signal in
the front or back porch of the ADV7192. It is possible to delay or
advance the pulse by zero, one, two or three clock cycles.
MR5 BIT DESCRIPTION
Y-Level Control (MR50)
Note: TTX functionality is shared with VSO and CLAMP on Pin
62. CLAMP/VSO Select (MR77) and TTX Input/CLAMP–VSO
Output (MR76) have to be set accordingly.
This bit controls the component Y output level on the ADV7192
If this bit is set (0), the encoder outputs Betacam levels when
configured in PAL or NTSC mode. If this bit is set (1), the
encoder outputs SMPTE levels when configured in PAL or
NTSC mode.
Clamp Delay Direction (MR56)
This bit controls a positive or negative delay in the CLAMP signal. If this bit is set (1), the delay is negative. If it is set (0), the
delay is positive.
UV-Levels Control (MR51–MR52)
These bits control the component U and V output levels on the
ADV7192. It is possible to have UV levels with a peak-to-peak
amplitude of either 700 mV (MR52 + MR51 = 01) or 1000 mV
(MR52 + MR51 = 10) in NTSC and PAL. It is also possible to
have default values of 934 mV for NTSC and 700 mV for PAL
(MR52 + MR51 = 00).
MR57
MR56
MR55
Clamp Position (MR57)
This bit controls the position of the CLAMP signal. If this bit is
set (1), the CLAMP signal is located in the back porch position.
If this bit is set (0), the CLAMP signal is located in the front
porch position.
MR54
MR53
CLAMP DELAY
DIRECTION
MR57
0
FRONT PORCH
1
BACK PORCH
0
1
0
1
0
1
MR50
0
DISABLE
1
ENABLE
DISABLE
ENABLE
CLAMP DELAY
UV LEVEL CONTROL
MR52 MR51
NO DELAY
1 PCLK
2 PCLK
3 PCLK
0
0
1
1
0
1
0
1
DEFAULT LEVELS
700mV
1000mV
RESERVED
Figure 44. Mode Register 5, MR5
REV. A
MR50
Y LEVEL
CONTROL
MR53
MR55 MR54
0
0
1
1
MR51
RGB SYNC
MR56
0
POSITIVE
1
NEGATIVE
CLAMP
POSITION
MR52
–33–
ADV7192
MR67
MR66
MR65
MR64
MR63
MR67 MR66 MR65
MR64 MR63 MR62
FIELD COUNTER
ZERO MUST
BE WRITTEN
TO THESE BITS
MR62
MR61
MR60
PLL ENABLE
CONTROL
MR61
0
1
POWER-UP SLEEP
MODE CONTROL
MR60
0
ENABLED
1
DISABLED
ENABLED
DISABLED
Figure 45. Mode Register 6, MR6
Mode Register 6
MR6 (MR67–MR60)
(Address (SR4–SR0) = 06H)
Luma Saturation Control (MR71)
When this bit is set (1), the luma signal will be clipped if it reaches
a limit that corresponds to an input luma value of 255 (after
scaling by the Contrast Control Register). This prevents the
chrominance component of the composite video signal being
clipped if the amplitude of the luma is too high. When this bit is
set (0), this control is disabled.
Mode Register 6 is a 8-bit-wide register. Figure 45 shows the
various operations under the control of Mode Register 6.
MR6 BIT DESCRIPTION
Power-Up Sleep Mode Control (MR60)
After RESET is applied this control is enabled (MR60 = 0) if
both SCRESET/RTC/TR and NTSC_PAL pins are tied high.
The ADV7192 will then power up in Sleep Mode to facilitate
low power consumption before the I2C is initialized. When this
control is disabled (MR60 = 1, via the I2C) Sleep Mode control
passes to Sleep Mode Control, MR27.
Hue Adjust Control (MR72)
PPL Enable Control (MR61)
Reserved (MR62, MR63, MR64)
This bit is used to enable brightness control on the ADV7192.
The actual brightness level is programmed in the Brightness
Control Register. This value or set-up level is added to the scaled
Y data. When this bit is set (1), brightness control is enabled.
When this bit is set (0), brightness control is disabled.
A Logical 0 must be written to these bits.
Sharpness Filter Enable (MR74)
Field Counter (MR65, MR66, MR67)
This bit is used to enable the sharpness control of the luminance
signal on the ADV7192 (Luma Filter Select has to be set to
Extended, MR04–MR02 = 100). The various responses of the
filter are determined by the Sharpness Control Register. When this
bit is set (1), the luma response is altered by the amount described
in the Sharpness Control Register. When this bit is set (0), the
sharpness control is disabled. See Internal Filter Response section
for luma signal responses.
This bit is used to enable hue adjustment on the composite and
chroma output signals of the ADV7192. When this bit is set (1),
the hue of the color is adjusted by the phase offset described in
the Hue Adjust Control Register. When this bit is set (0), hue
adjustment is disabled.
Brightness Enable Control (MR73)
The PLL control should be enabled (MR61 = 0 ) when 4×
Oversampling is enabled (MR16 = 1). When this bit is toggled,
it is also used to reset the PLL.
These three bits are read only bits. The field count can be read
back over the I2C interface. In NTSC mode the field count goes
from 0–3, in PAL Mode from 0–7.
MODE REGISTER 7
MR7 (MR77–MR70)
(Address (SR4–SR0) = 07H)
Mode Register 7 is a 8-bit-wide register. Figure 46 shows the
various operations under the control of Mode Register 7.
CSO_HSO Output Control (MR75)
This bit is used to determine whether HSO or CSO TTL output
signal is output at the CSO_HSO pin. If this bit is set (1), the
CSO TTL signal is output. If this bit is set (0), the HSO TTL
signal is output.
MR7 BIT DESCRIPTION
Color Control Enable (MR70)
This bit is used to enable control of contrast and saturation of
color. If this bit is set (1) color controls are enabled (Contrast
Control Register, U-Scale Register, V-Scale Register). If this bit
is set (0), the color control features are disabled.
MR77
MR76
MR75
TTX INPUT/CLAMP–VSO
OUTPUT CONTROL
MR76
0
1
TTX INPUT
CLAMP/VSO
OUTPUT
CLAMP/ VSO
SELECT
MR77
0
1
VSO OUTPUT
CLAMP OUTPUT
This bit controls whether Pin 62 is configured as an output or as
an input pin. A 1 selects Pin 62 to be an output for CLAMP or
VSO functionality. A 0 selects this pin as a TTX input pin.
MR74
MR73
SHARPNESS FILTER
ENABLE
MR74
0
1
CSO_HSO
OUTPUT CONTROL
MR75
0
1
TTX Input/CLAMP–VSO Output (MR76)
HSO OUT
CSO OUT
DISABLE
ENABLE
MR72
HUE ADJUST
CONTROL
MR72
0
1
BRIGHTNESS
ENABLE CONTROL
MR73
0
1
MR71
DISABLE
ENABLE
MR70
COLOR CONTROL
ENABLE
MR70
0
DISABLE
1
ENABLE
LUMA SATURATION
CONTROL
MR71
DISABLE
ENABLE
0
1
DISABLE
ENABLE
Figure 46. Mode Register 7, MR7
–34–
REV. A
ADV7192
MR87
MR86
MR85
GAMMA ENABLE
CONTROL
MR86
0
DISABLE
1
ENABLE
GAMMA CURVE
SELECT CONTROL
MR87
0
CURVE A
1
CURVE B
MR84
MR83
MR84
MR81
16-PIXEL
PORT CONTROL
MR83
0
DISABLE
1
ENABLE
MR80
PROGRESSIVE
SCAN CONTROL
MR80
0
DISABLE
1
ENABLE
DOUBLE BUFFER
CONTROL
MR82
0
DISABLE
1
ENABLE
ZERO SHOULD
BE WRITTEN
TO THIS BIT
DNR ENABLE
CONTROL
MR85
0
DISABLE
1
ENABLE
MR82
MR81
ZERO SHOULD
BE WRITTEN
TO THIS BIT
Figure 47. Mode Register 8, MR8
CLAMP/VSO Select (MR77)
Gamma Curve Select Control (MR87)
This bit is used to select the functionality of Pin 62. Setting this
bit to 1 selects CLAMP as the output signal. A 0 selects VSO
as the output signal. Since this pin is also shared with the TTX
functionality, TTX Input/CLAMP–VSO Output has to be set
accordingly (MR76).
This bit selects which of the two programmable gamma curves is
to be used. When setting MR87 to 0, the gamma correction curve
selected is Curve A. Otherwise, Curve B is selected. Each curve
will have to be programmed by the user. For further information
on Gamma Correction controls see Gamma Correction Registers section.
MODE REGISTER 8
MR8 (MR87–MR80)
(Address (SR4–SR0) = 08H)
Mode Register 8 is an 8-bit-wide register. Figure 47 shows the
various operations under the control of Mode Register 8.
MR8 BIT DESCRIPTION
Progressive Scan Control (MR80)
This control enables the progressive scan inputs on pins
Y(0)/P8–Y(7)/P15, Y(8)–Y(9), Cr(0)–Cr(9), Cb(0)–Cb(9). To
enable this control MR80 has to be set to 1. It is assumed that
the incoming Y data contains all necessary sync information.
MODE REGISTER 9
MR9 (MR97–MR90)
(Address (SR4–SR0) = 09H)
Mode Register 9 is an 8-bit-wide register. Figure 49 shows the
various operations under the control of Mode Register 9.
MR9 BIT DESCRIPTION
Undershoot Limiter (MR90–MR91)
A 0 must be written to this bit.
This control ensures that no luma video data will go below a
programmable level. This prevents any synchronization problems
due to luma signals going below the blanking level. Available
limit levels are –1.5 IRE, –6 IRE, –11 IRE. Note that this facility is
only available in 4× Oversampling mode (MR16 = 1). When the
device is operated in 2× Oversampling mode (MR16 = 0) or RGB
output without RGB sync are selected, the minimum luma level is
set in Timing Register 0, TR06 (Min Luma Control).
Double Buffer Control (MR82)
Black Burst Y DAC (MR92)
Double Buffering can be enabled or disabled on the Contrast
Control Register, U Scale Register, V Scale Register, Hue Adjust
Control Register, Closed Captioning Register, Brightness Control
Register, Gamma Curve Select Bit and the Macrovision Registers. Double Buffer is not available in Master Mode.
It is possible to output a Black Burst signal from the DAC
which is selected to be the Luma DAC (MR22, MR21, MR20).
This signal can be useful for locking two video sources together
using professional video equipment. See also Black Burst Output section.
16-Bit Pixel Port (MR83)
Black Burst Luma (MR93)
This bit controls if the ADV7192 is operated in 8-bit or 16-bit
mode. In 8-bit mode the input data will be set up on Pins P0–P7.
In 16-bit mode the first eight bits are set up on Pin 3–10, with
LSB on Pin 3. The second eight bits are set up on Pin 13–20.
It is possible to output a Black Burst signal from the DAC which
is selected to be the Y-DAC (MR22, MR21, MR20). This signal
can be useful for locking two video sources together using professional video equipment. See also Black Burst Output section.
Note: Simultaneous progressive scan input and 16-bit pixel input
is not possible.
Reserved (MR81)
Reserved (MR84)
3.58MHz
COLOR BURST
(9 CYCLES)
A Logic 0 must be written to this bit.
DNR Enable Control (MR85)
To enable the DNR process this bit has to be set to 1. If this bit
is set to other DNR processing is bypassed. For further information on DNR controls see DNR Mode Control section.
–20 IRE
–40 IRE
4.43MHz
COLOR BURST
(10 CYCLES)
Gamma Enable Control (MR86)
To enable the programmable gamma correction this bit has to be
set to enabled (MR86 = 1). For further information on Gamma
Correction controls see Gamma Correction Registers section.
