TI THS7373IPW

THS7373
www.ti.com
SBOS506 – DECEMBER 2009
4-Channel Video Amplifier with 1-SD and 3-HD Sixth-Order Filters and 6-dB Gain
Check for Samples: THS7373
FEATURES
DESCRIPTION
• One SDTV Video Amplifier for CVBS Video
• Three HDTV Video Amplifiers for Y’/P’B/P’R,
720p/1080i/1080p30, or G’B’R’ (R’G’B’)
• Sixth-Order Low-Pass Filters:
– CVBS Channel: –3 dB at 9.5-MHz
– HD Channels: –3 dB at 36-MHz with
350-MHz Bypass for 1080p60 Support
• Versatile Input Biasing:
– DC-Coupled with 300-mV Output Shift
– AC-Coupled with Sync-Tip Clamp
– Allows AC-Coupling with Biasing
• Built-in 6-dB Gain (2 V/V)
• +3-V to +5-V Single-Supply Operation
• Rail-to-Rail Output:
– Output Swings Within 100 mV from the
Rails: Allows AC or DC Output Coupling
– Supports Driving Two Video Lines/Channel
• Low Total Quiescent Current: 16.2 mA at 3.3 V
• Disabled Supply Current Function: 0.1 μA
• Low Differential Gain/Phase: 0.15%/0.25°
• RoHS-Compliant Package: TSSOP-14
Fabricated using the revolutionary, complementary
Silicon-Germanium (SiGe) BiCom3X process, the
THS7373 is a low-power, single-supply, 3-V to 5-V,
four-channel integrated video buffer. It incorporates
one
standard-definition
(CVBS)
and
three
high-definition (HD) filter channels. All filters feature
sixth-order Butterworth characteristics that are useful
as digital-to-analog converter (DAC) reconstruction
filters or as analog-to-digital converter (ADC)
anti-aliasing filters. The HD filters can be bypassed to
support 1080p60 video or up to quad extended
graphics array (QXGA) RGB video.
1
234
As part of the THS7373 flexibility, the input can be
configured for ac- or dc-coupled inputs. The 300-mV
output level shift allows for a full sync dynamic range
at the output with 0-V input. The ac-coupled modes
include a transparent sync-tip clamp option for
composite video (CVBS), Y', and G'B'R' signals.
AC-coupled biasing for C'/P'B/P'R channels can easily
be achieved by adding an external resistor to VS+.
The THS7373 rail-to-rail output stage with 6-dB gain
allows for both ac and dc line driving. The ability to
drive two lines, or 75-Ω loads, allows for maximum
flexibility as a video line driver. The 16.2-mA total
quiescent current at 3.3 V and 0.1 μA (disabled
mode) makes it an excellent choice for
power-sensitive video applications.
APPLICATIONS
•
•
•
The THS7373 is available in a small TSSOP-14
package
that
is
lead-free
and
green
(RoHS-compliant).
Set Top Box Output Video Buffering
PVR/DVDR/ BluRay™ Output Buffering
Low-Power Video Buffering
THS7373
CVBS Out
75 W
CVBS
SOC/Encoder/DAC
R
CVBS OUT 14
1
CVBS IN
2
HD CH1 IN
HD CH1 OUT 13
3
HD CH2 IN
HD CH2 OUT 12
4
HD CH3 IN
HD CH3 OUT 11
5
GND
6
DISABLE
7
NC
75 W
Y' Out
75 W
Y'/G'
R
P’B/B'
75 W
VS+ 10
HD BYPASS
9
NC
8
75 W
P'B Out
R
P’R/R'
R
75 W
75 W
To GPIO Controller
or GND
P'R Out
75 W
+3 V to +5 V
Figure 1. Single-Supply, DC-Input/DC-Output Coupled Video Line Driver
1
2
3
4
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
BluRay is a trademark of Blu-ray Disc Association (BDA).
Macrovision is a registered trademark of Macrovision Corporation.
All other trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2009, Texas Instruments Incorporated
THS7373
SBOS506 – DECEMBER 2009
www.ti.com
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
PACKAGE/ORDERING INFORMATION (1)
PRODUCT
PACKAGE-LEAD
THS7373IPW
(1)
(2)
TRANSPORT MEDIA, QUANTITY
Rails, 90
TSSOP-14
THS7373IPWR
(2)
ECO STATUS (2)
Pb-Free, Green
Tape and Reel, 2000
For the most current package and ordering information see the Package Option Addendum at the end of this document, or see the TI
web site at www.ti.com.
These packages conform to Lead (Pb)-free and green manufacturing specifications. Additional details including specific material content
can be accessed at www.ti.com/leadfree.
GREEN: TI defines Green to mean Lead (Pb)-Free and in addition, uses less package materials that do not contain halogens, including
bromine (Br), or antimony (Sb) above 0.1% of total product weight. N/A: Not yet available Lead (Pb)-Free; for estimated conversion
dates, go to www.ti.com/leadfree. Pb-FREE: TI defines Lead (Pb)-Free to mean RoHS compatible, including a lead concentration that
does not exceed 0.1% of total product weight, and, if designed to be soldered, suitable for use in specified lead-free soldering
processes.
ABSOLUTE MAXIMUM RATINGS (1)
Over operating free-air temperature range, unless otherwise noted.
THS7373
UNIT
5.5
V
Supply voltage, VS+ to GND
Input voltage, VI
–0.4 to VS+
V
±90
mA
Output current, IO
Continuous power dissipation
See the Dissipation Ratings Table
Maximum junction temperature, any condition
(2)
, TJ
+150
°C
+125
°C
–60 to +150
°C
Human body model (HBM)
2500
V
Charge device model (CDM)
1000
V
Machine model (MM)
200
V
Maximum junction temperature, continuous operation, long-term
reliability (3), TJ
Storage temperature range, TSTG
ESD rating:
(1)
(2)
(3)
Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may
degrade device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond
those specified is not implied.
The absolute maximum junction temperature under any condition is limited by the constraints of the silicon process.
The absolute maximum junction temperature for continuous operation is limited by the package constraints. Operation above this
temperature may result in reduced reliability and/or lifetime of the device.
DISSIPATION RATINGS
(1)
PACKAGE
θJC
(°C/W)
θJA
(°C/W)
AT TA ≤ +25°C
POWER RATING
AT TA = +85°C
POWER RATING
TSSOP-14 (PW)
38
115 (1)
870 mW
348 mW
These data were taken with the JEDEC High-K test printed circuit board (PCB). For the JEDEC low-K test PCB, the θJA is 130°C/W.
RECOMMENDED OPERATING CONDITIONS
MIN
Supply voltage, VS+
Ambient temperature, TA
2
NOM
3
–40
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+25
MAX
UNIT
5
V
+85
°C
Copyright © 2009, Texas Instruments Incorporated
Product Folder Link(s): THS7373
THS7373
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SBOS506 – DECEMBER 2009
ELECTRICAL CHARACTERISTICS: VS+ = +3.3 V
At TA = +25°C, RL = 150 Ω to GND, Filter mode, and dc-coupled input/output, unless otherwise noted.
THS7373
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
TEST
LEVEL (1)
–1 dB; VO = 0.2 VPP and 2 VPP
7
8.2
10.2
MHz
B
AC PERFORMANCE (CVBS CHANNEL)
Passband bandwidth
Small- and large-signal bandwidth
Attenuation
–3 dB; VO = 0.2 VPP and 2 VPP
7.8
9.5
11.4
MHz
B
With respect to 500 kHz (2), f = 6.75 MHz
–0.9
0.2
1.1
dB
B
With respect to 500 kHz (2), f = 27 MHz
42
54
dB
B
Group delay
Group delay variation
f = 100 kHz
70
ns
C
f = 5.1 MHz with respect to 100 kHz
9
ns
C
NTSC/PAL
0.15/0.25
%
C
Differential gain
Differential phase
NTSC/PAL
0.25/0.35
Degrees
C
f = 1 MHz, VO = 1.4 VPP
–70
dB
C
100 kHz to 6 MHz, non-weighted
70
dB
C
100 kHz to 6 MHz, unified weighting
78
dB
C
6.3
dB
A
6.35
dB
B
Total harmonic distortion
Signal-to-noise ratio
Gain
Output impedance
5.7
5.65
6
f = 6.75 MHz
0.8
Ω
C
Disabled
20 || 3
kΩ || pF
C
f = 6.75 MHz
45
dB
C
f = 1 MHz, CVBS channel to HD channels
–85
dB
C
Return loss
Crosstalk
TA = +25°C
TA = –40°C to +85°C
AC PERFORMANCE (HD CHANNELS)
Passband bandwidth
–1 dB; VO = 0.2 VPP and 2 VPP
27.8
33
38.8
MHz
B
Small- and large-signal bandwidth
–3 dB; VO = 0.2 VPP and 2 VPP
30.3
36
42.5
MHz
B
–3 dB; VO = 0.2 VPP
170
350
MHz
B
V/μs
B
dB
B
Bypass mode bandwidth
Slew rate
Attenuation
Bypass mode; VO = 2 VPP
400
450
With respect to 500 kHz (2), f = 27 MHz
–1
–0.1
With respect to 500 kHz (2), f = 74 MHz
34
40
dB
B
f = 100 kHz
20
ns
C
f = 27 MHz with respect to 100 kHz
6
ns
C
0.3
ns
C
Group delay
Group delay variation
Channel-to-channel delay
1
Differential gain
NTSC/PAL
0.1/0.1
%
C
Differential phase
NTSC/PAL
0.1/0.15
Degrees
C
f = 10 MHz, VO = 1.4 VPP
–52
dB
C
100 kHz to 30 MHz, non-weighted
62.5
dB
C
Total harmonic distortion
Signal-to-noise ratio
Gain
(1)
(2)
unified weighting
72
All channels, TA = +25°C
5.7
All channels, TA = –40°C to +85°C
5.65
6
dB
C
6.3
dB
A
6.35
dB
B
Test levels: (A) 100% tested at +25°C. Over temperature limits set by characterization and simulation. (B) Limits set by characterization
and simulation only. (C) Typical value only for information.
3.3-V supply filter specifications are ensured by 100% testing at 5-V supply along with design and characterization.
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THS7373
SBOS506 – DECEMBER 2009
www.ti.com
ELECTRICAL CHARACTERISTICS: VS+ = +3.3 V (continued)
At TA = +25°C, RL = 150 Ω to GND, Filter mode, and dc-coupled input/output, unless otherwise noted.