NTSC BLACK BURST SIGNAL
20 IRE
0 IRE
PAL BLACK BURST SIGNAL
21.5 IRE
0 IRE
–21.5 IRE
–43 IRE
Figure 48. Black Burst Signals for PAL and NTSC Standards
REV. A
–35–
ADV7192
MR97
MR96
MR97 MR96
ZERO MUST
BE WRITTEN
TO THESE BITS
MR95
MR94
CHROMA
DELAY CONTROL
MR95 MR94
0
0
1
1
0
1
0
1
0ns DELAY
148ns DELAY
296ns DELAY
RESERVED
MR93
BLACK BURST
LUMA DAC
MR93
0
DISABLE
1
ENABLE
MR92
MR91
BLACK BURST
Y DAC
MR92
0
DISABLE
1
ENABLE
MR90
UNDERSHOOT
LIMITER
MR91 MR90
0
0
1
1
0
1
0
1
DISABLED
–11 IRE
–6 IRE
–1.5 IRE
Figure 49. Mode Register 9 (MR9)
Chroma Delay Control (MR94–MR95)
Timing Register Reset (TR07)
The Chroma signal can be delayed by up to 8 clock cycles at
27 MHz using MR94–95. For further information see also
Chroma/Luma Delay Section.
Toggling TR07 from low to high and low again resets the internal timing counters. This bit should be toggled after power-up,
reset or changing to a new timing mode.
TIMING REGISTER 0 (TR07–TR00)
(Address (SR4–SR0) = 0AH)
TIMING REGISTER 1 (TR17–TR10)
(Address (SR4–SR0) = 0BH)
Figure 50 shows the various operations under the control of
Timing Register 0. This register can be read from as well as
written to.
Timing Register 1 is a 8-bit-wide register.
Figure 51 shows the various operations under the control of
Timing Register 1. This register can be read from as well written
to. This register can be used to adjust the width and position of
the master mode timing signals.
TR0 BIT DESCRIPTION
Master/Slave Control (TR00)
This bit controls whether the ADV7192 is in master or slave mode.
Timing Mode Selection (TR01–TR02)
These bits adjust the HSYNC pulsewidth.
These bits control the timing mode of the ADV7192. These
modes are described in more detail in the Video Timing Description section of the data sheet.
TPCLK = one clock cycle at 27 MHz.
HSYNC to VSYNC Delay (TR13–TR12)
BLANK Input Control (TR03)
This bit controls whether the BLANK input is used to accept
blank signals or whether blank signals are internally generated.
Note: When this input pin is tied high (to 5 V), the input is disabled regardless of the register setting. It, therefore, should be
tied low (to Ground) to allow control over the I2C register.
Luma Delay (TR04–TR05)
The luma signal can be delayed by up to 222 ns (or six clock
cycles at 27 MHz) using TR04–TR05. For further information
see Chroma/Luma Delay section.
TR05
TPCLK = one clock cycle at 27 MHz.
HSYNC to Pixel Data Adjust (TR16–TR17)
This enables the HSYNC to be adjusted with respect to the
pixel data. This allows the Cr and Cb components to be swapped.
TR03
LUMA DELAY
MIN LUMINANCE VALUE
TR05 TR04
LUMA MIN =
SYNC BOTTOM
LUMA MIN =
BLANK –7.5 IRE
TR02
TR01
BLANK INPUT
CONTROL
TR03
0
ENABLE
1
DISABLE
TR07
1
When the ADV7192 is in Timing Mode 1, these bits adjust the
position of the HSYNC output relative to the VSYNC output
rising edge.
When the ADV7192 is configured in Timing Mode 2, these bits
adjust the VSYNC pulsewidth.
TR04
TIMING
REGISTER RESET
TR06
0
TPCLK = one clock cycle at 27 MHz.
HSYNC to VSYNC Rising Edge Delay (TR14–TR15)
VSYNC Width (TR14–TR15)
This bit is used to control the minimum luma output value
by the ADV7192 in 2× Oversampling mode and 4× Oversampling
mode. When this bit is set to a Logic 1, the luma is limited to
7IRE below the blank level. When this bit is set to (0), the luma
value can be as low as the sync bottom level.
TR06
These bits adjust the position of the HSYNC output relative to
the VSYNC output.
TPCLK = one clock cycle at 27 MHz.
Min Luminance Value (TR06)
TR07
TR1 BIT DESCRIPTION
HSYNC Width (TR10–TR11)
0
0
1
1
0
1
0
1
0ns DELAY
74ns DELAY
148ns DELAY
222ns DELAY
TR00
MASTER / SLAVE
CONTROL
TR00
0
SLAVE TIMING
1
MASTER TIMING
TIMING MODE
SELECTION
TR02 TR01
0
0
0
1
1
0
1
1
MODE 0
MODE 1
MODE 2
MODE 3
Figure 50. Timing Register 0
–36–
REV. A
ADV7192
TR17
TR16
TR15
HSYNC TO PIXEL
DATA ADJUST
TR15 TR14
0 TPCLK
1 T PCLK
2 TPCLK
3 TPCLK
0
1
0
1
TR13
TR13 TR12
TC
0
1
TR12
TR11
HSYNC TO
VSYNC DELAY
HSYNC TO VSYNC
RISING EDGE DELAY
(MODE 1 ONLY)
TR17 TR16
0
0
1
1
TR14
0
0
1
1
TB
TB + 32s
0
1
0
1
TR10
HSYNC WIDTH
TB
TR11 TR10
0 TPCLK
4 T PCLK
8 TPCLK
18 TPCLK
0
0
1
1
TA
1 TPCLK
4 T PCLK
16 TPCLK
128 TPCLK
0
1
0
1
VSYNC WIDTH
(MODE 2 ONLY)
TR15 TR14
0
0
1
1
0
1
0
1
1 TPCLK
4 T PCLK
16 TPCLK
128 TPCLK
TIMING MODE 1 (MASTER/PAL)
LINE 1
HSYNC
LINE 313
LINE 314
TA
TC
TB
VSYNC
Figure 51. Timing Register 1
This adjustment is available in both master and slave timing
modes.
SUBCARRIER
PHASE
REGISTER
TPCLK = one clock cycle at 27 MHz.
These 8-bit-wide registers are used to set up the Subcarrier Frequency. The value of these registers are calculated by using the
following equation:
(2
32
Subcarrier Frequency Register =
32
)
FPH3
FPH2
FPH1
FPH0
These 8-bit-wide registers are used to set up the closed captioning
extended data bytes on Even Fields. Figure 54 shows how the
high and low bytes are set up in the registers.
fCLK
BYTE 1
)
BYTE 0
– 1 × 3.5795454 × 106
27 × 10
6
Figure 52 shows how the frequency is set up by the four registers.
FSC31
FSC30
FSC29
FSC28
FSC27
FSC26
FSC25
FSC24
FSC23
FSC22
FSC21
FSC20
FSC19
FSC18
FSC17
FSC16
FSC15
FSC14
FSC13
FSC12
FSC11
FSC10
FSC9
FSC8
FSC7
FSC6
FSC5
FSC4
FSC3
FSC2
FSC1
FSC0
This 8-bit-wide register is used to set up the Subcarrier Phase.
Each bit represents 1.41°. For normal operation this register is
set to 00Hex.
CCD6
CCD13 CCD12 CCD11 CCD10
CCD5
CCD4
CCD3
CCD2
CCD9
CCD1
CCD8
CCD0
Figure 54. Closed Captioning Extended Data Register
CLOSED CAPTIONING ODD FIELD
DATA REGISTER 1–0 (CED15-CED0)
(Subaddress (SR4–SR0) = 13–14H)
These 8-bit-wide registers are used to set up the closed captioning
data bytes on Odd Fields. Figure 55 shows how the high and low
bytes are set up in the registers.
BYTE 0
SUBCARRIER PHASE REGISTER (FPH7–FPH0)
(Address (SR4–SR0) = 10H)
CCD15 CCD14
CCD7
BYTE 1
Figure 52. Subcarrier Frequency Registers
REV. A
FPH4
– 1 × f SCF
Subcarrier Register Value = 21F07C16 Hex
SUBCARRIER
FREQUENCY
REG 3
SUBCARRIER
FREQUENCY
REG 2
SUBCARRIER
FREQUENCY
REG 1
SUBCARRIER
FREQUENCY
REG 0
FPH5
CLOSED CAPTIONING EVEN FIELD
DATA REGISTER 1–0 (CCD15–CCD0)
(Address (SR4–SR0) = 11–12H)
Example: NTSC Mode, fCLK = 27 MHz, fSCF = 3.5795454 MHz
(2
FPH6
Figure 53. Subcarrier Phase Register
SUBCARRIER FREQUENCY REGISTERS 3–0
(FSC31–FSC0) (Address (SR4–SR0) = 0CH–0FH)
Subcarrier Frequency Value =
FPH7
CED15
CED7
CED14
CED6
CED13
CED5
CED12
CED4
CED11
CED3
CED10
CED2
CED9
CED1
CED8
CED0
Figure 55. Closed Captioning Data Register
NTSC PEDESTAL/PAL TELETEXT CONTROL
REGISTERS 3–0
(PCE15–0, PCO15–0)/(TXE15–0, TXO15–0)
(Subaddress (SR4–SR0) = 15–18H)
These 8-bit-wide registers are used to enable the NTSC pedestal/
PAL Teletext on a line-by-line basis in the vertical blanking
interval for both odd and even fields. Figures 56 and 57 show
the four control registers. A Logic 1 in any of the bits of these
–37–
ADV7192
registers has the effect of turning the Pedestal OFF on the equivalent line when used in NTSC. A Logic 1 in any of the bits of
these registers has the effect of turning Teletext ON on the
equivalent line when used in PAL.
LINE 17 LINE 16
FIELD 1/3
FIELD 1/3
FIELD 2/4
FIELD 2/4
PCO7
PCO6
PCO5
PCO4
PCO3
PCO2
PCO1
LINE 22 LINE 21 LINE 20
PCO15 PCO14 PCO13
PCO12 PCO11 PCO10
PCO0
PCO9
PCO8
LINE 15 LINE 14 LINE 13 LINE 12 LINE 11 LINE 10
PCE7
PCE5
PCE3
PCE2
PCE1
LINE 25 LINE 24 LINE 23
LINE 22 LINE 21 LINE 20
PCE15
PCE12
PCE14
PCE13
PCE11
LINE 14 LINE 13
FIELD 1/3
TXO7
TXO6
PCE10
FIELD 2/4
TXO5
TXO4
TXO3
PCE0
LINE 8
LINE 7
TXO1
TXO0
TXO12
TXE7
TXE6
TXO10
TXO9
TXO8
LINE 12 LINE 11 LINE 10
LINE 9
LINE 8
LINE 7
TXE1
TXE0
TXE4
TXE3
TXE2
LINE 22 LINE 21 LINE 20
LINE 19 LINE 18 LINE 17
TXE15
TXE12
TXE14
TXE13
TXE11
TC00
TTXREQ
FALLING EDGE CONTROL
TC03 TC02 TC01 TC00
0
0
0
0
0 PCLK
0
0
0
1
1 PCLK
''
''
''
''
'' PCLK
1
1
1
0
14 PCLK
1
1
1
1
15 PCLK
TXE10
These four data bits are the final four bits of CGMS data output stream. Note it is CGMS data ONLY in these bit positions,
i.e., WSS data does not share this location.
LINE 16 LINE 15
TXO11
TXE5
TC01
C/W0 BIT DESCRIPTION
CGMS Data Bits (C/W00–C/W03)
TXO2
LINE 19 LINE 18 LINE 17
TXO13
TC02
CGMS_WSS register 0 is an 8-bit-wide register. Figure 59 shows
the operations under control of this register.
PCE8
LINE 9
TXO15
TXO14
TC03
Figure 58. Teletext Control Register
LINE 19 LINE 18
PCE9
LINE 22 LINE 21 LINE 20
LINE 14 LINE 13
FIELD 2/4
LINE 12 LINE 11 LINE 10
TC04
CGMS_WSS REGISTER 0 C/W0 (C/W07–C/W00)
(Address (SR4–SR0) = 19H)
Figure 56. Pedestal Control Registers
FIELD 1/3
TC05
LINE 19 LINE 18
LINE 17 LINE 16
PCE4
TC06
TTXREQ
RISING EDGE CONTROL
TC07 TC06 TC05 TC04
0
0
0
0
0 PCLK
0
0
0
1
1 PCLK
''
''
''
''
'' PCLK
1
1
1
0
14 PCLK
1
1
1
1
15 PCLK
LINE 15 LINE 14 LINE 13 LINE 12 LINE 11 LINE 10
LINE 25 LINE 24 LINE 23
PCE6
TC07
CGMS CRC Check Control (C/W04)
When this bit is enabled (1), the last six bits of the CGMS data,
i.e., the CRC check sequence, is internally calculated by the
ADV7192. If this bit is disabled (0) the CRC values in the register are output to the CGMS data stream.