THS7373
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
TEST
LEVEL (1)
AC PERFORMANCE (HD CHANNELS) (continued)
Output impedance
Return loss
Crosstalk
f = 30 MHz, Filter mode
1.4
Ω
C
f = 30 MHz, Bypass mode
1
Ω
C
Disabled
1.8 || 3
kΩ || pF
C
f = 30 MHz, Filter mode
41
dB
C
f = 1 MHz, HD to CVBS channel
–78
dB
C
f = 1 MHz, CVBS to HD channels
–85
dB
C
f = 1 MHz, HD to HD channels
–78
dB
C
A
DC PERFORMANCE
Biased output voltage
Input voltage range
VIN = 0 V, CVBS channel
200
300
400
mV
VIN = 0 V, HD channels
200
300
400
mV
A
–0.1/1.46
V
C
200
μA
A
DC input, limited by output
Sync-tip clamp charge current
VIN = –0.1 V, CVBS channel
140
VIN = –0.1 V, HD channels
280
Input impedance
400
μA
A
800 || 2
kΩ || pF
C
3.15
V
C
3.1
V
A
3.1
V
C
OUTPUT CHARACTERISTICS
RL = 150 Ω to +1.65 V
RL = 150 Ω to GND
High output voltage swing
2.85
RL = 75 Ω to +1.65 V
RL = 75 Ω to GND
3
V
C
RL = 150 Ω to +1.65 V (VIN = –0.2 V)
0.04
V
C
RL = 150 Ω to GND (VIN = –0.2 V)
0.03
RL = 75 Ω to +1.65 V (VIN = –0.2 V)
0.1
Low output voltage swing
0.1
V
A
V
C
RL = 75 Ω to GND (VIN = –0.2 V)
0.05
V
C
Output current (sourcing)
RL = 10 Ω to +1.65 V
80
mA
C
Output current (sinking)
RL = 10 Ω to +1.65 V
70
mA
C
POWER SUPPLY
Operating voltage
Total quiescent current, no load
2.6
3.3
5.5
V
B
13.4
16.2
21
mA
A
VIN = 0 V, all channels off, VDISABLE = 3 V
0.1
10
μA
A
At dc
52
dB
C
V
A
VIN = 0 V, all channels on
Power-supply rejection ratio
(PSRR)
LOGIC CHARACTERISTICS (3)
VIH
Disabled or Bypass mode
VIL
Enabled or Filter mode
2
1.8
0.7
IIH
Applied voltage = 3.3 V
IIL
Applied voltage = 0 V
0.65
V
A
0.2
μA
C
0.2
μA
C
Disable time
150
ns
C
Enable time
150
ns
C
Bypass/filter switch time
15
ns
C
(3)
4
The logic input pins should not be left floating. They must be connected to logic low (or GND) or logic high (or VS+).
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THS7373
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SBOS506 – DECEMBER 2009
ELECTRICAL CHARACTERISTICS: VS+ = +5 V
At TA = +25°C, RL = 150 Ω to GND, Filter mode, and dc-coupled input/output, unless otherwise noted.
THS7373
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
TEST
LEVEL (1)
–1 dB; VO = 0.2 VPP and 2 VPP
7
8.2
10.2
MHz
B
AC PERFORMANCE (CVBS CHANNEL)
Passband bandwidth
Small- and large-signal bandwidth
Attenuation
–3 dB; VO = 0.2 VPP and 2 VPP
7.8
9.5
11.4
MHz
B
With respect to 500 kHz, f = 6.75 MHz
–0.9
0.2
1.1
dB
A
With respect to 500 kHz, f = 27 MHz
42
54
dB
A
Group delay
Group delay variation
f = 100 kHz
70
ns
C
f = 5.1 MHz with respect to 100 kHz
9
ns
C
NTSC/PAL
0.15/0.25
%
C
Differential gain
Differential phase
NTSC/PAL
0.25/0.4
Degrees
C
f = 1 MHz, VO = 1.4 VPP
–73
dB
C
100 kHz to 6 MHz, non-weighted
70
dB
C
100 kHz to 6 MHz, unified weighting
78
dB
C
6.3
dB
A
6.35
dB
B
Total harmonic distortion
Signal-to-noise ratio
Gain
Output impedance
5.7
5.65
6
f = 6.75 MHz
0.8
Ω
C
Disabled
20 || 3
kΩ || pF
C
f = 6.75 MHz
45
dB
C
f = 1 MHz, CVBS channel to HD channels
–86
dB
C
Return loss
Crosstalk
TA = +25°C
TA = –40°C to +85°C
AC PERFORMANCE (HD CHANNELS)
Passband bandwidth
–1 dB; VO = 0.2 VPP and 2 VPP
27.8
33
38.8
MHz
B
Small- and large-signal bandwidth
–3 dB; VO = 0.2 VPP and 2 VPP
30.3
36
42.5
MHz
B
–3 dB; VO = 0.2 VPP
170
375
MHz
B
V/μs
B
dB
A
Bypass mode bandwidth
Slew rate
Attenuation
Bypass mode; VO = 2 VPP
400
450
With respect to 500 kHz, f = 27 MHz
–1
–0.1
With respect to 500 kHz, f = 74 MHz
34
40
dB
A
f = 100 kHz
20
ns
C
f = 27MHz with respect to 100 kHz
6
ns
C
0.3
ns
C
Group delay
Group delay variation
Channel-to-channel delay
1
Differential gain
NTSC/PAL
0.1/0.1
%
C
Differential phase
NTSC/PAL
0.15/0.2
Degrees
C
f = 10 MHz, VO = 1.4 VPP
–55
dB
C
100 kHz to 30 MHz, non-weighted
62.5
dB
C
Total harmonic distortion
Signal-to-noise ratio
Gain
unified weighting
5.7
All channels, TA = –40°C to +85°C
5.65
Output impedance
(1)
72
All channels, TA = +25°C
6
dB
C
6.3
dB
A
6.35
dB
B
f = 30 MHz, Filter mode
1.4
Ω
C
f = 30 MHz, Bypass mode
1
Ω
C
Disabled
1.8 || 3
kΩ || pF
C
Test levels: (A) 100% tested at +25°C. Over temperature limits set by characterization and simulation. (B) Limits set by characterization
and simulation only. (C) Typical value only for information.
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THS7373
SBOS506 – DECEMBER 2009
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ELECTRICAL CHARACTERISTICS: VS+ = +5 V (continued)
At TA = +25°C, RL = 150 Ω to GND, Filter mode, and dc-coupled input/output, unless otherwise noted.
THS7373
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
TEST
LEVEL (1)
AC PERFORMANCE (HD CHANNELS) (continued)
Return loss
Crosstalk
f = 30 MHz, Filter mode
41
dB
C
f = 1 MHz, HD to CVBS channel
–78
dB
C
f = 1 MHz, CVBS to HD channels
–86
dB
C
f = 1 MHz, HD to HD channels
–78
dB
C
A
DC PERFORMANCE
Biased output voltage
Input voltage range
VIN = 0 V, CVBS channel
200
300
400
mV
VIN = 0 V, HD channels
200
300
400
mV
A
–0.1/2.3
V
C
A
DC input, limited by output
Sync-tip clamp charge current
VIN = –0.1 V, CVBS channel
140
200
μA
VIN = –0.1 V, HD channels
280
400
μA
A
800 || 2
kΩ || pF
C
4.85
V
C
4.75
V
A
4.7
V
C
Input impedance
OUTPUT CHARACTERISTICS
RL = 150 Ω to +2.5 V
RL = 150 Ω to GND
High output voltage swing
4.5
RL = 75 Ω to +2.5V
Low output voltage swing
RL = 75 Ω to GND
4.5
V
C
RL = 150 Ω to +2.5 V (VIN = –0.2 V)
0.05
V
C
RL = 150 Ω to GND (VIN = –0.2 V)
0.03
V
A
0.1
RL = 75 Ω to +2.5 V (VIN = –0.2 V)
0.1
V
C
RL = 75 Ω to GND (VIN = –0.2 V)
0.05
V
C
Output current (sourcing)
RL = 10 Ω to +2.5 V
90
mA
C
Output current (sinking)
RL = 10 Ω to +2.5 V
85
mA
C
POWER SUPPLY
Operating voltage
Total quiescent current, no load
2.6
5
5.5
V
B
14
16.9
22
mA
A
VIN = 0 V, all channels off, VDISABLE = 3 V
1
10
μA
A
At dc
52
dB
C
V
A
VIN = 0 V, all channels on
Power-supply rejection ratio
(PSRR)
LOGIC CHARACTERISTICS (2)
VIH
Disabled or Bypass engaged
VIL
Enabled or Bypass disengaged
2.2
2.1
0.8
IIH
Applied voltage = 3.3 V
IIL
Applied voltage = 0 V
0.75
V
A
0.2
μA
C
0.2
μA
C
Disable time
100
ns
C
Enable time
100
ns
C
Bypass/filter switch time
10
ns
C
(2)
6
The logic input pins should not be left floating. They must be connected to logic low (or GND) or logic high (or VS+).
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SBOS506 – DECEMBER 2009
PIN CONFIGURATION
PW PACKAGE
TSSOP-14
(TOP VIEW)
CVBS IN
1
14
CVBS OUT
HD CH1 IN
2
13
HD CH1 OUT
HD CH2 IN
3
12
HD CH2 OUT
HD CH3 IN
4
11
HD CH3 OUT
GND
5
10
VS+
DISABLE
6
9
HD BYPASS
NC
7
8
NC
NOTE: NC = No connection.
TERMINAL FUNCTIONS
TERMINAL
NAME
NO.
I/O
CVBS IN
1
I
CVBS filter video input
DESCRIPTION
HD CH.1 IN
2
I
HD channels 1 video input
HD CH.2 IN
3
I
HD channels 2 video input
HD CH.3 IN
4
I
HD channels 3 video input
GND
5
I
Ground pin for all internal circuitry
DISABLE
6
I
Disable pin. Logic high disables the part; logic low enables the part. This pin must not be left
floating. It must be connected to a defined logic state (or GND or VS+).
NC
7, 8
—
HD BYPASS
9
I
Internal HD filter bypass. Logic high bypasses the internal HD low-pass filter; logic low uses the HD
internal filters. This pin must not be left floating. It must be connected to a defined logic state (or
GND or VS+).
VS+
10
I
Positive power-supply pin; connect to +3 V to +5 V
HD CH.3
OUT
11
O
HD channels 3 video output
HD CH.2
OUT
12
O
HD channels 2 video output
HD CH.1
OUT
13
O
HD channels 1 video output
CVBS OUT
14
O
CVBS filter video output
No internal connection
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FUNCTIONAL BLOCK DIAGRAM
+VS
gm
Level
Shift
CVBS
Input
LPF
Sync-Tip Clamp
(DC Restore)
800 kW
Bypass
6 dB
CVBS
Output
6 dB
HD Channel 1
Output
6 dB
HD Channel 2
Output
6 dB
HD Channel 3
Output
6-Pole
9.5-MHz
+VS
gm
Level
Shift
HD Channel 1
Input
LPF
Sync-Tip Clamp
(DC Restore)
800 kW
Bypass
6-Pole
36-MHz
+VS
gm
Level
Shift
HD Channel 2
Input
LPF
Sync-Tip Clamp
(DC Restore)
800 kW
Bypass
6-Pole
36-MHz
+VS
gm
Level
Shift
HD Channel 3
Input
800 kW
8
LPF
Sync-Tip Clamp
(DC Restore)
+3 V to +5 V
Bypass
6-Pole
36-MHz
HD BYPASS
DISABLE
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SBOS506 – DECEMBER 2009
TYPICAL CHARACTERISTICS
Table 1. Table of Graphs: +3.3 V and +5 V
TITLE
FIGURE
Maximum Output Voltage vs Temperature
Figure 2
Minimum Output Voltage vs Temperature
Figure 3
CVBS Channel Output Impedance vs Frequency
Figure 4
CVBS Channel S22 Output Reflection Ratio vs Frequency
Figure 5
HD Channels Output Impedance vs Frequency
Figure 6
HD Channels S22 Output Reflection Ratio vs Frequency
Figure 7
CVBS Channel Disabled Output Impedance vs Frequency
Figure 8
HD Channels Disabled Output Impedance vs Frequency
Figure 9
Input Resistance vs Temperature
Figure 10
Total Quiescent Current vs Temperature
Figure 11
Total Quiescent Current vs Supply Voltage
Figure 12
Table 2. Table of Graphs: 3.3 V, Standard-Definition (CVBS) Channels
TITLE
FIGURE
CVBS Channel Small-Signal Gain vs Frequency
Figure 13, Figure 14, Figure 17
CVBS Channel Large-Signal Gain vs Frequency
Figure 15, Figure 16
CVBS Channel Phase vs Frequency
Figure 18
CVBS Channel Group Delay vs Frequency
Figure 19
CVBS Channel Second-Order Harmonic Distortion vs Frequency
Figure 23
CVBS Channel Third-Order Harmonic Distortion vs Frequency
Figure 24
Crosstalk vs Frequency
Figure 27, Figure 28
CVBS Channel Slew Rate vs Output Voltage
Figure 29
Disable Mode Response vs Time
Figure 30
CVBS Channel Differential Gain
Figure 21
CVBS Channel Differential Phase
Figure 22
CVBS Channel Small-Signal Pulse Response vs Time
Figure 25
CVBS Channel Large-Signal Pulse Response vs Time
Figure 26
CVBS Channel PSRR vs Frequency
Figure 20
Output Offset Voltage vs Temperature
Figure 31
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Table 3. Table of Graphs: 3.3 V, High-Definition (HD) Channels
TITLE
FIGURE
HD Channels Small-Signal Gain vs Frequency
Figure 32, Figure 33, Figure 36, Figure 37
HD Channels Large-Signal Gain vs Frequency
Figure 34, Figure 35
HD Channels Phase vs Frequency
Figure 38
HD Channels Group Delay vs Frequency
Figure 39
HD Channels Second-Order Harmonic Distortion vs Frequency
Figure 41, Figure 43
HD Channels Third-Order Harmonic Distortion vs Frequency
Figure 42, Figure 44
HD Channels Slew Rate vs Output Voltage
Figure 49
Bypass Mode Response vs Time
Figure 50
Disable Mode Response vs Time
Figure 51, Figure 52
HD Channels Small-Signal Pulse Response vs Time
Figure 45, Figure 47
HD Channels Large-Signal Pulse Response vs Time
Figure 46, Figure 48
HD Channels PSRR vs Frequency
Figure 40
Table 4. Table of Graphs: 5 V, Standard-Definition (CVBS) Channels
TITLE
FIGURE
CVBS Channel Small-Signal Gain vs Frequency
Figure 53, Figure 54, Figure 57
CVBS Channel Large-Signal Gain vs Frequency
Figure 55, Figure 56
CVBS Channel Phase vs Frequency
Figure 58
CVBS Channel Group Delay vs Frequency
Figure 59
CVBS Channel Second-Order Harmonic Distortion vs Frequency
Figure 63
CVBS Channel Third-Order Harmonic Distortion vs Frequency
Crosstalk vs Frequency
Figure 64
Figure 67, Figure 68
CVBS Channel Slew Rate vs Output Voltage
Figure 69
Disable Mode Response vs Time
Figure 70
CVBS Channel Small-Signal Pusle Response vs Time
Figure 65
CVBS Channel Large-Signal Pulse Response vs Time
Figure 66
CVBS Channel PSRR vs Frequency
Figure 60
CVBS Channel Differential Gain
Figure 61
CVBS Channel Differential Phase
Figure 62
CVBS Channel Attenuation at 6.75 MHz vs Temperature
Figure 71
CVBS Channel Attenuation at 27 MHz vs Temperature
Figure 72
Output Offset Voltage vs Temperature
Figure 73
10
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Table 5. Table of Graphs: 5 V, High-Definition (HD) Channels
TITLE
FIGURE
HD Channels Small-Signal Gain vs Frequency
Figure 74, Figure 75, Figure 78, Figure 79
HD Channels Large-Signal Gain vs Frequency
Figure 76, Figure 77
HD Channels Phase vs Frequency
Figure 80
HD Channels Group Delay vs Frequency
Figure 81
HD Channels Second-Order Harmonic Distortion vs Frequency
Figure 83, Figure 85
HD Channels Third-Order Harmonic Distortion vs Frequency
Figure 84, Figure 86
HD Channels Slew Rate vs Output Voltage
Figure 91
Bypass Mode Response vs Time
Figure 92
Disable Mode Response vs Time
Figure 93, Figure 94
HD Channels PSRR vs Frequency
Figure 82
HD Channels Small-Signal Pulse Response vs Time
Figure 87, Figure 89
HD Channels Large-Signal Pulse Response vs Time
Figure 88, Figure 90
HD Channels Attenuation at 27 MHz vs Temperature
Figure 95
HD Channels Attenuation at 74 MHz vs Temperature
Figure 96
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TYPICAL CHARACTERISTICS: +3.3 V and +5 V
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
MAXIMUM OUTPUT VOLTAGE vs TEMPERATURE
5.0
Minimum Output Voltage (V)
VS = +5 V
4.8
Maximum Output Voltage (V)
MINIMUM OUTPUT VOLTAGE vs TEMPERATURE
0.07
4.6
4.4
4.2
Load = 150 W to GND
DC-Coupled Output
CVBS and HD Channels
4.0
3.8
3.6
3.4
VS = +3.3 V
3.2
0.06
Load = 150 W to GND
DC-Coupled Output
CVBS and HD Channels
0.05
0.04
VS = +3.3 V
0.03
VS = +5 V
0.02
0.01
0
3.0
-40
10
-15
35
60
85
-40
10
-15
Ambient Temperature (°C)
60
85
Figure 2.
Figure 3.
CVBS CHANNEL OUTPUT IMPEDANCE vs FREQUENCY
CVBS CHANNEL S22 OUTPUT REFLECTION RATIO vs
FREQUENCY
0
VS = +3.3 V and +5 V
S22, Output Reflection Ratio (dB)
Output Impedance (W)
100
10
1
0.1
0.01
100 k
1M
10 M
100 M
VS = +3.3 V and +5 V
-10
-20
-30
-40
-50
-60
-70
100 k
1G
1M
Frequency (Hz)
100 M
1G
Figure 5.
HD CHANNELS OUTPUT IMPEDANCE vs FREQUENCY
HD CHANNELS S22 OUTPUT REFLECTION RATIO vs
FREQUENCY
0
VS = +3.3 V and +5 V
S22, Output Reflection Ratio (dB)
Output Impedance (W)
10 M
Frequency (Hz)
Figure 4.
100
10
1
Filter Mode
Bypass Mode
0.1
0.01
100 k
1M
10 M
100 M
1G
VS = +3.3 V and +5 V
-10
-20
-30
-40
Filter Mode
-50
Bypass Mode
-60
-70
100 k
Frequency (Hz)
1M
10 M
100 M
1G
Frequency (Hz)
Figure 6.
12
35
Ambient Temperature (°C)
Figure 7.
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TYPICAL CHARACTERISTICS: +3.3 V and +5 V (continued)
CVBS CHANNEL DISABLED OUTPUT IMPEDANCE vs
FREQUENCY
HD CHANNELS DISABLED OUTPUT IMPEDANCE vs
FREQUENCY
100 k
10 k
VS = +3.3 V and +5 V
Disable Mode
Output Impedance (W)
Output Impedance (W)
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
10 k
1k
100
100 k
1M
10 M
100 M
VS = +3.3 V and +5 V
Disable Mode
1k
100
100 k
1G
1M
10 M
Figure 8.
TOTAL QUIESCENT CURRENT vs TEMPERATURE
17.5
VS = +3.3 V and +5 V
CVBS and HD Channels
No Load
17.3
Total Quiescent Current (mA)
Input Resistance (kW)
810
1G
Figure 9.
INPUT RESISTANCE vs TEMPERATURE
815
100 M
Frequency (Hz)
Frequency (Hz)
805
800
795
790
17.1
VS = +5 V
16.9
16.7
16.5
VS = +3.3 V
16.3
16.1
15.9
15.7
785
15.5
-40
-15
10
35
60
85
-40
10
-15
35
60
85
Ambient Temperature (°C)
Ambient Temperature (°C)
Figure 10.
Figure 11.
TOTAL QUIESCENT CURRENT vs SUPPLY VOLTAGE
17.50
Total Quiescent Current (mA)
RL = 150 W
17.25
17.00
16.75
16.50
16.25
16.00
15.75
15.50
3.0
3.5
4.0
4.5
5.0
Supply Voltage (V)
Figure 12.
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TYPICAL CHARACTERISTICS: 3.3 V, Standard-Definition (CVBS) Channels
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
10
VS = +3.3 V
DC-Coupled Output
Load = RL || 10 pF
VO = 0.2 VPP
Small-Signal Gain (dB)
0
-10
-20
-30
RL = 150 W
-40
CVBS CHANNEL SMALL-SIGNAL GAIN vs FREQUENCY
6.5
-50
1M
10 M
100 M
5.5
RL = 75 W
5.0
4.5
4.0
3.5
3.0
RL = 75 W
-60
100 k
RL = 150 W
6.0
Small-Signal Gain (dB)
CVBS CHANNEL SMALL-SIGNAL GAIN vs FREQUENCY
VS = +3.3 V
DC-Coupled Output
Load = RL || 10 pF
VO = 0.2 VPP
2.5
100 k
1G
1M
100 M
Figure 14.
CVBS CHANNEL LARGE-SIGNAL GAIN vs FREQUENCY
CVBS CHANNEL LARGE-SIGNAL GAIN vs FREQUENCY
10
6.5
0
6.0
-10
-20
VO = 0.2 VPP
-30
-40
VS = +3.3 V
DC-Coupled Output
Load = 150 W || 10 pF
-60
100 k
1M
Large-Signal Gain (dB)
Large-Signal Gain (dB)
Figure 13.
-50
100 M
VO = 0.2 VPP and 2 VPP
5.0
4.5
4.0
3.5
3.0
VO = 2 VPP
10 M
5.5
VS = +3.3 V
DC-Coupled Output
Load = 150 W || 10 pF
2.5
100 k
1G
1M
Figure 15.
45
0
0
-90
CL = 10 pF
CL = 5 pF
CL = 15 pF
-30
-50
-60
RL = 75 W and 150 W
-45
-10
-135
-180
-225
VS = +3.3 V
DC-Coupled Output
Load = 150 W || CL
VO = 0.2 VPP
1M
Phase (°)
Small-Signal Gain (dB)
CVBS CHANNEL PHASE vs FREQUENCY
10
-40
-270
-315
CL = 20 pF
10 M
100 M
Figure 16.
CVBS CHANNEL SMALL-SIGNAL GAIN vs FREQUENCY
-20
10 M
Frequency (Hz)
Frequency (Hz)
100 M
1G
VS = +3.3 V
DC-Coupled Output
Load = RL || 10 pF
VO = 0.2 VPP
-360
100 k
Frequency (Hz)
1M
10 M
100 M
Frequency (Hz)
Figure 17.
14
10 M
Frequency (Hz)
Frequency (Hz)
Figure 18.
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TYPICAL CHARACTERISTICS: 3.3 V, Standard-Definition (CVBS) Channels (continued)
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
CVBS CHANNEL GROUP DELAY vs FREQUENCY
120
100
Power-Supply Rejection Ratio (dB)
VS = +3.3 V
DC-Coupled Output
Load = RL || 10 pF
VO = 0.2 VPP
110
Group Delay (ns)
CVBS CHANNEL PSRR vs FREQUENCY
60
90
80
70
60
RL = 75 W and 150 W
50
40
100 k
1M
10 M
VS = +3.3 V
50
40
30
20
10
0
100 k
100 M
1M
Frequency (Hz)
10 M
100 M
Frequency (Hz)
Figure 19.
Figure 20.