LINE 16 LINE 15
TXE9
TXE8
CGMS Odd Field Control (C/W05)
Figure 57. Teletext Control Registers
When this bit is set (1), CGMS is enabled for odd fields. Note
this is only valid in NTSC mode.
TELETEXT REQUEST CONTROL REGISTER TC07
(TC07–TC00)
(Address (SR4–SR0) = 1CH)
CGMS Even Field Control (C/W06)
When this bit is set (1), CGMS is enabled for even fields. Note
this is only valid in NTSC mode.
Teletext Control Register is an 8-bit-wide register. See Figure 58.
WSS Control (C/W07)
TTXREQ Falling Edge Control (TC00–TC03)
These bits control the position of the falling edge of TTXREQ.
It can be programmed from zero clock cycles to a maximum of 15
clock cycles. This controls the active window for Teletext data.
Increasing this value reduces the amount of Teletext bits below the
default of 360. If Bits TC00–TC03 are 00Hex when Bits TC04–
TC07 are changed then the falling edge of TTREQ will track that
of the rising edge (i.e., the time between the falling and rising
edge remains constant).
PCLK = clock cycle at 27 MHz.
When this bit is set (1), wide screen signalling is enabled. Note
this is only valid in PAL mode.
CGMS_WSS REGISTER 1 C/W1 (C/W17–C/W10)
(Address (SR4–SR0) = 1AH)
CGMS_WSS register 1 is an 8-bit-wide register. Figure 60 shows
the operations under control of this register.
C/W1 BIT DESCRIPTION
CGMS/WSS Data (C/W10–C/W15)
These bit locations are shared by CGMS data and WSS data. In
NTSC mode these bits are CGMS data. In PAL mode these bits
are WSS data.
TTXREQ Rising Edge Control (TC04–TC07)
These bits control the position of the rising edge of TTXREQ.
It can be programmed from zero clock cycles to a maximum of 15
clock cycles.
PCLK = clock cycle at 27 MHz.
C/W07
C/W06
WSS CONTROL
C/W07
0
1
DISABLE
ENABLE
C/W05
CGMS ODD FIELD
CONTROL
C/W05
0
1
CGMS EVEN FIELD
CONTROL
C/W06
0
1
C/W04
DISABLE
ENABLE
C/W03
C/W02
C/W01
C/W00
C/W03 – C/W00
CGMS DATA BITS
DISABLE
ENABLE
CGMS CRC CHECK
CONTROL
C/W04
0
1
DISABLE
ENABLE
Figure 59. CGMS_WSS Register 0
–38–
REV. A
ADV7192
CGMS Data (C/W16–C/W17)
COLOR CONTROL REGISTERS 1–2 (CC1–CC2)
(Address (SR4–SR0) = 1EH–1FH)
These bits are CGMS data bits only.
C/W17
C/W16
C/W15
C/W14
C/W13
C/W12
C/W17 – C/W16
C/W15 – C/W10
CGMS DATA
CGMS/WSS DATA
C/W11
C/W10
The color control registers are 8-bit-wide registers used to scale
the U and V output levels. Figure 63 shows the operations under
control of these registers.
CC17
CC16
CC15
Figure 60. CGMS_WSS Register 1
CC14
CC13
CC12
CC11
CC10
CC22
CC21
CC20
CC17 – CC10
U SCALE VALUE
CGMS_WSS REGISTER 2
C/W1 (C/W27–C/W20)
(Address (SR4–SR0) = 1BH)
CC27
CC26
CC25
CGMS_WSS Register 2 is an 8-bit-wide register. Figure 61 shows
the operations under control of this register.
V SCALE VALUE
Figure 63. Color Control Registers
These bit locations are shared by CGMS data and WSS data. In
NTSC mode these bits are CGMS data. In PAL mode these bits
are WSS data.
C/W26
C/W25
C/W24
C/W23
CC23
CC27 – CC20
C/W2 BIT DESCRIPTION
CGMS/WSS Data (C/W20–C/W27)
C/W27
CC24
C/W22
C/W21
C/W20
CC1 BIT DESCRIPTION
U Scale Value (CC10–CC17)
These eight bits represent the value required to scale the U level
from 0.0 to 2.0 of its initial level. The value of these eight bits is
calculated using the following equation:
U Scale Value = Scale Factor × 128
C/W27 – C/W20
Example:
CGMS/WSS DATA
Scale Factor = 1.18
Figure 61. CGMS_WSS Register 2
CONTRAST CONTROL REGISTER (CC00–CC07)
(Address (SR4–SR0) = 1DH)
The contrast control register is an 8-bit-wide register used to
scale the Y output levels. Figure 62 shows the operation under
control of this register.
Y Scale Value (CC00–CC07)
These eight bits represent the value required to scale the Y pixel
data from 0.0 to 1.5 of its initial level. The value of these eight
bits is calculated using the following equation:
Y Scale Value = Scale Factor × 128
U Scale Value = 1.18 × 128 = 151.04
U Scale Value = 151 (rounded to the nearest integer)
U Scale Value = 10010111b
U Scale Value = 97h
CC2 BIT DESCRIPTION
V Scale Value (CC20–CC27)
These eight bits represent the value required to scale the V pixel
data from 0.0 to 2.0 of its initial level. The value of these eight
bits is calculated using the following equation:
V Scale Value = Scale Factor × 128
Example:
Example:
Scale Factor = 1.18
Scale Factor = 1.18
V Scale Value = 1.18 × 128 = 151.04
V Scale Value = 151 (rounded to the nearest integer)
V Scale Value = 10010111b
V Scale Value = 97h
Y Scale Value = 1.18 × 128 = 151.04
Y Scale Value = 151 (rounded to the nearest integer)
Y Scale Value = 10010111b
Y Scale Value = 97h
CC07
CC06
CC05
CC04
CC03
CC02
CC01
CC00
CC07 – CC00
Y SCALE VALUE
Figure 62. Contrast Control Register
REV. A
–39–
ADV7192
HUE ADJUST CONTROL REGISTER (HCR)
(Address (SR5–SR0) = 20H)
BRIGHTNESS CONTROL REGISTER (BCR)
(Address (SR5–SR0) = 21H)
The hue control register is an 8-bit-wide register used to adjust
the hue on the composite and chroma outputs. Figure 64 shows
the operation under control of this register.
The brightness control register is an 8-bit-wide register which
allows brightness control. Figure 65 shows the operation under
control of this register.
HCR7
HCR6
HCR5
HCR4
HCR3
HCR2
HCR1
BCR BIT DESCRIPTION
Brightness Value (BCR0–BCR6)
HCR0
Seven bits of this 8-bit-wide register are used to control the
brightness level. The brightness is controlled by adding a programmable setup level onto the scaled Y data. This brightness
level can be a positive or negative value.
HCR7 – HCR0
HUE ADJUST VALUE
Figure 64. Hue Control Register
The programmable brightness levels in NTSC, without pedestal,
and PAL are max 15 IRE and min –7.5 IRE, in NTSC pedestal
max 22.5 IRE and min 0 IRE.
HCR BIT DESCRIPTION
Hue Adjust Value (HCR0–HCR7)
These eight bits represent the value required to vary the hue of
the video data, i.e., the variance in phase of the subcarrier during
active video with respect to the phase of the subcarrier during
the colorburst. The ADV7192 provides a range of ± 22.5° increments of 0.17578125°. For normal operation (zero adjustment),
this register is set to 80Hex. FFHex and 00Hex represent the
upper and lower limit (respectively) of adjustment attainable.
Hue Adjust [°] = 0.17578125° × (HCRd – 128); for positive Hue
Adjust Value
Example:
To adjust the hue by 4° write 97h to the Hue Adjust Control
Register:
Table IV. Brightness Control Register Value
Setup
Level in
NTSC with
Pedestal
Setup
Level in
NTSC No
Pedestal
Setup
Level in
PAL
Brightness
Control
Register
Value
22.5 IRE
15 IRE
7.5 IRE
0 IRE
15 IRE
7.5 IRE
0 IRE
–7.5 IRE
15 IRE
7.5 IRE
0 IRE
–7.5 IRE
1Eh
0Fh
00h
71h
NOTE
Values in the range from 3F h to 44h might result in an invalid output signal.
(4/0.17578125) + 128 = 151d* = 97h
To adjust the hue by (–4°) write 69h to the Hue Adjust Control
Register:
(–4/0.17578125) + 128 = 105d* = 69h
*Rounded to the nearest integer.
EXAMPLE
1. Standard: NTSC with Pedestal. To add 20 IRE brightness level write 28h into the Brightness Control Register:
[Brightness Control Register Value]h = [IRE Value ⫻ 2.015631]h = [20 ⫻ 2.015631]h = [40.31262]h = 28h
2. Standard: PAL. To add –7 IRE brightness level write 72h into the Brightness Control Register:
[|IRE Value| ⫻ 2.015631] = [7 ⫻ 2.015631] = [14.109417] = 0001110b
[0001110] into two’s complement = 1110010b = 72h
NTSC WITHOUT PEDESTAL
+7.5 IRE
100 IRE
0 IRE
–7.5 IRE
NO SETUP VALUE
ADDED
BCR7
BCR6
POSITIVE SETUP
VALUE ADDED
WRITE TO BRIGHTNESS
CONTROL REGISTER: 12h
BCR5
BCR4
BCR3
NEGATIVE SETUP
VALUE ADDED
WRITE TO BRIGHTNESS
CONTROL REGISTER: 6Eh
BCR2
BCR7
BCR6 – BCR0
ZERO MUST BE
WRITTEN TO
THIS BIT
BRIGHTNESS VALUE
BCR1
BCR0
Figure 65. Brightness Control Register
–40–
REV. A
ADV7192
SHARPNESS RESPONSE REGISTER (PR)
(Address (SR5–SR0) = 22H)
DNR07
The sharpness response register is an 8-bit-wide register. The
four MSBs are set to 0. The four LSBs are written to in order to
select a desired filter response. Figure 66 shows the operation
under control of this register.
0
0
0
0
0
0
0
0
1
DNR03
0
0
0
0
1
1
1
1
0
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
DNR07
PR2
PR1
PR7 – PR4
PR3 – PR0
ZERO MUST BE
WRITTEN TO
THESE BITS
SHARPNESS
RESPONSE VALUE
DNR00
CORING GAIN BORDER
0
0
0
0
0
0
0
0
1
+1/16
+2/16
+3/16
+4/16
+5/16
+6/16
+7/16
+8/16
DNR06
DNR05
DNR04
DNR03
CORING GAIN DATA
0
0
0
0
0
0
0
0
1
A Logical 0 must be written to these bits.
PR3
DNR01
DNR DNR DNR DNR
03 02 01 00
0
0
0
0
1
1
1
1
0
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
+1/16
+2/16
+3/16
+4/16
+5/16
+6/16
+7/16
+8/16
PR0
0
0
0
0
1
1
1
1
0
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
DNR02
DNR01
DNR00
CORING GAIN BORDER
DNR DNR DNR DNR
07 06 05 04
PR4
DNR02
Figure 67. DNR Register 0 in DNR Sharpness Mode
Reserved (PR4–PR7)
PR5
DNR04
CORING GAIN DATA
These four bits are used to select the desired luma filter response. The
option of twelve responses is given supporting a gain boost/
attenuation in the range –4 dB to +4 dB. The value 12 (1100)
written to these four bits corresponds to a boost of +4 dB while
the value 0 (0000) corresponds to –4 dB. For normal operation
these four bits are set to 6 (0110). Note: Luma Filter Select has
to be set to Extended Mode and Sharpness Filter Control has to
be enabled for settings in the Sharpness Control Register to
take effect (MR02–04 = 100; MR74 = 1).
PR6
DNR05
DNR DNR DNR DNR
07 06 05 04
PR BIT DESCRIPTION
Sharpness Response Value (PR3–PR0)
PR7
DNR06
DNR DNR DNR DNR
03 02 01 00
0
–1/8
–2/8
–3/8
–4/8
–5/8
–6/8
–7/8
–1
0
0
0
0
0
0
0
0
1
0
0
0
0
1
1
1
1
0
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
0
–1/8
–2/8
–3/8
–4/8
–5/8
–6/8
–7/8
–1
Figure 68. DNR Register 0 in DNR Mode
Figure 66. Sharpness Response Register
DNR REGISTERS 2–0
(DNR2–DNR0)
(Address (SR5–SR0) = 23H–25H)
The Digital Noise Reduction Registers are three 8-bit-wide
register. They are used to control the DNR processing. See
Digital Noise Register section.