CVBS CHANNEL DIFFERENTIAL GAIN
CVBS CHANNEL DIFFERENTIAL PHASE
0
0.40
VS = +3.3 V
0.35
Differential Phase (°)
Differential Gain (%)
-0.05
NTSC
-0.10
PAL
-0.15
0.30
PAL
0.25
NTSC
0.20
0.15
0.10
-0.20
0.05
VS = +3.3 V
0
-0.25
1st
2nd
3rd
4th
5th
1st
6th
2nd
3rd
4th
5th
6th
CVBS CHANNEL SECOND-ORDER HARMONIC DISTORTION vs
FREQUENCY
CVBS CHANNEL THIRD-ORDER HARMONIC DISTORTION vs
FREQUENCY
-30
VS = +3.3 V
DC-Coupled Output
RL = 150 W || 10 pF
-40
Third-Order Harmonic Distortion (dBc)
Figure 22.
Second-Order Harmonic Distortion (dBc)
Figure 21.
VO = 2.5 VPP
VO = 2 VPP
-50
-60
VO = 1.4 VPP
-70
VO = 1 VPP
-80
VO = 0.5 VPP
-90
-100
-30
VS = +3.3 V
DC-Coupled Output
RL = 150 W || 10 pF
-40
-50
VO = 2 VPP
VO = 2.5 VPP
-60
-70
VO = 1.4 VPP
-80
VO = 1 VPP
-90
VO = 0.5 VPP
-100
1
7
1
Frequency (MHz)
7
Frequency (MHz)
Figure 23.
Figure 24.
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TYPICAL CHARACTERISTICS: 3.3 V, Standard-Definition (CVBS) Channels (continued)
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
CVBS CHANNEL SMALL-SIGNAL PULSE RESPONSE vs TIME
0.65
3.6
0.55
Input
tR/tF = 120 ns
1.6
0.45
Output Voltage
Waveforms
1.5
Input Voltage (V)
1.7
4.6
Input
tR/tF = 1 ns
-0.35
Input
tR/tF = 120 ns
1.6
-0.6
-100
-3.35
100 200 300 400 500 600 700 800 900 1000
0
Time (ns)
Figure 25.
Figure 26.
CROSSTALK vs FREQUENCY
VS = +3.3 V
Filter Mode
Input-Referred
Worst-Case Crosstalk
-50
CROSSTALK vs FREQUENCY
-20
-30
HD In, HD Out
-40
Crosstalk (dB)
Crosstalk (dB)
-40
-60
-70
-80
VS = +3.3 V
Bypass Mode
Input-Referred
Worst-Case Crosstalk
-60
-70
-80
HD In, SD Out
-90
SD In, HD Out
-100
HD In, SD Out
SD In, HD Out
-100
10 M
1M
100 M
10 M
1M
1G
Figure 27.
CVBS CHANNEL DISABLE MODE RESPONSE vs TIME
2.4
VS = +3.3 V
DC-Coupled Output
Load = 150 W || 10 pF
4
2.1
2
VDISABLE
1.8
0
1.5
VOUT (V)
40
30
20
Positive and Negative Slew Rate
-2
1.2
VS = +3.3 V
0.9
-6
0.6
-8
0.3
10
-10
VOUT
0
-0.3
0
0.5
1.0
1.5
2.0
2.5
-4
VDISABLE (V)
Slew Rate (V/ms)
1G
Figure 28.
CVBS CHANNEL SLEW RATE vs OUTPUT VOLTAGE
-12
0
100
200
300
400
500
600
-14
Time (ns)
Output Voltage (VPP)
Figure 29.
16
100 M
Frequency (Hz)
Frequency (Hz)
50
HD In, HD Out
-50
-90
60
-2.35
Input
tR/tF = 1 ns
Time (ns)
-30
-1.35
Output Voltage
Waveforms
VS = +3.3 V
VS = +3.3 V
1.4
0.25
-100 0 100 200 300 400 500 600 700 800 900 1000
0.65
2.6
0.6
0.35
Input
tR/tF = 1 ns
1.65
Input
tR/tF = 120 ns
Input Voltage Waveforms
Input Voltage (V)
Input
tR/tF = 1 ns
1.8
Output Voltage (V)
Input
tR/tF = 120 ns
Input Voltage Waveforms
CVBS CHANNEL LARGE-SIGNAL PULSE RESPONSE vs TIME
0.75
Output Voltage (V)
1.9
Figure 30.
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TYPICAL CHARACTERISTICS: 3.3 V, Standard-Definition (CVBS) Channels (continued)
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
OUTPUT OFFSET VOLTAGE vs TEMPERATURE
Output Offset Voltage (mV)
315
310
VS = +3.3 V
Input = 0 V
305
CVBS Channel
300
HD Channels
295
290
285
-40
-15
10
35
60
85
Ambient Temperature (°C)
Figure 31.
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TYPICAL CHARACTERISTICS: 3.3 V, High-Definition (HD) Channels
With load = 150 Ω || 5 pF, dc-coupled input and output, unless otherwise noted.
HD CHANNELS SMALL-SIGNAL GAIN vs FREQUENCY
10
RL = 75 W
Filter Mode
-20
-30
-60
RL = 150 W
VS = +3.3 V
DC-Coupled Output
Load = RL || 5 pF
VO = 0.2 VPP
1M
6.5
6.0
5.5
RL = 75 W
100 M
3.0
2.5
1G
RL = 75 W
4.5
4.0
RL = 150 W
Filter Mode
5.0
3.5
10 M
Bypass
Mode
7.0
Small-Signal Gain (dB)
Small-Signal Gain (dB)
RL = 150 W
-10
-50
7.5
Bypass
Mode
0
-40
HD CHANNELS SMALL-SIGNAL GAIN vs FREQUENCY
VS = +3.3 V
DC-Coupled Output
Load = RL || 5 pF
VO = 0.2 VPP
RL = 150 W
10 M
1M
Frequency (Hz)
100 M
1G
Frequency (Hz)
Figure 32.
Figure 33.
HD CHANNELS LARGE-SIGNAL GAIN vs FREQUENCY
HD CHANNELS LARGE-SIGNAL GAIN vs FREQUENCY
10
Filter Mode
VO = 0.2 VPP
-20
VO = 2 VPP
-30
-40
VS = +3.3 V
DC-Coupled Output
Load = 150 W || 5 pF
VO = 2 VPP
-60
1M
10 M
VO = 1 VPP
6.5
5.5
VO = 0.2 VPP and 2 VPP
5.0
4.5
Filter Mode
4.0
VO = 2 VPP
VS = +3.3 V
DC-Coupled Output
Load = 150 W || 5 pF
3.5
2.5
1G
1M
10 M
Frequency (Hz)
100 M
1G
Frequency (Hz)
Figure 34.
Figure 35.
HD CHANNELS SMALL-SIGNAL GAIN vs FREQUENCY
HD CHANNELS SMALL-SIGNAL GAIN vs FREQUENCY
10
20
0
10
Small-Signal Gain (dB)
Small-Signal Gain (dB)
Bypass
Mode
6.0
3.0
VO = 0.2 VPP
100 M
VO = 0.2 VPP
7.0
Large-Signal Gain (dB)
Large-Signal Gain (dB)
VO = 1 VPP
-10
-50
7.5
Bypass
Mode
0
-10
-20
CL = 15 pF
CL = 5 pF
-30
-40
-50
VS = +3.3 V
Filter Mode
DC-Coupled Output
Load = 150 W || CL
VO = 0.2 VPP
-60
10 M
100 M
-10
1G
CL = 20 pF
-20
-30
-40
-50
CL = 20 pF
CL = 5 pF
0
CL = 15 pF
VS = +3.3 V
Bypass Mode
DC-Coupled Output
Load = 150 W || CL
VO = 0.2 VPP
-60
10 M
100 M
1G
Frequency (Hz)
Frequency (Hz)
Figure 36.
18
RL = 75 W
Figure 37.
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TYPICAL CHARACTERISTICS: 3.3 V, High-Definition (HD) Channels (continued)
With load = 150 Ω || 5 pF, dc-coupled input and output, unless otherwise noted.
HD CHANNELS PHASE vs FREQUENCY
VS = +3.3 V
Filter Mode
DC-Coupled Output
Load = RL || 5 pF
VO = 0.2 VPP
RL = 75 W and 150 W
0
35
Bypass Mode
-45
Group Delay (ns)
Filter Mode
-90
Phase (°)
HD CHANNELS GROUP DELAY vs FREQUENCY
40
45
RL = 75 W and 150 W
-135
-180
-225
VS = +3.3 V
DC-Coupled Output
Load = RL || 5 pF
VO = 0.2 VPP
-270
-315
-360
100 k
1M
30
25
20
RL = 75 W and 150 W
15
10
5
10 M
100 M
10 M
1M
1G
Figure 39.
HD CHANNELS PSRR vs FREQUENCY
HD CHANNELS SECOND-ORDER HARMONIC DISTORTION vs
FREQUENCY
Power-Supply Rejection Ratio (dB)
Second-Order Harmonic Distortion (dBc)
Figure 38.
60
VS = +3.3 V
50
40
30
20
10
0
100 k
100 M
Frequency (Hz)
Frequency (Hz)
1M
10 M
-30
VS = +3.3 V
Filter Bypass
DC-Coupled Output
RL = 150 W || 5 pF
-40
-50
VO = 2.5 VPP
VO = 2 VPP
-60
VO = 1.4 VPP
-70
-80
VO = 0.5 VPP
-90
VO = 1 VPP
-100
1
100 M
10
60
Frequency (MHz)
Frequency (Hz)
HD CHANNELS THIRD-ORDER HARMONIC DISTORTION vs
FREQUENCY
HD CHANNELS SECOND-ORDER HARMONIC DISTORTION vs
FREQUENCY
-30
VS = +3.3 V
Filter Bypass
DC-Coupled Output
RL = 150 W || 5 pF
-40
-50
Second-Order Harmonic Distortion (dBc)
Figure 41.
Third-Order Harmonic Distortion (dBc)
Figure 40.
VO = 2.5 VPP
VO = 2 VPP
-60
VO = 1.4 VPP
-70
VO = 1 VPP
-80
-90
VO = 0.5 VPP
-100
1
10
60
-30
VS = +3.3 V
DC-Coupled Output
RL = 150 W || 5 pF
-40
VO = 2.5 VPP
VO = 2 VPP
-50
-60
VO = 1.4 VPP
-70
VO = 1 VPP
-80
VO = 0.5 VPP
-90
-100
1
Frequency (MHz)
10
30
Frequency (MHz)
Figure 42.
Figure 43.
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TYPICAL CHARACTERISTICS: 3.3 V, High-Definition (HD) Channels (continued)
With load = 150 Ω || 5 pF, dc-coupled input and output, unless otherwise noted.
HD CHANNELS THIRD-ORDER HARMONIC DISTORTION vs
FREQUENCY
1.9
VS = +3.3 V
DC-Coupled Output
RL = 150 W || 5 pF
-50
VO = 2 VPP
-60
VO = 1.4 VPP
-70
-80
VO = 0.5 VPP
-90
Input
tR/tF = 1 ns
1.7
0.55
Input
tR/tF = 1 ns
Input
tR/tF = 33.6 ns
1.6
0.45
Output Voltage
Waveforms
0.35
VS = +3.3 V
Filter Mode
10
30
0.25
0
-50
50
Figure 44.
0.65
1.8
-0.35
Input
tR/tF = 33.6 ns
1.6
-1.35
Output Voltage
Waveforms
0.6
-2.35
50
100
150
250
200
0.75
Input
tR/tF = 1 ns
Input Voltage
Waveform
1.7
0.55
1.6
0.45
Output Voltage
Waveform
0.35
VS = +3.3 V
Bypass Mode
-3.35
1.4
0.25
0
-50
50
100
150
Time (ns)
Time (ns)
Figure 46.
Figure 47.
HD CHANNELS LARGE-SIGNAL PULSE RESPONSE vs TIME
4.6
600
0.65
500
-0.35
1.6
-1.35
Output Voltage
Waveform
0.6
Slew Rate (V/ms)
2.6
Input Voltage (V)
Output Voltage (V)
Input Voltage
Waveform
-0.6
-50
0
Negative Slew Rate
VS = +3.3 V
DC-Coupled Output
Load = 150 W || 5 pF
Positive Slew Rate
300
200
Positive and Negative Slew Rate
100
50
100
150
Time (ns)
200
250
-3.35
Filter Mode
0
0.5
1.0
1.5
2.0
2.5
Output Voltage (VPP)
Figure 48.
20
250
400
-2.35
VS = +3.3 V
Bypass Mode
200
HD CHANNELS SLEW RATE vs OUTPUT VOLTAGE
1.65
Bypass Mode
Input
tR/tF = 1 ns
3.6
0.65
1.5
VS = +3.3 V
Filter Mode
0
250
Input Voltage (V)
Input
tR/tF = 1 ns
1.9
Input Voltage (V)
Output Voltage (V)
Input
tR/tF = 33.6 ns
Input
tR/tF = 1 ns
-50
200
HD CHANNELS SMALL-SIGNAL PULSE RESPONSE vs TIME
1.65
Output Voltage (V)
Input Voltage Waveforms
-0.6
150
Figure 45.
HD CHANNELS LARGE-SIGNAL PULSE RESPONSE vs TIME
2.6
100
Time (ns)
Frequency (MHz)
3.6
0.65
1.4
1
4.6
0.75
Input
tR/tF = 33.6 ns
1.5
VO = 1 VPP
-100
Input Voltage Waveforms
1.8
VO = 2.5 VPP
Output Voltage (V)
-40
HD CHANNELS SMALL-SIGNAL PULSE RESPONSE vs TIME
Input Voltage (V)
Third-Order Harmonic Distortion (dBc)
-30
Figure 49.
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TYPICAL CHARACTERISTICS: 3.3 V, High-Definition (HD) Channels (continued)
With load = 150 Ω || 5 pF, dc-coupled input and output, unless otherwise noted.
HD CHANNELS BYPASS MODE RESPONSE vs TIME
1.6
1.4
VBYPASS
2.4
2
2.1
VOUT
0.8
-4
0.6
-6
0.4
-8
VS = +3.3 V
fIN = 50 MHz
0.2
0
0
50
100
150
200
250
0
1.5
VOUT (V)
-2
2
VDISABLE
-2
VS = +3.3 V
Bypass Mode
1.2
-4
0.9
-6
0.6
-8
VOUT
0.3
-10
-10
0
-12
-12
-0.3
300
100
0
200
VDISABLE (V)
1.0
4
1.8
0
VBYPASS (V)
VOUT (V)
1.2
HD CHANNELS DISABLE MODE RESPONSE vs TIME
4
300
Time (ns)
Time (ns)
Figure 50.
Figure 51.
400
500
600
-14
HD CHANNELS DISABLE MODE RESPONSE vs TIME
2.4
4
2.1
2
VDISABLE
1.8
0
VOUT (V)
-2
VS = +3.3 V
Filter Mode
1.2
-4
0.9
-6
0.6
-8
0.3
-10
VOUT
0
-0.3
VDISABLE (V)
1.5
-12
0
100
200
300
400
500
600
-14
Time (ns)
Figure 52.
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TYPICAL CHARACTERISTICS: 5 V, Standard-Definition (CVBS) Channels
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
CVBS CHANNEL SMALL-SIGNAL GAIN vs FREQUENCY
VS = +5 V
DC-Coupled Output
Load = RL || 10 pF
VO = 0.2 VPP
Small-Signal Gain (dB)
0
-10
-20
-30
RL = 150 W
-40
CVBS CHANNEL SMALL-SIGNAL GAIN vs FREQUENCY
6.5
-50
1M
10 M
100 M
5.5
RL = 75 W
5.0
4.5
4.0
3.5
3.0
RL = 75 W
-60
100 k
RL = 150 W
6.0
Small-Signal Gain (dB)
10
VS = +5 V
DC-Coupled Output
Load = RL || 10 pF
VO = 0.2 VPP
2.5
100 k
1G
1M
100 M
Figure 54.
CVBS CHANNEL LARGE-SIGNAL GAIN vs FREQUENCY
CVBS CHANNEL LARGE-SIGNAL GAIN vs FREQUENCY
10
6.5
0
6.0
-10
-20
VO = 0.2 VPP
-30
-40
VS = +5 V
DC-Coupled Output
Load = 150 W || 10 pF
-60
100 k
1M
Large-Signal Gain (dB)
Large-Signal Gain (dB)
Figure 53.
-50
100 M
VO = 0.2 VPP and 2 VPP
5.0
4.5
4.0
3.5
3.0
VO = 2 VPP
10 M
5.5
VS = +5 V
DC-Coupled Output
Load = 150 W || 10 pF
2.5
100 k
1G
1M
Figure 55.
45
0
0
-90
CL = 10 pF
CL = 15 pF
CL = 5 pF
-30
-50
-60
RL = 75 W and 150 W
-45
-10
-135
-180
-225
VS = +5 V
DC-Coupled Output
Load = 150 W || CL
VO = 0.2 VPP
1M
Phase (°)
Small-Signal Gain (dB)
CVBS CHANNEL PHASE vs FREQUENCY
10
-20
-270
-315
CL = 20 pF
10 M
100 M
Figure 56.
CVBS CHANNEL SMALL-SIGNAL GAIN vs FREQUENCY
-40
10 M
Frequency (Hz)
Frequency (Hz)
100 M
1G
VS = +5 V
DC-Coupled Output
Load = RL || 10 pF
VO = 0.2 VPP
-360
100 k
Frequency (Hz)
1M
10 M
100 M
Frequency (Hz)
Figure 57.
22
10 M
Frequency (Hz)
Frequency (Hz)
Figure 58.
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TYPICAL CHARACTERISTICS: 5 V, Standard-Definition (CVBS) Channels (continued)
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
CVBS CHANNEL GROUP DELAY vs FREQUENCY
120
100
Power-Supply Rejection Ratio (dB)
VS = +5 V
DC-Coupled Output
Load = RL || 10 pF
VO = 0.2 VPP
110
Group Delay (ns)
CVBS CHANNEL PSRR vs FREQUENCY
60
90
80
70
60
RL = 75 W and 150 W
50
40
100 k
1M
10 M
VS = +5 V
50
40
30
20
10
0
100 k
100 M
1M
Frequency (Hz)
10 M
100 M
Frequency (Hz)
Figure 59.
Figure 60.
CVBS CHANNEL DIFFERENTIAL GAIN
CVBS CHANNEL DIFFERENTIAL PHASE
0
0.40
VS = +5 V
0.35
Differential Phase (°)
Differential Gain (%)
-0.05
NTSC
-0.10
PAL
-0.15
0.30
PAL
0.25
0.20
NTSC
0.15
0.10
-0.20
0.05
VS = +5 V
0
-0.25
1st
2nd
3rd
4th
5th
1st
6th
2nd
3rd
4th
5th
6th
CVBS CHANNEL SECOND-ORDER HARMONIC DISTORTION vs
FREQUENCY
CVBS CHANNEL THIRD-ORDER HARMONIC DISTORTION vs
FREQUENCY
-30
VS = +5 V
DC-Coupled Output
RL = 150 W || 10 pF
-40
Third-Order Harmonic Distortion (dBc)
Figure 62.
Second-Order Harmonic Distortion (dBc)
Figure 61.
VO = 2 VPP
VO = 3 VPP
-50
-60
VO = 1.4 VPP
-70
VO = 1 VPP
-80
VO = 0.5 VPP
-90
-100
-30
VS = +5 V
DC-Coupled Output
RL = 150 W || 10 pF
-40
-50
-60
-80
-90
VO = 1 VPP
-100
1
7
VO = 3 VPP
VO = 2 VPP
-70
VO = 1.4 VPP
1
Frequency (MHz)
7
Frequency (MHz)
Figure 63.
Figure 64.
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TYPICAL CHARACTERISTICS: 5 V, Standard-Definition (CVBS) Channels (continued)
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
CVBS CHANNEL SMALL-SIGNAL PUSLE RESPONSE vs TIME
0.65
3.6
0.55
Input
tR/tF = 120 ns
1.6
0.45
Output Voltage
Waveforms
1.5
Input Voltage (V)
1.7
4.6
Input
tR/tF = 1 ns
-0.35
Input
tR/tF = 120 ns
1.6
-0.6
-100
-3.35
100 200 300 400 500 600 700 800 900 1000
0
Time (ns)
Figure 65.
Figure 66.
CROSSTALK vs FREQUENCY
VS = +5 V
Filter Mode
Input-Referred
Worst-Case Crosstalk
-50
CROSSTALK vs FREQUENCY
-20
-30
HD In, HD Out
-40
Crosstalk (dB)
Crosstalk (dB)
-40
-60
-70
-80
VS = +5 V
Bypass Mode
Input-Referred
Worst-Case Crosstalk
-60
-70
-80
HD In, SD Out
-90
SD In, HD Out
-100
HD In, SD Out
SD In, HD Out
-100
10 M
1M
100 M
10 M
1M
1G
Figure 67.
4
2.1
2
VDISABLE
1.8
0
1.5
VOUT (V)
40
30
VS = +5 V
-4
0.9
-6
0.6
20
Positive and Negative Slew Rate
10
1.0
1.5
2.0
2.5
-8
VOUT
0.3
-10
0
-12
-0.3
0
-2
1.2
0
100
200
300
400
500
VDISABLE (V)
Slew Rate (V/ms)
CVBS CHANNEL DISABLE MODE RESPONSE vs TIME
2.4
VS = +5 V
DC-Coupled Output
Load = 150 W || 10 pF
0.5
1G
Figure 68.
CVBS CHANNEL SLEW RATE vs OUTPUT VOLTAGE
600
-14
Time (ns)
Output Voltage (VPP)
Figure 69.
24
100 M
Frequency (Hz)
Frequency (Hz)
50
HD In, HD Out
-50
-90
60
-2.35
Input
tR/tF = 1 ns
Time (ns)
-30
-1.35
Output Voltage
Waveforms
VS = +5 V
VS = +5 V
1.4
0.25
-100 0 100 200 300 400 500 600 700 800 900 1000
0.65
2.6
0.6
0.35
Input
tR/tF = 1 ns
1.65
Input
tR/tF = 120 ns
Input Voltage Waveforms
Input Voltage (V)
Input
tR/tF = 1 ns
1.8
Output Voltage (V)
Input
tR/tF = 120 ns
Input Voltage Waveforms
CVBS CHANNEL LARGE-SIGNAL PUSLE RESPONSE vs TIME
0.75
Output Voltage (V)
1.9
Figure 70.
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SBOS506 – DECEMBER 2009
TYPICAL CHARACTERISTICS: 5 V, Standard-Definition (CVBS) Channels (continued)
With load = 150 Ω || 10 pF, dc-coupled input and output, unless otherwise noted.
CVBS CHANNEL ATTENUATION AT 6.75 MHz vs
TEMPERATURE
CVBS CHANNEL ATTENUATION AT 27 MHz vs TEMPERATURE
57
0.8
VS = +5 V
Relative to 500 kHz
Attenuation at 27 MHz (dB)
Attenuation at 6.75 MHz (dB)
1.0
0.6
0.4
0.2
0
-0.2
56
VS = +5 V
Relative to 500 kHz
55
54
53
52
51
-0.4
-40
-15
10
35
60
85
-40
10
-15
35
60
85
Ambient Temperature (°C)
Ambient Temperature (°C)
Figure 71.