Coring Gain Border (DNR00–DNR03)
These four bits are assigned to the gain factor applied to border
areas.
In DNR Mode the range of gain values is 0–1, in increments of
1/8. This factor is applied to the DNR filter output which lies
below the set threshold range. The result is then subtracted
from the original signal.
DNR1 BIT DESCRIPTION
DNR Threshold (DNR10–DNR15)
These six bits are used to define the threshold value in the range
of 0 to 63. The range is an absolute value.
Border Area (DNR16)
In setting DNR16 to a Logic 1 the block transition area can be
defined to consist of four pixels. If this bit is set to a Logic 0 the
border transition area consists of two pixels, where one pixel
refers to two clock cycles at 27 MHz.
Block Size Control (DNR17)
This bit is used to select the size of the data blocks to be processed
(see Figure 69). Setting the block size control function to a Logic 1
defines a 16 × 16 pixel data block, a Logic 0 defines an 8 × 8 pixel
data block, where one pixel refers to two clock cycles at 27 MHz.
In DNR Sharpness Mode the range of gain values is 0–0.5, in
increments of 1/16. This factor is applied to the DNR filter output
which lies above the threshold range.
720 485 PIXELS
(NTSC)
2 PIXEL
BORDER DATA
The result is added to the original signal.
Coring Gain Data (DNR04–DNR07)
88
88
PIXEL BLOCK PIXEL BLOCK
These four bits are assigned to the gain factor applied to the
luma data inside the MPEG pixel block.
In DNR Mode the range of gain values is 0–1, in increments of
1/8. This factor is applied to the DNR filter output which lies
below the set threshold range. The result is then subtracted
from the original signal.
Figure 69. MPEG Block Diagram
In DNR Sharpness Mode the range of gain values is 0–0.5, in
increments of 1/16. This factor is applied to the DNR filter output which lies above the threshold range. The result is added to
the original signal.
Figures 67 and 68 show the various operations under the control
of DNR Register 0.
REV. A
–41–
ADV7192
DNR17
BLOCK SIZE
CONTROL
DNR17
0
1
DNR16
DNR15
DNR14
DNR13
DNR10
DNR DNR DNR DNR DNR DNR
15 14 13 12 11 10
DNR16
0
1
DNR11
DNR THRESHOLD
BORDER AREA
8 PIXELS
16 PIXELS
DNR12
2 PIXELS
4 PIXELS
0
0
•
•
•
1
1
0
0
•
•
•
1
1
0
0
•
•
•
1
1
0
0
•
•
•
1
1
0
0
•
•
•
1
1
0
1
•
•
•
0
1
0
1
•
•
•
62
63
Figure 70. DNR Register 1
DNR2 BIT DESCRIPTION
DNR Input Select (DNR20–DNR22)
GAIN CONTROL
BLOCK SIZE CONTROL
BORDER AREA
BLOCK OFFSET
GAIN
CORING GAIN DATA
CORING GAIN BORDER
DNR
MODE
Three bits are assigned to select the filter which is applied to the
incoming Y data. The signal which lies in the passband of the
selected filter is the signal which will be DNR processed. Figure 71
shows the filter responses selectable with this control.
NOISE SIGNAL PATH
DNR Mode Control (DNR23)
FILTER BLOCK
This bit controls the DNR mode selected. A Logic 0 selects
DNR mode, a Logic 1 selects DNR Sharpness mode.
FILTER OUTPUT
< THRESHOLD ?
Y DATA
INPUT
DNR works on the principle of defining low amplitude, highfrequency signals as probable noise and subtracting this noise
from the original signal.
FILTER OUTPUT
> THRESHOLD
MAIN SIGNAL PATH
In DNR mode, it is possible to subtract a fraction of the signal
which lies below the set threshold, assumed to be noise, from
the original signal. The threshold is set in DNR Register 1.
DNR
SHARPNESS
MODE
When DNR Sharpness mode is enabled it is possible to add a
fraction of the signal which lies above the set threshold to the
original signal, since this data is assumed to be valid data and
not noise. The overall effect being that the signal will be boosted
(similar to using Extended SSAF Filter).
FILTER BLOCK
FILTER OUTPUT
> THRESHOLD ?
Y DATA
INPUT
FILTER D
FILTER OUTPUT
< THRESHOLD
0.8
MAGNITUDE – dB
MAIN SIGNAL PATH
0.6
0.2
Four bits are assigned to this control which allows a shift of the
data block of 15 pixels maximum. Consider the coring gain positions fixed. The block offset shifts the data in steps of one pixel
such that the border coring gain factors can be applied at the
same position regardless of variations in input timing of the data.
FILTER A
1
DNR
OUT
Block Offset (DNR24–DNR27)
FILTER B
0
ADD
SIGNAL
ABOVE
THRESHOLD
RANGE
TO
ORIGINAL
SIGNAL
Figure 72. Block Diagram for DNR Mode and DNR Sharpness Mode
FILTER C
0.4
0
DNR
OUT
GAIN CONTROL
BLOCK SIZE CONTROL
BORDER AREA
BLOCK OFFSET
GAIN
CORING GAIN DATA
CORING GAIN BORDER
NOISE SIGNAL PATH
1
SUBTRACT
SIGNAL IN
THRESHOLD
RANGE
FROM
ORIGINAL
SIGNAL
2
3
4
FREQUENCY – MHz
5
6
APPLY DATA
CORING GAIN
Figure 71. Filter Response of Filters Selectable
DNR27-DNR24
= 01HEX
APPLY BORDER
CORING GAIN
OXXXXXXO
OXXXXXXO
OXXXXXXO
OXXXXXXO
OXXXXXXO
OXXXXXXO
OFFSET
CAUSED BY
VARIATIONS IN
INPUT TIMING
Figure 73. DNR27–DNR24 Block Offset Control
–42–
REV. A
ADV7192
DNR27
DNR26
DNR25
DNR24
0
0
0
•
•
•
1
1
1
0
0
0
•
•
•
1
1
1
0
0
1
•
•
•
0
1
1
0
1
0
•
•
•
1
0
1
0 PIXEL OFFSET
1 PIXEL OFFSET
2 PIXEL OFFSET
•
•
•
13 PIXEL OFFSET
14 PIXEL OFFSET
15 PIXEL OFFSET
DNR22
DNR MODE
CONTROL
BLOCK OFFSET CONTROL
DNR DNR DNR DNR
27 26 25 24
DNR23
DNR21
DNR20
DNR INPUT SELECT CONTROL
DNR DNR DNR
22 21 20
DNR23
0
DNR MODE
1
DNR
SHARPNESS
MODE
0
0
0
1
0
1
1
0
1
0
1
0
FILTER A
FILTER B
FILTER C
FILTER D
Figure 74. DNR Register 2
GAMMA CORRECTION REGISTERS 0–13 (GAMMA
CORRECTION 0–13)
(Address (SR5–SR0) = 26H–32H)
The Gamma Correction Registers are fourteen 8-bit wide register. They are used to program the gamma correction Curves A
and B.
y96 = [(80/224)0.5 × 224] + 16 = 150*
y128 = [(112/224)0.5 × 224] + 16 = 174*
*Rounded to the nearest integer.
The above will result in a gamma curve shown below, assuming
a ramp signal as an input.
Generally gamma correction is applied to compensate for the
nonlinear relationship between signal input and brightness level
output (as perceived on the CRT). It can also be applied wherever nonlinear processing is used.
300
GAMMA-CORRECTED AMPLITUDE
GAMMA CORRECTION BLOCK OUTPUT
TO A RAMP INPUT
Gamma correction uses the function:
SignalOUT = (SignalIN)
γ
where
γ = gamma power factor
Gamma correction is performed on the luma data only. The
user has the choice to use two different curves, Curve A or Curve B.
At any one time only one of these curves can be used.
250
300
SIGNAL OUTPUT
200
250
0.5
150 200
150
100
100
SIGNAL INPUT
50
50
The response of the curve is programmed at seven predefined
locations. In changing the values at these locations the gamma
curve can be modified. Between these points linear interpolation
is used to generate intermediate values. Considering the curve
to have a total length of 256 points, the seven locations are at:
32, 64, 96, 128, 160, 192, and 224.
0
0
50
100
150
LOCATION
200
250
Figure 75. Signal Input (Ramp) and Signal Output for
Gamma 0.5
Location 0, 16, 240 and 255 are fixed and can not be changed.
300
For the length of 16 to 240 the gamma correction curve has to
be calculated as below:
y = xγ
where
GAMMA-CORRECTED AMPLITUDE
GAMMA CORRECTION BLOCK OUTPUT
TO A RAMP INPUT FOR VARIOUS GAMMA VALUES
y = gamma corrected output
x = linear input signal
γ = gamma power factor
To program the gamma correction registers, the seven values for
y have to be calculated using the following formula:
yn = [x(n–16) /(240–16) ]γ × (240–16) + 16
250
SIGNAL OUTPUTS
200
0.3
0.5
150
T
PU
IN
AL
1.5
N
G
SI
100
1.8
50
where
x(n-16) = Value for x along x-axis at points n = 32, 64, 96, 128,
160, 192, or 224
yn
0
0.5
y32 = [(16/224) × 224] + 16 = 76*
y64 = [(48/224)0.5 × 224] + 16 = 120*
REV. A
50
100
150
LOCATION
200
250
Figure 76. Signal Input (Ramp) and Selectable Gamma
Output Curves
= Value for y along the y-axis, which has to be written
into the gamma correction register
Example:
0
The gamma curves shown above are examples only, any user
defined curve is acceptable in the range of 16–240.
–43–
ADV7192
BRIGHTNESS DETECT REGISTER
(Address (SR5–SR0) = 34H)
OCR BIT DESCRIPTION
Reserved (OCR00)
The Brightness Detect Register is an 8-bit-wide register used only
to read back data in order to monitor the brightness/darkness of
the incoming video data on a field-by-field basis. The brightness
information is read from the I2C and based on this information, the
color controls or the gamma correction controls may be adjusted.
A Logic 0 must be written to this bit.
The luma data is monitored in the active video area only. The
average brightness I2C register is updated on the falling edge of
every VSYNC signal.
CLKOUT Pin Control (OCR01)
This bit enables the CLKOUT pin when set to 1 and, therefore, outputs a 54 MHz clock generated by the internal PLL.
The PLL and 4× Oversampling have to be enabled for this control to take effect, (MR61 = 0; MR16 = 1).
Reserved (OCR02–03)
A Logic 0 must be written to this bit.
OUTPUT CLOCK REGISTER (OCR 9–0)
(Address (SR4–SR0) = 35H)
Reserved (OCR04–06)
The Output Clock Register is an 8-bit-wide register. Figure 76
shows the various operations under the control of this register.
Reserved (OCR07)
OCR07
OCR06
A Logic 1 must be written to these bits.
OCR05
A Logic 0 must be written to this bit.
OCR04
OCR03
OCR02
OCR01
OCR00
OCR07
OCR06 – OCR04
OCR03 – OCR02
OCR00
ZERO MUST BE
WRITTEN TO
THIS BIT
ONE MUST BE
WRITTEN TO
THESE BITS
ZERO MUST BE
WRITTEN TO
THESE BITS
ZERO MUST BE
WRITTEN TO
THIS BIT
CLKOUT
PIN CONTROL
OCR01
0
ENSABLED
1
DISABLED
Figure 77. Output Clock Register
–44–
REV. A
ADV7192
APPENDIX 1
BOARD DESIGN AND LAYOUT CONSIDERATIONS
The ADV7192 is a highly integrated circuit containing both
precision analog and high-speed digital circuitry. It has been
designed to minimize interference effects on the integrity of the
analog circuitry by the high-speed digital circuitry. It is imperative that these same design and layout techniques be applied to
the system level design such that high-speed, accurate performance
is achieved. The Recommended Analog Circuit Layout shows
the analog interface between the device and monitor.
The layout should be optimized for lowest noise on the ADV7192
power and ground lines by shielding the digital inputs and providing good decoupling. The lead length between groups of VAA
and AGND and VDD and DGND pins should by minimized so
as to minimize inductive ringing.
Ground Planes
pins on the ADV7192 must have at least one 0.1 µF decoupling capacitor to AGND. The same applies to groups of VDD and
DGND. These capacitors should be placed as close as possible to the device.