Figure 72.
OUTPUT OFFSET VOLTAGE vs TEMPERATURE
Output Offset Voltage (mV)
315
310
VS = +5 V
Input = 0 V
305
CVBS Channel
300
HD Channels
295
290
285
-40
-15
10
35
60
85
Ambient Temperature (°C)
Figure 73.
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TYPICAL CHARACTERISTICS: 5 V, High-Definition (HD) Channels
With load = 150 Ω || 5 pF, dc-coupled input and output, unless otherwise noted.
HD CHANNELS SMALL-SIGNAL GAIN vs FREQUENCY
10
RL = 75 W
Filter Mode
-20
-30
-60
RL = 150 W
VS = +5 V
DC-Coupled Output
Load = RL || 5 pF
VO = 0.2 VPP
1M
6.5
6.0
5.5
RL = 75 W
100 M
3.0
2.5
1G
RL = 75 W
4.5
4.0
RL = 150 W
Filter Mode
5.0
3.5
10 M
Bypass
Mode
7.0
Small-Signal Gain (dB)
Small-Signal Gain (dB)
RL = 150 W
-10
-50
7.5
Bypass
Mode
0
-40
HD CHANNELS SMALL-SIGNAL GAIN vs FREQUENCY
VS = +5 V
DC-Coupled Output
Load = RL || 5 pF
VO = 0.2 VPP
RL = 150 W
10 M
1M
Frequency (Hz)
100 M
1G
Frequency (Hz)
Figure 74.
Figure 75.
HD CHANNELS LARGE-SIGNAL GAIN vs FREQUENCY
HD CHANNELS LARGE-SIGNAL GAIN vs FREQUENCY
10
Filter Mode
VO = 0.2 VPP
-20
VO = 2 VPP
-30
-40
VS = +5 V
DC-Coupled Output
Load = 150 W || 5 pF
VO = 2 VPP
-60
1M
10 M
VO = 1 VPP
6.5
5.5
VO = 0.2 VPP and 2 VPP
5.0
4.5
Filter Mode
4.0
VO = 2 VPP
VS = +5 V
DC-Coupled Output
Load = 150 W || 5 pF
3.5
2.5
1G
1M
10 M
Frequency (Hz)
100 M
1G
Frequency (Hz)
Figure 76.
Figure 77.
HD CHANNELS SMALL-SIGNAL GAIN vs FREQUENCY
HD CHANNELS SMALL-SIGNAL GAIN vs FREQUENCY
10
20
0
10
Small-Signal Gain (dB)
Small-Signal Gain (dB)
Bypass
Mode
6.0
3.0
VO = 0.2 VPP
100 M
VO = 0.2 VPP
7.0
Large-Signal Gain (dB)
Large-Signal Gain (dB)
VO = 1 VPP
-10
-50
7.5
Bypass
Mode
0
-10
-20
CL = 15 pF
CL = 5 pF
-30
-40
-50
VS = +5 V
Filter Mode
DC-Coupled Output
Load = 150 W || CL
VO = 0.2 VPP
-60
10 M
100 M
-10
1G
CL = 20 pF
-20
-30
-40
-50
CL = 20 pF
CL = 5 pF
0
CL = 15 pF
VS = +5 V
Bypass Mode
DC-Coupled Output
Load = 150 W || CL
VO = 0.2 VPP
-60
10 M
100 M
1G
Frequency (Hz)
Frequency (Hz)
Figure 78.
26
RL = 75 W
Figure 79.
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TYPICAL CHARACTERISTICS: 5 V, High-Definition (HD) Channels (continued)
With load = 150 Ω || 5 pF, dc-coupled input and output, unless otherwise noted.
HD CHANNELS PHASE vs FREQUENCY
VS = +5 V
Filter Mode
DC-Coupled Output
Load = RL || 5 pF
VO = 0.2 VPP
RL = 75 W and 150 W
0
35
Bypass Mode
-45
Group Delay (ns)
Filter Mode
-90
Phase (°)
HD CHANNELS GROUP DELAY vs FREQUENCY
40
45
RL = 75 W and 150 W
-135
-180
-225
VS = +5 V
DC-Coupled Output
Load = RL || 5 pF
VO = 0.2 VPP
-270
-315
-360
100 k
1M
30
25
20
RL = 75 W and 150 W
15
10
5
10 M
100 M
10 M
1M
1G
Figure 81.
HD CHANNELS PSRR vs FREQUENCY
HD CHANNELS SECOND-ORDER HARMONIC DISTORTION vs
FREQUENCY
Second-Order Harmonic Distortion (dBc)
Figure 80.
60
Power-Supply Rejection Ratio (dB)
100 M
Frequency (Hz)
Frequency (Hz)
VS = +5 V
50
40
30
20
10
0
100 k
1M
10 M
-30
VS = +5 V
Filter Bypass
DC-Coupled Output
RL = 150 W || 5 pF
-40
-50
VO = 3 VPP
VO = 2 VPP
VO = 1.4 VPP
-60
-70
VO = 1 VPP
-80
VO = 0.5 VPP
-90
-100
1
100 M
10
60
Frequency (MHz)
Frequency (Hz)
HD CHANNELS THIRD-ORDER HARMONIC DISTORTION vs
FREQUENCY
HD CHANNELS SECOND-ORDER HARMONIC DISTORTION vs
FREQUENCY
-30
VS = +5 V
Filter Bypass
DC-Coupled Output
RL = 150 W || 5 pF
-40
-50
VO = 1.4 VPP
VO = 3 VPP
-60
-70
VO = 1 VPP
-80
VO = 2 VPP
-90
VO = 0.5 VPP
-100
1
10
60
Second-Order Harmonic Distortion (dBc)
Figure 83.
Third-Order Harmonic Distortion (dBc)
Figure 82.
-30
VS = +5 V
DC-Coupled Output
RL = 150 W || 5 pF
-40
VO = 3 VPP
VO = 2 VPP
-50
-60
VO = 1.4 VPP
-70
VO = 1 VPP
-80
VO = 0.5 VPP
-90
-100
1
Frequency (MHz)
10
30
Frequency (MHz)
Figure 84.
Figure 85.
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TYPICAL CHARACTERISTICS: 5 V, High-Definition (HD) Channels (continued)
With load = 150 Ω || 5 pF, dc-coupled input and output, unless otherwise noted.
HD CHANNELS THIRD-ORDER HARMONIC DISTORTION vs
FREQUENCY
HD CHANNELS SMALL-SIGNAL PULSE RESPONSE vs TIME
1.9
VS = +5 V
DC-Coupled Output
RL = 150 W || 5 pF
-50
VO = 1.4 VPP
-60
VO = 0.5 VPP VO = 1 VPP
VO = 3 VPP
VO = 2 VPP
-70
-80
1.7
0.55
Input
tR/tF = 1 ns
Input
tR/tF = 33.6 ns
0.45
Output Voltage
Waveforms
1.5
0.35
VS = +5 V
Filter Mode
1.4
1
10
30
0.25
0
-50
50
Figure 86.
Input
tR/tF = 33.6 ns
Input
tR/tF = 1 ns
0.65
1.8
-0.35
Input
tR/tF = 33.6 ns
1.6
-1.35
Output Voltage
Waveforms
0.6
-2.35
-50
0
50
100
150
250
200
Input
tR/tF = 1 ns
Input Voltage
Waveform
1.7
0.55
1.6
0.45
Output Voltage
Waveform
0.35
VS = +5 V
Bypass Mode
-3.35
1.4
0.25
0
-50
50
100
150
Time (ns)
Time (ns)
Figure 88.
Figure 89.
HD CHANNELS LARGE-SIGNAL PULSE RESPONSE vs TIME
4.6
600
0.65
500
-0.35
1.6
-1.35
Output Voltage
Waveform
0.6
Slew Rate (V/ms)
2.6
Input Voltage (V)
Output Voltage (V)
Input Voltage
Waveform
Negative Slew Rate
Positive Slew Rate
400
300
VS = +5 V
DC-Coupled Output
Load = 150 W || 5 pF
200
Filter Mode
-2.35
VS = +5 V
Bypass Mode
-0.6
-50
0
250
200
HD CHANNELS SLEW RATE vs OUTPUT VOLTAGE
1.65
Bypass Mode
Input
tR/tF = 1 ns
3.6
0.65
1.5
VS = +5 V
Filter Mode
-0.6
0.75
Input Voltage (V)
Input
tR/tF = 1 ns
1.9
Input Voltage (V)
2.6
250
200
HD CHANNELS SMALL-SIGNAL PULSE RESPONSE vs TIME
1.65
Output Voltage (V)
Input Voltage Waveforms
3.6
150
Figure 87.
HD CHANNELS LARGE-SIGNAL PULSE RESPONSE vs TIME
4.6
100
Time (ns)
Frequency (MHz)
Output Voltage (V)
0.65
1.6
-90
-100
100
50
100
150
Time (ns)
200
250
-3.35
Positive and Negative Slew Rate
0
0.5
1.0
1.5
2.0
2.5
Output Voltage (VPP)
Figure 90.
28
0.75
Input
tR/tF = 33.6 ns
Input
tR/tF = 1 ns
1.8
Output Voltage (V)
-40
Input Voltage Waveforms
Input Voltage (V)
Third-Order Harmonic Distortion (dBc)
-30
Figure 91.
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TYPICAL CHARACTERISTICS: 5 V, High-Definition (HD) Channels (continued)
With load = 150 Ω || 5 pF, dc-coupled input and output, unless otherwise noted.
HD CHANNELS BYPASS MODE RESPONSE vs TIME
1.4
VBYPASS
2
2.1
0
1.8
-2
VOUT
0.8
-4
0.6
-6
0.4
-8
VS = +5 V
fIN = 50 MHz
0.2
0
0
50
100
150
200
250
1.2
-6
-10
0
-12
-12
-0.3
200
300
Time (ns)
-6
0.6
-8
VOUT
Attenuation at 27 MHz (dB)
-4
VDISABLE (V)
-2
0.9
0.4
-0.4
-12
-0.6
-14
-0.8
600
VS = +5 V
Relative to 500 kHz
-0.2
0
500
-14
0
-10
400
600
0.2
0.3
300
500
0.6
0
1.2
400
HD CHANNELS ATTENUATION AT 27 MHz vs TEMPERATURE
2
VS = +5 V
Filter Mode
200
100
0
Figure 93.
1.5
100
-8
VOUT
-10
4
0
-4
0.9
Time (ns)
1.8
-0.3
-2
VS = +5 V
Bypass Mode
0.3
HD CHANNEL DISABLE MODE RESPONSE vs TIME
VOUT (V)
0
1.5
Figure 92.
VDISABLE
2
VDISABLE
0.6
300
2.4
2.1
4
VDISABLE (V)
1.0
2.4
VBYPASS (V)
VOUT (V)
1.2
HD CHANNELS DISABLE MODE RESPONSE vs TIME
4
VOUT (V)
1.6
-40
10
-15
Time (ns)
35
60
85
Ambient Temperature (°C)
Figure 94.
Figure 95.
HD CHANNELS ATTENUATION AT 74 MHz vs TEMPERATURE
43
Attenuation at 74 MHz (dB)
42
VS = +5 V
Relative to 500 kHz
41
40
39
38
37
36
35
-40
-15
10
35
60
85
Ambient Temperature (°C)
Figure 96.