It is important to note that while the ADV7192 contains circuitry
to reject power supply noise, this rejection decreases with frequency. If a high frequency switching power supply is used, the
designer should pay close attention to reducing power supply
noise and consider using a three-terminal voltage regulator for
supplying power to the analog power plane.
Digital Signal Interconnect
The digital inputs to the ADV7192 should be isolated as much as
possible from the analog outputs and other analog circuitry. Also,
these input signals should not overlay the analog power plane.
The ground plane should encompass all ADV7192 ground pins,
voltage reference circuitry, power supply bypass circuitry for
the ADV7192, the analog output traces, and all the digital signal
traces leading up to the ADV7192. This should be as substantial as
possible to maximize heat spreading and power dissipation on
the board.
Any active termination resistors for the digital inputs should be
connected to the regular PCB power plane (VCC), and not the
analog power plane.
Power Planes
Analog Signal Interconnect
The ADV7192 and any associated analog circuitry should have its
own power plane, referred to as the analog power plane (VAA). This
power plane should be connected to the regular PCB power plane
(VCC) at a single point through a ferrite bead. This bead should
be located within three inches of the ADV7192.
The ADV7192 should be located as close as possible to the output
connectors to minimize noise pickup and reflections due to
impedance mismatch.
The metallization gap separating device power plane and board
power plane should be as narrow as possible to minimize the
obstruction to the flow of heat from the device into the general board.
Due to the high clock rates involved, long clock lines to the
ADV7192 should be avoided to reduce noise pickup.
The video output signals should overlay the ground plane, and
not the analog power plane, to maximize the high frequency power
supply rejection.
Digital inputs, especially pixel data inputs and clocking signals
should never overlay any of the analog signal circuitry and should
be kept as far away as possible.
The PCB power plane should provide power to all digital logic
on the PC board, and the analog power plane should provide
power to all ADV7192 power pins and voltage reference circuitry.
For best performance, the outputs should each have a 300 Ω load
resistor connected to AGND. These resistors should be placed
as close as possible to the ADV7192 so as to minimize reflections.
Plane-to-plane noise coupling can be reduced by ensuring that
portions of the regular PCB power and ground planes do not
overlay portions of the analog power plane, unless they can be
arranged such that the plane-to-plane noise is common-mode.
The ADV7192 should have no inputs left floating. Any inputs
that are not required should be tied to ground.
Supply Decoupling
For optimum performance, bypass capacitors should be installed
using the shortest leads possible, consistent with reliable operation,
to reduce the lead inductance. Best performance is obtained
with 0.1 µF ceramic capacitor decoupling. Each group of VAA
REV. A
–45–
ADV7192
POWER SUPPLY DECOUPLING
FOR EACH POWER SUPPLY GROUP
5V (VAA)
10nF
5V (VAA)
0.1F
5V (VAA)
5V (VAA)
COMP2
VREF
COMP1
79, 68,
34, 21
53,
48, 38
0.1F
0.1F
VAA
VDD
DAC A
300
Cb0 – Cb9
Cr0 – Cr9
0.1F
10nF
DAC B
300
ADV7192
Y0/P8 – Y7/P15
Y8 – Y9
DAC C
300
UNUSED
INPUTS
SHOULD BE
GROUNDED
P7 – P0
DAC D
300
CSO_HSO
VSO/TTX/CLAMP
DAC E
PAL_NTSC
300
SCRESET/RTC/TR
DAC F
HSYNC
5V (VAA)
100
BLANK
4.7k
27MHz CLOCK
(SAME CLOCK AS
USED BY MPEG2
DECODER)
5k
5V (VAA)
5k
SCL
RESET
4.7F
6.3V
5V (VAA)
300
VSYNC
100
MPU BUS
SDATA
TTXREQ
RSET2
CLKIN
ALSB
5V (VAA)
4.7k
1.2k
RSET1
AGND
DGND
52, 49,
35
1.2k
80, 69, 43,
33, 22
Figure 78. Recommended Analog Circuit Layout
–46–
REV. A
ADV7192
APPENDIX 2
CLOSED CAPTIONING
FCC Code of Federal Regulations (CFR) 47 Section 15.119
and EIA608 describe the closed captioning information for Lines
21 and 284.
The ADV7192 supports closed captioning conforming to the
standard television synchronizing waveform for color transmission.
Closed captioning is transmitted during the blanked active line
time of Line 21 of the odd fields and Line 284 of even fields.
Closed captioning consists of a seven-cycle sinusoidal burst that
is frequency and phase locked to the caption data. After the clock
run-in signal, the blanking level is held for two data bits and is
followed by a Logic Level 1 start bit. Sixteen bits of data follow
the start bit. These consist of two eight-bit bytes, seven data
bits, and one odd parity bit. The data for these bytes is stored
in Closed Captioning Data Registers 0 and 1.
The ADV7192 also supports the extended closed captioning
operation which is active during even fields and is encoded on
Scan Line 284. The data for this operation is stored in Closed
Captioning Extended Data Registers 0 and 1.
All clock run-in signals and timing to support Closed Captioning
on Lines 21 and 284 are generated automatically by the ADV7192
All pixels inputs are ignored during Lines 21 and 284 if closed
captioning is enabled.
10.5 0.25s
The ADV7192 uses a single buffering method. This means that
the closed captioning buffer is only one byte deep, therefore, there
will be no frame delay in outputting the closed captioning data
unlike other two byte deep buffering systems. The data must
be loaded one line before (Line 20 or Line 283) it is outputted
on Line 21 and Line 284. A typical implementation of this method
is to use VSYNC to interrupt a microprocessor, which in turn will
load the new data (two bytes) every field. If no new data is required
for transmission, 0s must be inserted in both data registers, this
is called NULLING. It is also important to load control codes all
of which are double bytes on Line 21 or a TV will not recognize
them. If there is a message like Hello World which has an odd number
of characters, it is important to pad it out to even in order to get
end of caption 2-byte control code to land in the same field.
12.91s
7 CYCLES
OF 0.5035 MHz
(CLOCK RUN-IN)
TWO 7-BIT + PARITY
ASCII CHARACTERS
(DATA)
S
T
A
R
T
50 IRE
P
A
R
I
T
Y
D0–D6
BYTE 0
40 IRE
REFERENCE COLOR BURST
(9 CYCLES)
FREQUENCY = FSC = 3.579545MHz
AMPLITUDE = 40 IRE
10.003s
33.764s
27.382s
Figure 79. Closed Captioning Waveform (NTSC)
REV. A
–47–
D0–D6
BYTE 1
P
A
R
I
T
Y
ADV7192
APPENDIX 3
COPY GENERATION MANAGEMENT SYSTEM (CGMS)
The ADV7192 supports Copy Generation Management System
(CGMS) conforming to the standard. CGMS data is transmitted
on Line 20 of the odd fields and Line 283 of even fields. Bits
C/W05 and C/W06 control whether or not CGMS data is outputed
on ODD and EVEN fields. CGMS data can only be transmitted
when the ADV7192 is configured in NTSC mode. The CGMS
data is 20 bits long, the function of each of these bits is as shown
below. The CGMS data is preceded by a reference pulse of
the same amplitude and duration as a CGMS bit, see Figure 79.
These bits are outputed from the configuration registers in the
following order: C/W00 = C16, C/W01 = C17, C/W02 = C18,
C/W03 = C19, C/W10 = C8, C/W11 = C9, C/W12 = C10,
C/W13 = C11, C/W14 = C12, C/W15 = C13, C/W16 = C14,
C/W17 = C15, C/W20 = C0, C/W21 = C1, C/W22 = C2,
C/W23 = C3, C/W24 = C4, C/W25 = C5, C/W26 = C6,
C/W27 = C7. If the bit C/W04 is set to a Logic 1, the last six
bits C19–C14 which comprise the 6-bit CRC check sequence
are calculated automatically on the ADV7192 based on the
lower 14 bits (C0–C13) of the data in the data registers and
output with the remaining 14-bits to form the complete 20-bits
of the CGMS data. The calculation of the CRC sequence is
based on the polynomial X6 + X + 1 with a preset value of
111111. If C/W04 is set to a Logic 0 then all 20-bits (C0–C19)
are output directly from the CGMS registers (no CRC calculated, must be calculated by the user).
Function of CGMS Bits
Word 0 – 6 Bits
Word 1 – 4 Bits
Word 2 – 6 Bits
CRC – 6 Bits CRC Polynomial = X6 + X + 1 (Preset to
111111)
WORD 0
B1
B2
B3
Aspect Ratio
Display Format
Undefined
WORD 0
B4, B5, B6
WORD 1
B7, B8, B9,
B10
WORD 2
B11, B12,
B13, B14
1
16:9
Letterbox
0
4:3
Normal
Identification Information About Video and
Other Signals (e.g., Audio)
Identification Signal Incidental to Word 0
Identification Signal and Information
Incidental to Word 0
100 IRE
CRC SEQUENCE
REF
70 IRE
C0
C1
C2
C3
C4
C5
C6
C7
C8
C9 C10 C11 C12 C13 C14 C15 C16 C17 C18 C19
0 IRE
49.1s 0.5s
–40 IRE
11.2s
2.235s 20ns
Figure 80. CGMS Waveform Diagram
–48–
REV. A
ADV7192
APPENDIX 4
WIDE SCREEN SIGNALING
The ADV7192 supports Wide Screen Signaling (WSS) conforming
to the standard. WSS data is transmitted on Line 23. WSS data
can only be transmitted when the ADV7192 is configured in PAL
mode. The WSS data is 14-bits long, the function of each of these
bits is as shown below. The WSS data is preceded by a run-in
sequence and a Start Code, see Figure 80. The bits are output
from the configuration registers in the following order: C/W20 = W0,
C/W21 = W1, C/W22 = W2, C/W23 = W3, C/W24 = W4,
C/W25 = W5, C/W26 = W6, C/W27 = W7, C/W10 = W8,
C/W11 = W9, C/W12 = W10, C/W13 = W11, C/W14 = W12,
C/W15 = W13. If the bit C/W07 is set to a Logic 1, it enables
the WSS data to be transmitted on Line 23. The latter portion of
Line 23 (42.5 µs from the falling edge of HSYNC) is available for
the insertion of video.
Function of CGMS Bits
Bit 0–Bit 2
Bit 3
B0,
0
1
0
1
0
1
0
1
B1,
0
0
1
1
0
0
1
1
Aspect Ratio/Format/Position
Is Odd Parity Check of Bit 0–Bit 2
B2,
0
0
0
0
1
1
1
1
B3
1
0
0
1
0
1
1
0
Aspect
Ratio
4:3
14:9
14:9
16:9
16:9
>16:9
14:9
16:9
Format
Format
Full Format
Letterbox
Letterbox
Letterbox
Letterbox
Letterbox
Full Format
Nonapplicable
Position
Position
Nonapplicable
Center
Top
Center
Top
Center
Center
Nonapplicable
B4
0
1
Camera Mode
Film Mode
B5
0
1
Standard Coding
Motion Adaptive Color Plus
B6
0
1
No Helper
Modulated Helper
B7
RESERVED
B9
0
1
0
1
B10
0
0
1
1
No Open Subtitles
Subtitles in Active Image Area
Subtitles Out of Active Image Area
RESERVED
B11
0
No Surround Sound Information
1
Surround Sound Mode
B12 RESERVED
B13 RESERVED
500mV
W0 W1 W2 W3 W4 W5 W6 W7 W8 W9 W10 W11 W12 W13
RUN-IN
SEQUENCE
START
CODE
ACTIVE
VIDEO
11.0s
38.4s
42.5s
Figure 81. WSS Waveform Diagram
REV. A
–49–
ADV7192
APPENDIX 5
TELETEXT INSERTION
Time, tPD, is the time needed by the ADV7192 to interpolate
input data on TTX and insert it onto the CVBS or Y outputs,
such that it appears tSYNTTXOUT = 10.2 µs after the leading edge
of the horizontal signal. Time TTXDEL is the pipeline delay time
by the source that is gated by the TTXREQ signal in order to
deliver TTX data.
Teletext Protocol
With the programmability that is offered with TTXREQ signal
on the Rising/Falling edges, the TTX data is always inserted at
the correct position of 10.2 µs after the leading edge of Horizontal
Sync pulse, thus this enables a source interface with variable
pipeline delays.
Thus 37 TTX bits correspond to 144 clocks (27 MHz), each bit
has a width of almost four clock cycles. The ADV7192 uses an
internal sequencer and variable phase interpolation filter to minimize the phase jitter and thus generate a bandlimited signal
which can be output on the CVBS and Y outputs.
The width of the TTXREQ signal must always be maintained
such that it allows the insertion of 360 (in order to comply with
the Teletext Standard PAL-WST) teletext bits at a text data rate
of 6.9375 Mbits/s, this is achieved by setting TC03–TC00 to 0.
The insertion window is not open if the Teletext Enable bit
(MR33) is set to 0.
At the TTX input the bit duration scheme repeats after every
37 TTX bits or 144 clock cycles. The protocol requires that
TTX Bits 10, 19, 28, 37 are carried by three clock cycles, all
other bits by four clock cycles. After 37 TTX bits, the next bits
with three clock cycles are Bits 47, 56, 65, and 74. This scheme
holds for all following cycles of 37 TTX bits, until all 360 TTX
bits are completed. All teletext lines are implemented in the
same way. Individual control of teletext lines are controlled
by Teletext Setup Registers.
The relationship between the TTX bit clock (6.9375 MHz) and
the system CLOCK (27 MHz) for 50 Hz is given as follows:
(27 MHz/4) = 6.75 MHz
(6.9375 × 106/6.75 × 106 = 1.027777
45 BYTES (360 BITS) – PAL
TELETEXT VBI LINE
ADDRESS & DATA
RUN-IN CLOCK
Figure 82. Teletext VBI Line
tSYNTTXOUT
CVBS/Y
tPD
HSYNC
tPD
10.2s
TTXDATA
TTXDEL
TTXREQ
PROGRAMMABLE PULSE EDGES
TTXST
tSYNTTXOUT = 10.2s
tPD = PIPELINE DELAY THROUGH ADV7192
TTXDEL = TTXREQ TO TTX (PROGRAMMABLE RANGE = 4 BITS [0–15 CLOCK CYCLES])
Figure 83. Teletext Functionality Diagram
–50–
REV. A
ADV7192
APPENDIX 6
OPTIONAL OUTPUT FILTER
If an output filter is required for the CVBS, Y, UV, Chroma and
RGB outputs of the ADV7192, the following filter in Figure 84
can be used in 2× Oversampling Mode. In 4× Oversampling
Mode the filter in Figure 86 is recommended. The plot of the filter characteristics are shown in Figures 85 and 87. An output filter
22H
22H
is not required if the outputs of the ADV7192 are connected to
most analog monitors or TVs, however, if the output signals are
applied to a system where sampling is used, (e.g., Digital TVs)
then a filter is required to prevent aliasing.
22H
6.8H
FILTER O/P
FILTER I/P
600
22pF
68pF
56pF
10H
FILTER I/P
FILTER O/P
600
600
27pF
68pF
600
Figure 86. Output Filter for 4× Oversampling Mode
Figure 84. Output Filter for 2× Oversampling Mode
0
0
–7
–10
–14
MAGNITUDE – dB
MAGNITUDE – dB
–20
–30
–40
–21
–28
–35
–42
–49
–50
–56
–60
–70
100k
–63
1.0M
–70
100k
100M
10M
1.0M
10M
FREQUENCY – Hz
FREQUENCY – Hz
Figure 87. Output Filter Plot for 4× Oversampling Filter
Figure 85. Output Filter Plot for 2× Oversampling Filter
2 FILTER
REQUIREMENTS
0
dB
4 FILTER
REQUIREMENTS
–30
6.75
13.5
27.0
FREQUENCY – MHz
40.5
Figure 88. Output Filter Requirements in 4× Oversampling Mode
REV. A
100M
–51–
54.0
ADV7192
APPENDIX 7
DAC BUFFERING
External buffering is needed on the ADV7192 DAC outputs.
The configuration in Figure 89 is recommended.
+VCC
When calculating absolute output full-scale current and voltage
use the following equations:
4
INPUT/
OPTIONAL
FILTER O/P
VOUT = IOUT × RLOAD
IOUT = (VREF × K)/RSET
5
AD8051
3
1
OUTPUT TO
TV MONITOR
2
–VCC
K = 4.2146 constant, VREF = 1.235 V
Figure 90. Recommended DAC Output Buffer Using an
Op Amp
VAA
ADV7192
VREF
RSET1
1.2k
PIXEL
PORT
DAC A
OUTPUT
BUFFER
CVBS
DAC B
OUTPUT
BUFFER
LUMA
DAC C
OUTPUT
BUFFER
CHROMA
DAC D
OUTPUT
BUFFER
G
DAC E
OUTPUT
BUFFER
B
DAC F
OUTPUT
BUFFER
R
DIGITAL
CORE
RSET2
1.2k
Figure 89. Output DAC Buffering Configuration
–52–
REV. A
ADV7192
APPENDIX 8
RECOMMENDED REGISTER VALUES
The ADV7192 registers can be set depending on the user standard required. The following examples give the various register formats
for several video standards.
NTSC (FSC = 3.5795454 MHz)
Address
00Hex
01Hex
02Hex
03Hex
04Hex
05Hex
06Hex
07Hex
08Hex
09Hex
0AHex
0BHex
0CHex
0DHex
0EHex
0FHex
10Hex
11Hex
12Hex
13Hex
14Hex
15Hex
16Hex
17Hex
18Hex
19Hex
1AHex
1BHex
1CHex
1DHex
1EHex
1FHex
20Hex
21Hex
22Hex
23Hex
24Hex
25Hex
35Hex
REV. A
Mode Register 0
Mode Register 1
Mode Register 2
Mode Register 3
Mode Register 4
Mode Register 5
Mode Register 6
Mode Register 7
Mode Register 8
Mode Register 9
Timing Register 0
Timing Register 1
Subcarrier Frequency Register 0
Subcarrier Frequency Register 1
Subcarrier Frequency Register 2
Subcarrier Frequency Register 3
Subcarrier Phase Register
Closed Captioning Ext Register 0
Closed Captioning Ext Register 1
Closed Captioning Register 0
Closed Captioning Register 1
Pedestal Control Register 0
Pedestal Control Register 1
Pedestal Control Register 2
Pedestal Control Register 3
CGMS_WSS Reg 0
CGMS_WSS Reg 1
CGMS_WSS Reg 2
Teletext Control Register
Contrast Control Register
Color Control Register 1
Color Control Register 2
Hue Control Register
Brightness Control Register
Sharpness Response Register
DNR 0
DNR 1
DNR 2
Output Clock Register
PAL B, D, G, H, I (FSC = 4.43361875 MHz)
Data
Address
10Hex
3FHex
62Hex
00Hex
00Hex
00Hex
00Hex
00Hex
04Hex
00Hex
08Hex
00Hex
16Hex
7CHex
F0Hex
21Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
44Hex
20Hex
00Hex
70Hex
00Hex
01Hex
02Hex
03Hex
04Hex
05Hex
06Hex
07Hex
08Hex
09Hex
0AHex
0BHex
0CHex
0DHex
0EHex
0FHex
10Hex
11Hex
12Hex
13Hex
14Hex
15Hex
16Hex
17Hex
18Hex
19Hex
1AHex
1BHex
1CHex
1DHex
1EHex
1FHex
20Hex
21Hex
22Hex
23Hex
24Hex
25Hex
35Hex
–53–
Data
Mode Register 0
Mode Register 1
Mode Register 2
Mode Register 3
Mode Register 4
Mode Register 5
Mode Register 6
Mode Register 7
Mode Register 8
Mode Register 9
Timing Register 0
Timing Register 1
Subcarrier Frequency Register 0
Subcarrier Frequency Register 1
Subcarrier Frequency Register 2
Subcarrier Frequency Register 3
Subcarrier Phase Register
Closed Captioning Ext Register 0
Closed Captioning Ext Register 1
Closed Captioning Register 0
Closed Captioning Register 1
Pedestal Control Register 0
Pedestal Control Register 1
Pedestal Control Register 2
Pedestal Control Register 3
CGMS_WSS Reg 0
CGMS_WSS Reg 1
CGMS_WSS Reg 2
Teletext Control Register
Contrast Control Register
Color Control Register 1
Color Control Register 2
Hue Control Register
Brightness Control Register
Sharpness Response Register
DNR0
DNR1
DNR2
Output Clock Register
11Hex
3FHex
62Hex
00Hex
00Hex
00Hex
00Hex
00Hex
04Hex
00Hex
08Hex
00Hex
CBHex
8AHex
09Hex
2AHex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
44Hex
20Hex
00Hex
70Hex
ADV7192
PAL N (FSC = 4.43361875 MHz)
Address
00Hex
01Hex
02Hex
03Hex
04Hex
05Hex
06Hex
07Hex
08Hex
09Hex
0AHex
0BHex
0CHex
0DHex
0EHex
0FHex
10Hex
11Hex
12Hex
13Hex
4Hex
15Hex
16Hex
17Hex
18Hex
19Hex
1AHex
1BHex
1CHex
DHex
1EHex
1FHex
20Hex
21Hex
22Hex
23Hex
24Hex
25Hex
35Hex
Mode Register 0
Mode Register 1
Mode Register 2
Mode Register 3
Mode Register 4
Mode Register 5
Mode Register 6
Mode Register 7
Mode Register 8
Mode Register 9
Timing Register 0
Timing Register 1
Subcarrier Frequency Register 0
Subcarrier Frequency Register 1
Subcarrier Frequency Register 2
Subcarrier Frequency Register 3
Subcarrier Phase Register
Closed Captioning Ext Register 0
Closed Captioning Ext Register 1
Closed Captioning Register 0
Closed Captioning Register 1
Pedestal Control Register 0
Pedestal Control Register 1
Pedestal Control Register 2
Pedestal Control Register 3
CGMS_WSS Reg 0
CGMS_WSS Reg 1
CGMS_WSS Reg 2
Teletext Control Register
Contrast Control Register
Color Control Register 1
Color Control Register 2
Hue Control Register
Brightness Control Register
Sharpness Response Register
DNR 0
DNR 1
DNR 2
Output Clock Register
PAL 60 (FSC = 4.43361875 MHz)
Data
Address
13Hex
3FHex
62Hex
00Hex
00Hex
00Hex
00Hex
00Hex
04Hex
00Hex
08Hex
00Hex
CBHex
8AHex
09Hex
2AHex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
44Hex
20Hex
00Hex
70Hex
00Hex
01Hex
02Hex
03Hex
04Hex
05Hex
06Hex
07Hex
08Hex
09Hex
0AHex
0BHex
0CHex
0DHex
0EHex
0FHex
10Hex