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APPLICATION INFORMATION
The THS7373 is targeted for systems that require a
single standard-definition (CVBS) video output for
CVBS video support along with three high-definition
(HD) video outputs. Although it can be used for
numerous other applications, the needs and
requirements of the video signal are the most
important design parameters of the THS7373. Built
on the revolutionary, complementary Silicon
Germanium (SiGe) BiCom3X process, the THS7373
incorporates many features not typically found in
integrated video parts while consuming very low
power. The THS7373 includes the following features:
• Single-supply 3-V to 5-V operation with low total
quiescent current of 16.2 mA at 3.3 V and 16.9
mA at 5 V
• Disable mode allows for shutting down the
THS7373
to
save
system
power
in
power-sensitive applications
• Input configuration accepting dc + level shift, ac
sync-tip clamp, or ac-bias:
– Reduces quiescent current to as low as 0.1 µA
• Flexible input configurations allows for dc + level
shift, ac sync-tip clamp, or ac-biasing:
– AC-biasing is configured by use of an external
pull-up resistor to the positive power supply
• Sixth-order, low-pass filter for DAC reconstruction
or ADC image rejection:
– 9.5 MHz for NTSC, PAL, or SECAM composite
video baseband signal (CVBS)
– 36 MHz for 720p, 1080i, or up to 1080p30
Y’/P’B/P’R or G’B’R’ signals
• HD bypass mode bypasses the HD low-pass
filters for all three channels:
– HD channels can support 1080p60 or QXGA
video
with
350-MHz
and
450-V/µs
performance
• Internal fixed gain of 2 V/V (+6 dB)
• Supports driving two video lines per channel with
dc-coupling or traditional ac-coupling
• Flow-through configuration using a TSSOP-14
package that complies with the latest lead-free
(RoHS-compatible) and green manufacturing
requirements
coefficient capacitors. The design of the THS7373
allows operation down to 2.6 V, but it is
recommended to use at least a 3-V supply to ensure
that no issues arise with headroom or clipping with
100% color-saturated CVBS signals.
A 0.1-μF capacitor should be placed as close as
possible to the power-supply pins to avoid potential
ringing or oscillations. Additionally, a large capacitor
(such as 22 μF to 100 μF) should be placed on the
power-supply line to minimize interference with
50-/60-Hz line frequencies.
INPUT VOLTAGE
The THS7373 input range allows for an input signal
range from –0.4 V to approximately (VS+ – 1.5 V).
However, because of the internal fixed gain of 2 V/V
(+6 dB) and the internal output level shift of 300 mV,
the output is generally the limiting factor for the
allowable linear input range. For example, with a 5-V
supply, the linear input range is from –0.4 V to 3.5 V.
However, because of the gain and level shift, the
linear output range limits the allowable linear input
range to approximately –0.1 V to 2.3 V.
INPUT OVERVOLTAGE PROTECTION
The THS7373 is built using a very high-speed,
complementary, bipolar, and CMOS process. The
internal junction breakdown voltages are relatively
low for these very small geometry devices. These
breakdowns are reflected in the Absolute Maximum
Ratings table. All input and output device pins are
protected with internal ESD protection diodes to the
power supplies, as shown in Figure 97.
These diodes provide moderate protection to input
overdrive voltages above and below the supplies as
well. The protection diodes can typically support
30 mA of continuous current when overdriven.
+VS
External
Input/Output
Pin
Internal
Circuitry
OPERATING VOLTAGE
The THS7373 is designed to operate from 3 V to 5 V
over the –40°C to +85°C temperature range. The
impact on performance over the entire temperature
range is negligible as a result of the implementation
of thin film resistors and high-quality, low-temperature
30
Figure 97. Internal ESD Protection
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TYPICAL CONFIGURATION AND VIDEO
TERMINOLOGY
A typical application circuit using the THS7373 as a
video buffer is shown in Figure 98. It shows a DAC or
encoder driving the input channels of the THS7373.
One channel is a CVBS connection using the
standard definition (CVBS) video filters. This signal
can be an NTSC, PAL, or SECAM video signal. The
other three channels are the component video
Y’/P’B/P’R (sometimes labeled Y’U’V’ or incorrectly
labeled Y’/C’B/C’R) video signals. These signals are
typically 720p, 1080i, or up to 1080p30 signals. If the
video DAC samples at greater than 74.25 MHz, then
480i/576i or 480p/576p signals are also supported
while effectively minimizing DAC images. Because
the HD filters can be bypassed, other formats such as
1080p60 (also known as Full-HD or True-HD) or
computer R'G'B' resolutions up to QXGA can also be
supported with the THS7373.
Note that the Y’ term is used for the luma channels
throughout this document rather than the more
common luminance (Y) term. This usage accounts for
the definition of luminance as stipulated by the
International Commission on Illumination (CIE). Video
departs from true luminance because a nonlinear
term, gamma, is added to the true RGB signals to
form R’G’B’ signals. These R’G’B’ signals are then
used to mathematically create luma (Y’). Thus,
luminance (Y) is not maintained, providing a
difference in terminology.
This rationale is also used for the chroma (C’) term.
Chroma is derived from the nonlinear R’G’B’ terms
and, thus, it is nonlinear. Chominance (C) is derived
from linear RGB, giving the difference between
chroma (C’) and chrominance (C). The color
difference signals (P’B/P’R/U’/V’) are also referenced
in this manner to denote the nonlinear (gamma
corrected) signals.
THS7373
CVBS Out
75 W
CVBS
SOC/Encoder/DAC
R
CVBS OUT 14
1
CVBS IN
2
HD CH1 IN
HD CH1 OUT 13
3
HD CH2 IN
HD CH2 OUT 12
75 W
Y' Out
75 W
Y'/G'
R
P’B/B'
4
HD CH3 IN
5
GND
6
DISABLE
7
NC
HD CH3 OUT 11
75 W
VS+ 10
HD BYPASS
9
NC
8
75 W
P'B Out
R
P’R/R'
R
75 W
75 W
To GPIO Controller
or GND
P'R Out
75 W
+3 V to +5 V
Figure 98. Typical Four-Channel System Inputs from DC-Coupled Encoder/DAC
with DC-Coupled Line Driving
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R’G’B’ (commonly mislabeled RGB) is also called
G’B’R’ (again commonly mislabeled as GBR) in
professional video systems. The Society of Motion
Picture
and
Television
Engineers
(SMPTE)
component standard stipulates that the luma
information is placed on the first channel, the blue
color difference is placed on the second channel, and
the red color difference signal is placed on the third
channel. This practice is consistent with the Y'/P'B/P'R
nomenclature. Because the luma channel (Y') carries
the sync information and the green channel (G') also
carries the sync information, it makes logical sense
that G' be placed first in the system. Because the
blue color difference channel (P'B) is next and the red
color difference channel (P'R) is last, then it also
makes logical sense to place the B' signal on the
second channel and the R' signal on the third
channel, respectfully. Thus, hardware compatibility is
better achieved when using G'B'R' rather than R'G'B'.
Note that for many G'B'R' systems, sync is embedded
on all three channels, but this configuration may not
always be the case in all systems.
INPUT MODE OF OPERATION: DC
The inputs to the THS7373 allow for both ac- and
dc-coupled inputs. Many DACs or video encoders can
be dc-connected to the THS7373. One of the
drawbacks to dc-coupling is when 0 V is applied to
the input. Although the input of the THS7373 allows
for a 0-V input signal without issue, the output swing
of a traditional amplifier cannot yield a 0-V signal,
resulting in possible clipping. This limitation is true for
any single-supply amplifier because of the
characteristics of the output transistors. Neither
CMOS nor bipolar transistors can achieve 0 V while
sinking current. This transistor characteristic is also
the same reason why the highest output voltage is
always less than the power-supply voltage when
sourcing current.
This output clipping can reduce the sync amplitudes
(both horizontal and vertical sync) on the video
signal. A problem occurs if the video signal receiver
uses an automatic gain control (AGC) loop to account
for losses in the transmission line. Some video AGC
circuits derive gain from the horizontal sync
amplitude. If clipping occurs on the sync amplitude,
then the AGC circuit can increase the gain too
much—resulting in too much luma and/or chroma
amplitude gain correction. This correction may result
in a picture with an overly bright display with too
much color saturation.
32
Other AGC circuits use the chroma burst amplitude
for amplitude control; reduction in the sync signals
does not alter the proper gain setting. However, it is
good engineering design practice to ensure that
saturation/clipping does not take place. Transistors
always take a finite amount of time to come out of
saturation. This saturation could possibly result in
timing delays or other aberrations in the signals.
To eliminate saturation or clipping problems, the
THS7373 has a 150-mV input level shift feature. This
feature takes the input voltage and adds an internal
+150-mV shift to the signal. Because the THS7373
also has a gain of 6 dB (2 V/V), the resulting output
with a 0-V applied input signal is approximately 300
mV. The THS7373 rail-to-rail output stage can create
this output level while connected to a typical video
load. This configuration ensures that no saturation or
clipping of the sync signals occur. This shift is
constant, regardless of the input signal. For example,
if a 1-V input is applied, the output is 2.3 V.
Because the internal gain is fixed at +6 dB, the gain
dictates what the allowable linear input voltage range
can be without clipping concerns. For example, if the
power supply is set to 3 V, the maximum output is
approximately 2.9 V while driving a significant amount
of current. Thus, to avoid clipping, the allowable input
is ([2.9 V – 0.3 V]/2) = 1.3 V. This range is valid for
up to the maximum recommended 5-V power supply
that allows approximately a ([4.9 V – 0.3 V]/2) = 2.3 V
input range while avoiding clipping on the output.
The input impedance of the THS7373 in this mode of
operation is dictated by the internal, 800-kΩ
pull-down resistor, as shown in Figure 99. Note that
the internal voltage shift does not appear at the input
pin; it only shows at the output pin.
+VS
Internal
Circuitry
Input
Pin
800 kW
Level
Shift
Figure 99. Equivalent DC Input Mode Circuit
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INPUT MODE OF OPERATION: AC SYNC TIP
CLAMP (STC)
Some video DACs or encoders are not referenced to
ground but rather to the positive power supply. The
resulting video signals are generally at too great a
voltage for a dc-coupled video buffer to function
properly. In other systems, the inputs may be
connecting to an unknown source with unknown dc
reference levels. To account for this scenario, the
THS7373 incorporates a sync-tip clamp circuit. This
function requires a capacitor (nominally 0.1 μF) to be
in series with the input pin. Although the term
sync-tip-clamp is used throughout this document, it
should be noted that the THS7373 would probably be
better termed as a dc restoration circuit based on
how this function is performed. This circuit is an
active clamp circuit and not a passive diode clamp
function.
The input to the THS7373 has an internal control loop
that sets the lowest input applied voltage to clamp at
ground (0 V). By setting the reference at 0 V, the
THS7373 allows a dc-coupled input to also function.
Therefore, the sync-tip-clamp (STC) is considered
transparent because it does not operate unless the
input signal goes below ground. The signal then goes
through the same 150-mV level shifter, resulting in an
output voltage low level of 300 mV. If the input signal
tries to go below 0 V, the internal control loop of the
STC sources up to 6 mA of current to increase the
input voltage level on the THS7373 input side of the
coupling capacitor. As soon as the voltage goes
above the 0-V level, the loop stops sourcing current
and becomes very high impedance.
One of the concerns about the sync-tip-clamp level is
how the clamp reacts to a sync edge that has
overshoot—common in VCR signals or reflections
found in poor printed circuit board (PCB) layouts.
Ideally, the STC should not react to the overshoot
voltage of the input signal. Otherwise, this response
could result in clipping on the rest of the video signal
because it may raise the bias voltage too much.