11Hex
12Hex
13Hex
14Hex
15Hex
16Hex
17Hex
18Hex
19Hex
1AHex
1BHex
1CHex
1DHex
1EHex
1FHex
20Hex
21Hex
22Hex
23Hex
24Hex
25Hex
35Hex
–54–
Data
Mode Register 0
Mode Register 1
Mode Register 2
Mode Register 3
Mode Register 4
Mode Register 5
Mode Register 6
Mode Register 7
Mode Register 8
Mode Register 9
Timing Register 0
Timing Register 1
Subcarrier Frequency Register 0
Subcarrier Frequency Register 1
Subcarrier Frequency Register 2
Subcarrier Frequency Register 3
Subcarrier Phase Register
Closed Captioning Ext Register 0
Closed Captioning Ext Register 1
Closed Captioning Register 0
Closed Captioning Register 1
Pedestal Control Register 0
Pedestal Control Register 1
Pedestal Control Register 2
Pedestal Control Register 3
CGMS_WSS Reg 0
CGMS_WSS Reg 1
CGMS_WSS Reg 2
Teletext Control Register
Contrast Control Register
Color Control Register 1
Color Control Register 2
Hue Control Register
Brightness Control Register
Sharpness Response Register
DNR 0
DNR 1
DNR 2
Output Clock Register
12Hex
3FHex
62Hex
00Hex
00Hex
00Hex
00Hex
00Hex
04Hex
00Hex
08Hex
00Hex
CBHex
8AHex
09Hex
2AHex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
44Hex
20Hex
00Hex
70Hex
REV. A
ADV7192
PAL M (FSC = 3.57561149 MHz)
Address
00Hex
01Hex
02Hex
03Hex
04Hex
05Hex
06Hex
07Hex
08Hex
09Hex
0AHex
0BHex
0CHex
0DHex
EHex
0FHex
10Hex
11Hex
12Hex
REV. A
Mode Register 0
Mode Register 1
Mode Register 2
Mode Register 3
Mode Register 4
Mode Register 5
Mode Register 6
Mode Register 7
Mode Register 8
Mode Register 9
Timing Register 0
Timing Register 1
Subcarrier Frequency Register 0
Subcarrier Frequency Register 1
Subcarrier Frequency Register 2
Subcarrier Frequency Register 3
Subcarrier Phase Register
Closed Captioning Ext Register 0
Closed Captioning Ext Register 1
Data
Address
12Hex
3FHex
62Hex
00Hex
00Hex
00Hex
00Hex
00Hex
04Hex
00Hex
08Hex
00Hex
A3Hex
EFHex
E6Hex
21Hex
00Hex
00Hex
00Hex
13Hex
14Hex
15Hex
16Hex
17Hex
18Hex
19Hex
1AHex
1BHex
1CHex
1DHex
1EHex
1FHex
20Hex
21Hex
22Hex
23Hex
24Hex
25Hex
35Hex
–55–
Data
Closed Captioning Register 0
Closed Captioning Register 1
Pedestal Control Register 0
Pedestal Control Register 1
Pedestal Control Register 2
Pedestal Control Register 3
CGMS_WSS Reg 0
CGMS_WSS Reg 1
CGMS_WSS Reg 2
Teletext Control Register
Contrast Control Register
Color Control Register 1
Color Control Register 2
Hue Control Register
Brightness Control Register
Sharpness Response Register
DNR 0
DNR 1
DNR 2
Output Clock Register
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
44Hex
20Hex
00Hex
70Hex
ADV7192
POWER-ON RESET REGISTER VALUES
POWER-ON RESET REG VALUES
(PAL_NTSC = 0, NTSC Selected)
Address
00Hex
01Hex
02Hex
03Hex
04Hex
05Hex
06Hex
07Hex
08Hex
09Hex
0AHex
0BHex
0CHex
0DHex
0EHex
0FHex
10Hex
11Hex
12Hex
13Hex
14Hex
15Hex
16Hex
17Hex
18Hex
19Hex
1AHex
1BHex
1CHex
1DHex
1EHex
1FHex
20Hex
21Hex
22Hex
23Hex
24Hex
25Hex
26Hex
27Hex
28Hex
29Hex
2AHex
2BHex
2CHex
2DHex
2EHex
2FHex
30Hex
31Hex
32Hex
33Hex
34Hex
35Hex
Mode Register 0
Mode Register 1
Mode Register 2
Mode Register 3
Mode Register 4
Mode Register 5
Mode Register 6
Mode Register 7
Mode Register 8
Mode Register 9
Timing Register 0
Timing Register 1
Subcarrier Frequency Register 0
Subcarrier Frequency Register 1
Subcarrier Frequency Register 2
Subcarrier Frequency Register 3
Subcarrier Phase Register
Closed Captioning Ext Register 0
Closed Captioning Ext Register 1
Closed Captioning Register 0
Closed Captioning Register 1
Pedestal Control Register 0
Pedestal Control Register 1
Pedestal Control Register 2
Pedestal Control Register 3
CGMS_WSS Reg 0
CGMS_WSS Reg 1
CGMS_WSS Reg 2
Teletext Control Register
Contrast Control Register
Color Control Register 1
Color Control Register 2
Hue Control Register
Brightness Control Register
Sharpness Response Register
DNR 0
DNR 1
DNR 2
Gamma 0
Gamma 1
Gamma 2
Gamma 3
Gamma 4
Gamma 5
Gamma 6
Gamma 7
Gamma 8
Gamma 9
Gamma 10
Gamma 11
Gamma 12
Gamma 13
Brightness Detect Register
Output Clock Register
POWER-ON RESET REG VALUES
(PAL_NTSC = 1, PAL Selected)
Data
Address
00Hex
07Hex
08Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
08Hex
00Hex
16Hex
7CHex
F0Hex
21Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
72Hex
00Hex
01Hex
02Hex
03Hex
04Hex
05Hex
06Hex
07Hex
08Hex
09Hex
0AHex
0BHex
0CHex
0DHex
0EHex
0FHex
10Hex
11Hex
12Hex
13Hex
14Hex
15Hex
16Hex
17Hex
18Hex
19Hex
1AHex
1BHex
1CHex
1DHex
1EHex
1FHex
20Hex
21Hex
22Hex
23Hex
24Hex
25Hex
26Hex
27Hex
28Hex
29Hex
2AHex
2BHex
2CHex
2DHex
2EHex
2FHex
30Hex
31Hex
32Hex
33Hex
34Hex
35Hex
–56–
Data
Mode Register 0
Mode Register 1
Mode Register 2
Mode Register 3
Mode Register 4
Mode Register 5
Mode Register 6
Mode Register 7
Mode Register 8
Mode Register 9
Timing Register 0
Timing Register 1
Subcarrier Frequency Register 0
Subcarrier Frequency Register 1
Subcarrier Frequency Register 2
Subcarrier Frequency Register 3
Subcarrier Phase Register
Closed Captioning Ext Register 0
Closed Captioning Ext Register 1
Closed Captioning Register 0
Closed Captioning Register 1
Pedestal Control Register 0
Pedestal Control Register 1
Pedestal Control Register 2
Pedestal Control Register 3
CGMS_WSS Reg 0
CGMS_WSS Reg 1
CGMS_WSS Reg 2
Teletext Control Register
Contrast Control Register
Color Control Register 1
Color Control Register 2
Hue Control Register
Brightness Control Register
Sharpness Response Register
DNR 0
DNR 1
DNR 2
Gamma 0
Gamma 1
Gamma 2
Gamma 3
Gamma 4
Gamma 5
Gamma 6
Gamma 7
Gamma 8
Gamma 9
Gamma 10
Gamma 11
Gamma 12
Gamma 13
Brightness Detect Register
Output Clock Register
01Hex
07Hex
08Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
08Hex
00Hex
CBHex
8AHex
09Hex
2AHex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
00Hex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
xxHex
72Hex
REV. A
ADV7192
APPENDIX 9
NTSC WAVEFORMS (WITH PEDESTAL)
130.8 IRE
PEAK COMPOSITE
1268.1mV
100 IRE
REF WHITE
1048.4mV
714.2mV
387.6mV
334.2mV
7.5 IRE
0 IRE
BLACK LEVEL
BLANK LEVEL
–40 IRE
SYNC LEVEL
48.3mV
REF WHITE
1048.4mV
Figure 91. NTSC Composite Video Levels
100 IRE
714.2mV
7.5 IRE
0 IRE
BLACK LEVEL
BLANK LEVEL
–40 IRE
SYNC LEVEL
387.6mV
334.2mV
48.3mV
Figure 92. NTSC Luma Video Levels
PEAK CHROMA
963.8mV
629.7mV (p-p)
286mV (p-p)
BLANK/BLACK LEVEL
650mV
PEAK CHROMA
335.2mV
0mV
Figure 93. NTSC Chroma Video Levels
100 IRE
REF WHITE
1052.2mV
720.8mV
7.5 IRE
0 IRE
BLACK LEVEL
BLANK LEVEL
387.5mV
331.4mV
–40 IRE
SYNC LEVEL
45.9mV
Figure 94. NTSC RGB Video Levels
REV. A
–57–
ADV7192
NTSC WAVEFORMS (WITHOUT PEDESTAL)
130.8 IRE
PEAK COMPOSITE
1289.8mV
100 IRE
REF WHITE
1052.2mV
714.2mV
0 IRE
BLANK/BLACK LEVEL
338mV
–40 IRE
SYNC LEVEL
52.1mV
Figure 95. NTSC Composite Video Levels
100 IRE
REF WHITE
1052.2mV
714.2mV
0 IRE
BLANK/BLACK LEVEL
SYNC LEVEL
–40 IRE
338mV
52.1mV
Figure 96. NTSC Luma Video Levels
PEAK CHROMA
978mV
694.9mV (p-p)
307mV (p-p)
650mV
BLANK/BLACK LEVEL
283mV
PEAK CHROMA
0mV
Figure 97. NTSC Chroma Video Levels
100 IRE
REF WHITE
1052.2mV
715.7mV
BLANK/BLACK LEVEL
0 IRE
SYNC LEVEL
–40 IRE
336.5mV
51mV
Figure 98. NTSC RGB Video Levels
–58–
REV. A
ADV7192
PAL WAVEFORMS
PEAK COMPOSITE
1284.2mV
1047.1mV
REF WHITE
696.4mV
350.7mV
BLANK/BLACK LEVEL
50.8mV
SYNC LEVEL
Figure 99. PAL Composite Video Levels
REF WHITE
1047mV
696.4mV
BLANK/BLACK LEVEL
350.7mV
SYNC LEVEL
50.8mV
Figure 100. PAL Luma Video Levels
990mV
PEAK CHROMA
672mV (p-p)
300mV (p-p)
650mV
BLANK/BLACK LEVEL
318mV
PEAK CHROMA
0mV
Figure 101. PAL Chroma Video Levels
REF WHITE
1050.2mV
698.4mV
BLANK/BLACK LEVEL
351.8mV
SYNC LEVEL
51mV
Figure 102. PAL RGB Video Levels
REV. A
–59–
ADV7192
VIDEO MEASUREMENT PLOTS
COLOR BAR (NTSC)
FIELD = 1
LINE = 21
WFM
FCC COLOR BAR
LUMINANCE LEVEL (IRE)
99.6
69.0
55.9
48.1
36.3
28.3
15.7
7.7
GRAY
YELLOW
CYAN
GREEN
MAGENTA
RED
BLUE
BLACK
100
50
0
CHROMINANCE LEVEL (IRE)
0.0
62.1
87.6
81.8
81.8
87.8
62.1
0.0
GRAY
YELLOW
CYAN
GREEN
MAGENTA
RED
BLUE
BLACK
167.3
283.8
240.9
60.80
103.6
347.1
YELLOW
CYAN
GREEN
MAGENTA
RED
BLUE
100
50
0
CHROMINANCE PHASE (DEGREE)
400
200
0
GRAY
AVERAGE 32
BLACK
32
Figure 103. NTSC Color Bar Measurement
COLOR BAR (PAL)
FIELD = 1
LINE = 21
WFM
FCC COLOR BAR
LUMINANCE LEVEL (mV)
1000
695.7
464.8
366.6
305.7
217.3
156.4
61.2
–0.4
GRAY
YELLOW
CYAN
GREEN
MAGENTA
RED
BLUE
BLACK
500
0
CHROMINANCE LEVEL (mV)
1000
0.0
474.4
669.1
623.5
624.7
669.6
475.2
0.0
GRAY
YELLOW
CYAN
GREEN
MAGENTA
RED
BLUE
BLACK
166.7
283.3
240.4
60.4
103.2
346.7
YELLOW
CYAN
GREEN
MAGENTA
RED
BLUE
500
0
CHROMINANCE PHASE (DEGREE)
400
300
200
100
0
GRAY
AVERAGE 32
BLACK
32
Figure 104. PAL Color Bar Measurement
–60–
REV. A
ADV7192
DG DP (NTSC)
MOD 5 STEP
WFM
DG DP (PAL)
FIELD = 1, LINE = 21
0.00
0.21
0.02
0.07
0.27
MIN = 0.00, MAX = 0.32, p-p/MAX = 0.32
DIIFFERENTIAL GAIN (PERCENT)
MIN = 0.00, MAX = 0.27, p-p/MAX = 0.27
DIIFFERENTIAL GAIN (PERCENT)
2.5
MOD 5 STEP
WFM
LINE = 570
0.08
2.5
0.00
0.30
0.15
0.24
0.32
0.26
1st
2nd
3rd
4th
5th
6th
1.5
1.5
0.5
0.5
–0.5
–0.5
–1.5
–1.5
–2.5
1st
2nd
3rd
4th
2.5
0.10
6th
–2.5
0.12
0.15
0.13
0.10
2.5
1.5
1.5
0.5
0.5
–0.5
–0.5
–1.5
–1.5
–2.5
1st
2nd
3rd
AVERAGE 32
4th
5th
6th
–2.5
Figure 105. NTSC DG DP Measurement
MOD 5 STEP
WFM
1st
2nd
0.13
0.16
3rd
4th
0.12
0.14
5th
6th
32
LUMINANCE NONLINEARITY (PAL)
WFM
MOD 5 STEP
LINE = 570
p-p = 0.4
LUMINANCE NONLINEARITY (PERCENT)
99.9
0.09
Figure 107. PAL DG DP Measurement
FIELD = 2, LINE = 77
111
0.00
AVERAGE 32
32
LUMINANCE NONLINEARITY (NTSC)
MIN = 0.00, MAX = 0.16, p-p = 0.16
DIFFERENTIAL PHASE (DEGREE)
MIN = 0.00, MAX = 0.20, p-p = 0.20
DIFFERENTIAL PHASE (DEGREE)
0.00
5th
99.9
99.6
100.0
99.9
109
111
107
109
105
107
103
p-p = 0.8
LUMINANCE NONLINEARITY (PERCENT)
113
99.6
99.9
100.0
2nd
3rd
99.6
99.9
105
101
103
99
101
97
99
95
97
93
95
91
93
89
1st
AVERAGE 32
2nd
3rd
4th
91
5th
1st
32
AVERAGE 32
Figure 106. NTSC Luminance Nonlinearity
REV. A
4th
32
Figure 108. PAL Luminance Nonlinearity
–61–
5th
ADV7192
CHROMINANCE NONLINEARITY(NTSC)
WFM
FIELD = 2, LINE = 217
CHROMINANCE AMPLITUDE ERROR (PERCENT)
0.5
NTSC–7 COMBINATION
CHROMINANCE NONLINEARITY(PAL)
WFM
LINE = 572
CHROMINANCE AMPLITUDE ERROR (PERCENT)
REF = 40IRE PACKET
0.0
–0.3
0.6
0.0
140mV
420mV
MOD 3 STEP
REF = 420mV PACKET
–0.4
10
10
0
0
–10
–10
20IRE
40IRE
80IRE
CHROMINANCE PHASE ERROR (DEGREE)
–0.0
5
REF = 40IRE PACKET
0.0
0.0
0
0
–5
–5
20IRE
40IRE
80IRE
CHROMINANCE LUMINANCE INTERMODULATION (PERCENT OF 714 mV)
0.0
0.1
700mV
CHROMINANCE PHASE ERROR (DEGREE)
REF = 420mV PACKET
–0.3
0.0
–0.3
140mV
420mV
700mV
CHROMINANCE LUMINANCE INTERMODULATION (PERCENT OF 700mV)
0.1
0.0
0.0
0.1
420mV
700mV
0.2
0.1
0.2
0.0
0.0
–0.1
–0.2
–0.2
20IRE
AVERAGE 32
40IRE
80IRE
140mV
AVERAGE 32
32
Figure 109. NTSC Chrominance Nonlinearity
CHROMINANCE AM/PM (NTSC)
FIELD = 2, LINE = 217
WFM
Figure 111. PAL Chrominance Nonlinearity
RED FIELD
CHROMINANCE AM/PM (PAL)
LINE = 572
BANDWIDTH 10kHz TO 100kHz
–86.5dB RMS
–90
–85
–80
–75
PM NOISE
–70
AM NOISE
–65
–60
dB RMS
–90
–85
APPROPRIATE
–80
–75
–70
–84.2dB RMS
–95
–82.7dB RMS
–95
WFM
BANDWIDTH 10kHz TO 100kHz
AM NOISE
–95
32
–90
–85
–80
–75
PM NOISE
–65
–60
dB RMS
–65
–60
dB RMS
–65
–60
dB RMS
–82.7dB RMS
–95
(0dB = 714mV p-p WITH AGC FOR 100% CHROMINANCE LEVEL)
–70
–90
–85
–80
–75
–70
(0dB = 700mV p-p WITH AGC FOR 100% CHROMINANCE LEVEL)
Figure 110. NTSC Chrominance AM/PM
Figure 112. PAL Chrominance AM/PM
–62–
REV. A
ADV7192
NOISE SPECTRUM (NTSC)
PEDESTAL
WFM
NOISE SPECTRUM (PAL)
FIELD = 2, LINE = 223
PEDESTAL
WFM
LINE = 511
NOISE LEVEL = –79.7dB RMS
AMPLITUDE (0dB = 714mV p-p)
NOISE LEVEL = –79.1dB RMS
AMPLITUDE (0dB = 714mV p-p)
BANDWIDTH 10kHz TO FULL
BANDWIDTH 10kHz TO FULL
20
0
0
–20
–20
–40
–40
–60
–60
–80
–80
–100
–100
1
2
3
MHz
4
5
6
1
4
5
6
7
Figure 115. PAL Noise Spectrum: Pedestal
RAMP
WFM
NOISE SPECTRUM (PAL)
FIELD = 2, LINE = 217
RAMP
WFM
LINE = 572
NOISE LEVEL = –63.1dB RMS
AMPLITUDE (0dB = 714mV p-p)
NOISE LEVEL = –62.3dB RMS
AMPLITUDE (0dB = 700mV p–p)
BANDWIDTH 100kHz TO FULL (TILT NULL)
BANDWIDTH 100kHz TO FULL (TILT NULL)
0
0
–10
–10
–20
–20
–30
–30
–40
–40
–50
–50
–60
–60
–70
–70
–80
–80
–90
–90
–100
–100
1
2
3
MHz
4
5
6
1
2
3
4
5
6
MHz
Figure 114. NTSC Noise Spectrum: Ramp
REV. A
3
MHz
Figure 113. NTSC Noise Spectrum: Pedestal
NOISE SPECTRUM (NTSC)
2
Figure 116. PAL Noise Spectrum: Ramp
–63–
7
ADV7192
505mV
BLACK
BLUE
RED
MAGENTA
GREEN
CYAN
YELLOW
WHITE
BLACK
BLUE
RED
MAGENTA
GREEN
CYAN
WHITE
YELLOW
UV WAVEFORMS
505mV
423mV
334mV
171mV
BETACAM LEVEL
BETACAM LEVEL
82mV
0mV
0mV
0mV
0mV
–82mV
171mV
334mV
–423mV
505mV
–505mV
467mV
BLACK
BLUE
RED
MAGENTA
GREEN
CYAN
WHITE
YELLOW
Figure 120. NTSC 100% Color Bars No Pedestal V Levels
BLACK
BLUE
RED
MAGENTA
GREEN
CYAN
WHITE
YELLOW
Figure 117. NTSC 100% Color Bars No Pedestal U Levels
467mV
391mV
309mV
158mV
BETACAM LEVEL
BETACAM LEVEL
76mV
0mV
0mV
0mV
0mV
–76mV
–158mV
–309mV
–391mV
–467mV
–467mV
350mV
BLACK
BLUE
RED
MAGENTA
GREEN
CYAN
WHITE
YELLOW
Figure 121. NTSC 100% Color Bars with Pedestal V
BLACK
BLUE
RED
MAGENTA
GREEN
CYAN
YELLOW
WHITE
Figure 118. NTSC 100% Color Bars with Pedestal U Levels
350mV
293mV
232mV
SMPTE LEVEL
SMPTE LEVEL
118mV
57mV
0mV
0mV
0mV
0mV
–57mV
–118mV
–232mV
–293mV
–350mV
–350mV
Figure 119. PAL 100% Color Bars U Levels
Figure 122. PAL 100% Color Bars V Levels
–64–
REV. A
ADV7192
OUTPUT WAVEFORMS
0.6
VOLTS
0.4
0.2
0.0
0.2
L608
0.0
10.0
20.0
30.0
40.0
50.0
60.0
MICROSECONDS
NOISE REDUCTION: 0.00 dB
APL = 39.1%
625 LINE PAL
NO FILTERING
PRECISION MODE OFF
SYNCHRONOUS
SLOW CLAMP TO 0.00 V AT 6.72 s
SOUND-IN-SYNC OFF
SYNC = SOURCE
FRAMES SELECTED: 1 2 3 4
Figure 123. 100/0/75/0 PAL Color Bars
VOLTS
0.5
0.0
L575
0.0
10.0
APL NEEDS SYNC = SOURCE!
625 LINE PAL
NO FILTERING
20.0
30.0
40.0
50.0
60.0
70.0
NO BRUCH SIGNAL
MICROSECONDS
PRECISION MODE OFF
SOUND-IN-SYNC OFF
SYNCHRONOUS
SYNC = A
SLOW CLAMP TO 0.00 V AT 6.72 s
FRAMES SELECTED: 1
Figure 124. 100/0/75/0 PAL Color Bars Luminance
REV. A
–65–
ADV7192
VOLTS
0.5
0.0
–0.5
L575
10.0
20.0
30.0
40.0
MICROSECONDS
APL NEEDS SYNC = SOURCE!
625 LINE PAL
NO FILTERING
50.0
60.0
NO BRUCH SIGNAL
PRECISION MODE OFF
SYNCHRONOUS
SLOW CLAMP TO 0.00 V AT 6.72 s
SOUND-IN-SYNC OFF
SYNC = A
FRAMES SELECTED: 1
Figure 125. 100/0/75/0 PAL Color Bars Chrominance
100.0
VOLTS
IRE:FLT
0.5
50.0
0.0
0.0
–50.0
0.0
APL = 44.6%
525 LINE NTSC
F1
L76
10.0
20.0
30.0
40.0
MICROSECONDS
50.0
PRECISION MODE OFF
SYNCHRONOUS
NO FILTERING
SLOW CLAMP TO 0.00 V AT 6.72 s
60.0
SYNC = A
FRAMES SELECTED: 1 2
Figure 126. 100/7.5/75/7.5 NTSC Color Bars
–66–
REV. A
ADV7192
100.0
0.6
0.4
VOLTS
IRE:FLT
50.0
0.2
0.0
0.0
–0.2
F2
L238
10.0
20.0
30.0
40.0
MICROSECONDS
NOISE REDUCTION: 15.05dB
APL = 44.7%
525 LINE NTSC
NO FILTERING
50.0
PRECISION MODE OFF
SYNCHRONOUS
SLOW CLAMP TO 0.00 V AT 6.72 s
60.0
SYNC = SOURCE
FRAMES SELECTED: 1 2
Figure 127. 100/7.5/75/7.5 NTSC Color Bars Luminance
0.4
50.0
0.0
IRE:FLT
VOLTS
0.2
–0.2
–50.0
–0.4
F1
L76
0.0
10.0
20.0
30.0
40.0
MICROSECONDS
NOISE REDUCTION: 15.05dB
APL NEEDS SYNC = SOURCE!
525 LINE NTSC
NO FILTERING
50.0
PRECISION MODE OFF
SYNCHRONOUS
SLOW CLAMP TO 0.00 V AT 6.72 s
60.0
SYNC = B
FRAMES SELECTED: 1 2
Figure 128. 100/7.5/75/7.5 NTSC Color Bars Chrominance
REV. A
–67–
ADV7192
APPENDIX 10
VECTOR PLOTS
V
APL = 39.6%
SYSTEM LINE L608
ANGLE (DEG) 0.0
GAIN 1.000 0.000dB
625 LINE PAL
BURST FROM SOURCE
DISPLAY +V AND –V
cy
R
g
M
g
75%
100%
YI
b
U
yl
B
G
Cy
m
g
r
SOUND IN SYNC OFF
Figure 129. PAL Vector Plot
R-Y
APL = 45.1%
SYSTEM LINE L76F1
ANGLE (DEG) 0.0
GAIN 1.000 0.000dB
525 LINE NTSC
BURST FROM SOURCE
cy
I
R
M
g
YI
Q
b
100%
B-Y
75%
B
G
Cy
–Q
–I
SETUP 7.5%
Figure 130. NTSC Vector Plot
–68–
REV. A
ADV7192
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
0.063 (1.60)
MAX
0.030 (0.75)
0.020 (0.50)
0.640 (16.25)
SQ
0.620 (15.75)
0.553 (14.05)
SQ
0.549 (13.95)
80
1
61
60
SEATING
PLANE
0.486
(12.35)
TYP
SQ
TOP VIEW
(PINS DOWN)
20
21
41
40
0.029 (0.73)
0.022 (0.57)
0.014 (0.35)
0.010 (0.25)
PRINTED IN U.S.A.
0.004 (0.10)
MAX
0.006 (0.15)
0.002 (0.05)
0.057 (1.45)
0.053 (1.35)
C00229–0–12/00 (rev. A)
80-Lead LQFP
(ST-80)
REV. A
–69–
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