To help minimize this input signal overshoot problem,
the control loop in the THS7373 has an internal
low-pass filter, as shown in Figure 100. This filter
reduces the response time of the STC circuit. This
delay is a function of how far the voltage is below
ground, but in general it is approximately an 800-ns
delay for the 9.5-MHz filter and approximately a
250-ns delay for the 36-MHz filters. The effect of this
filter is to slow down the response of the control loop
so as not to clamp on the input overshoot voltage but
rather the flat portion of the sync signal.
As a result of this delay, sync may have an apparent
voltage shift. The amount of shift depends on the
amount of droop in the signal as dictated by the input
capacitor and the STC current flow. Because sync is
used primarily for timing purposes with syncing
occurring on the edge of the sync signal, this shift is
transparent in most systems.
+VS
Internal
Circuitry
STC LPF
+VS
gm
Input
0.1 mF Input
Pin
800 kW
Level
Shift
Figure 100. Equivalent AC Sync-Tip-Clamp Input
Circuit
While this feature may not fully eliminate overshoot
issues on the input signal, in cases of extreme
overshoot and/or ringing, the STC system should help
minimize improper clamping levels. As an additional
method to help minimize this issue, an external
capacitor (for example, 10 pF to 47 pF) to ground in
parallel with the external termination resistors can
help filter overshoot problems.
It should be noted that this STC system is dynamic
and does not rely upon timing in any way. It only
depends on the voltage that appears at the input pin
at any given point in time. The STC filtering helps
minimize level shift problems associated with
switching noises or very short spikes on the signal
line. This architecture helps ensure a very robust
STC system.
When the ac STC operation is used, there must also
be some finite amount of discharge bias current. As
previously described, if the input signal goes below
the 0-V clamp level, the internal loop of the THS7373
sources current to increase the voltage appearing at
the input pin. As the difference between the signal
level and the 0-V reference level increases, the
amount
of
source
current
increases
proportionally—supplying up to 6 mA of current.
Thus, the time to re-establish the proper STC voltage
can be very fast. If the difference is very small, then
the source current is also very small to account for
minor voltage droop.
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However, what happens if the input signal goes
above the 0-V input level? The problem is the video
signal is always above this level and must not be
altered in any way. Thus, if the sync level of the input
signal is above this 0-V level, then the internal
discharge (sink) current reduces the ac-coupled bias
signal to the proper 0-V level.
This discharge current must not be large enough to
alter the video signal appreciably or picture quality
issues may arise. This effect is often seen by looking
at the tilt (droop) of a constant luma signal being
applied and the resulting output level. The associated
change in luma level from the beginning and end of
the video line is the amount of line tilt (droop).
If the discharge current is very small, the amount of
tilt is very low, which is a generally a good thing.
However, the amount of time for the system to
capture the sync signal could be too long. This effect
is also termed hum rejection. Hum arises from the ac
line voltage frequency of 50 Hz or 60 Hz. The value
of the discharge current and the ac-coupling capacitor
combine to dictate the hum rejection and the amount
of line tilt.
To allow for both dc- and ac-coupling in the same
part, the THS7373 incorporates an 800-kΩ resistor to
ground. Although a true constant current sink is
generally preferred over a resistor, there can be
issues when the voltage is near ground. This
configuration can cause the current sink transistor to
saturate and cause potential problems with the signal.
The 800-kΩ resistor is large enough to not impact a
dc-coupled DAC termination. For discharging an
ac-coupled source, Ohm’s Law is used. If the video
signal is 1 V, then there is 1 V/800 kΩ = 1.25 μA of
discharge current. If more hum rejection is desired or
if a loss of sync occurs, then simply decrease the
0.1-μF input coupling capacitor. A decrease from
0.1 μF to 0.047 μF increases the hum rejection by a
factor of 2.1. Alternatively, an external pull-down
resistor to ground may be added that decreases the
overall resistance and ultimately increases the
discharge current.
To ensure proper stability of the ac STC control loop,
the source impedance must be less than 1 kΩ with
the input capacitor in place. Otherwise, there is a
possibility of the control loop ringing, which may
appear on the output of the THS7373. Because most
DACs or encoders use resistors to establish the
voltage, which are typically less than 300 Ω, meeting
the less than 1 kΩ requirement is easily done.
However, if the source impedance looking from the
THS7373 input perspective is very high, then simply
adding a 1-kΩ resistor to GND ensures proper
operation of the THS7373.
34
The ac STC function is not recommended for
ac-coupled component video P’B/P’R/U’/V’ signals.
These signals either have no embedded sync or they
have a mid-level sync. Using STC on these signals
can cause clipping, saturation, or an apparent voltage
shift in some video signals, such as 100% yellow for
a few pixels in a video frame. For these signals and
ac-input coupling, using the ac-bias mode is
recommended.
INPUT MODE OF OPERATION: AC BIAS
Sync-tip clamps work very well for signals that have
horizontal and/or vertical syncs associated with them;
however, some video signals do not have a sync
embedded within the signal. If ac-coupling of these
signals is desired, then a dc bias is required to
properly set the dc operating point within the
THS7373. This function is easily accomplished with
the THS7373 by simply adding an external pull-up
resistor to the positive power supply, as shown in
Figure 101.
VS+
VS+
CIN
0.1 mF
Input
Internal
Circuitry
RPU
Input
Pin
800 kW
Level
Shift
Figure 101. AC-Bias Input Mode Circuit
Configuration
The dc voltage appearing at the input pin is equal to
Equation 1:
VDC = VS
800 kW
800 kW + RPU
(1)
The THS7373 allowable input range is approximately
0 V to (VS+ – 1.5 V), allowing for a very wide input
voltage range. As such, the input dc bias point is very
flexible, with the output dc bias point being the
primary factor. For example, if the output dc bias
point is desired to be 1.6 V on a 3.3-V supply, then
the input dc bias point should be (1.6 V – 300 mV)/2
= 0.65 V. Thus, the pull-up resistor calculates to
approximately 3.3 MΩ, resulting in 0.644 V. If the
output dc-bias point is desired to be 1.6 V with a 5-V
power supply, then the pull-up resistor calculates to
approximately 5.36 MΩ.
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Keep in mind that the internal 800-kΩ resistor has
approximately a ±20% variance. As such, the
calculations should take this variance into account.
For the 0.644-V example above, using an ideal
3.3-MΩ resistor, the input dc bias voltage is
approximately 0.644 V ± 0.1 V.
The value of the output bias voltage is very flexible
and is left to each individual design. It is important to
ensure that the signal does not clip or saturate the
video signal. Thus, it is recommended to ensure the
output bias voltage is between 0.9 V and (VS+ – 1 V).
For 100% color saturated CVBS or signals with
Macrovision®, the CVBS signal can reach up to
1.23 VPP at the input, or 2.46 VPP at the output of the
THS7373. In contrast, other signals are typically
1 VPP or 0.7 VPP at the input which translate to an
output voltage of 2 VPP or 1.4 VPP. The output bias
voltage must account for a worst-case situation,
depending on the signals involved.
One other issue that must be taken into account is
the dc-bias point is a function of the power supply. As
such, there is an impact on system power-supply
rejection ratio (PSRR). To help reduce this impact,
the input capacitor combines with the pull-up
resistance to function as a low-pass filter.
Additionally, the time to charge the capacitor to the
final dc bias point is a function of the pull-up resistor
and the input capacitor. Lastly, the input capacitor
forms a high-pass filter with the parallel impedance of
the pull-up resistor and the 800-kΩ resistor. In
general, it is good to have this high-pass filter at
approximately 3 Hz to minimize any potential droop
on a P’B or P’R signal. A 0.1-μF input capacitor with a
3.3-MΩ pull-up resistor equates to approximately a
2.5-Hz high-pass corner frequency.
AC biasing is recommended for use with component
video P’B, P’R, U’, or V’ signals because these signals
either have no embedded sync or the sync is a
mid-level sync rather than a bottom-level sync. This
method can also be used with sync signals if desired.
The benefit of using the STC function is that it
maintains a constant back-porch voltage as opposed
to a back-porch voltage that fluctuates depending on
the video content. Because the input corner
frequency is a very low 2.5 Hz, the input corner
frequency is also a very low 2.5 Hz, which is
respectable (relative to a STC configuration).
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OUTPUT MODE OF OPERATION:
DC-COUPLED
simultaneously per channel—essentially, a 75-Ω
load—while keeping the output dynamic range as
wide as possible. Figure 102 shows the THS7373
driving two video lines while keeping the output
dc-coupled.
The THS7373 incorporates a rail-to-rail output stage
that can be used to drive the line directly without the
need for large ac-coupling capacitors. This design
offers the best line tilt and field tilt (droop)
performance because no ac-coupling occurs. Keep in
mind that if the input is ac-coupled, then the resulting
tilt as a result of the input ac-coupling continues to be
seen on the output, regardless of the output coupling.
The 80-mA output current drive capability of the
THS7373 is designed to drive two video lines
THS7373
(1)
0.1 mF
CVBS
R
(1)
(1)
0.1 mF
3.65 MW
P'B
2
HD CH1 IN
CVBS Out 2
75 W
HD CH1 OUT 13
3
HD CH2 IN
HD CH2 OUT 12
4
HD CH3 IN
HD CH3 OUT 11
5
GND
6
DISABLE
7
NC
75 W
CVBS Out 1
(2)
330 mF
75 W
VS+ 10
HD BYPASS
9
NC
8
75 W
Y' Out 2
(2)
330 mF
+
DAC/Encoder/SOC
+3.3 V
R
CVBS IN
+
0.1 mF
Y’
1
(2)
330 mF
+
75 W
CVBS OUT 14
75 W
+3.3 V
R
(1)
0.1 mF
3.65 MW
P'R
R
Y' Out 1
(2)
330 mF
+
75 W
75 W
To GPIO Controller
or GND
75 W
P'B Out 1
(2)
330 mF
+
75 W
P’B Out 2
(2)
330 mF
+
75 W
+3 V to +5 V
75 W
(2)
330 mF
75 W
P'R Out 1
+
75 W
P’R Out 2
(2)
330 mF
+
75 W
75 W
(1) This example shows an ac-coupled input. DC-coupling is also allowed as long as the DAC output voltage is within the allowable linear
input and output voltage range of the THS7373. To achieve dc-coupling, remove the 0.1-μF input capacitors and the 3.65-MΩ pull-up
resistors.
(2) This example shows ac-coupled outputs. DC-coupled outputs are also allowed by simply removing the series capacitors on each output.
Figure 102. Typical CVBS + Component Video System with AC-Coupled Inputs and Two Outputs Per
Channel
36
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One concern of dc-coupling arises, however, if the
line is terminated to ground. If the ac-bias input
configuration is used, the THS7373 output has a dc
bias. With two lines terminated to ground, this
configuration creates a dc current path that results in
a slightly decreased high output voltage swing and an
increase in power dissipation of the THS7373. While
the THS7373 was designed to operate with a junction
temperature of up to +125°C, care must be taken to
ensure that the junction temperature does not exceed
this level or else long-term reliability could suffer.
If the ac bias places 1.6 V on the output with two
dc-coupled lines connected, then the output current
flow without a signal is (1.6 V/75 Ω) = 21.3 mA per
channel. With a 3.3-V supply, the power dissipation
adds approximately [(3.3 V – 1.6 V) × 21.3 mA] =
36.2 mW per channel. With a 5-V power supply, this
increases to 72.4 mW per channel. The overall low
power dissipation of the THS7373 design minimizes
potential thermal issues even when using the TSSOP
package at high ambient temperatures. However,
power and thermal analysis should always be
examined in any system to ensure no issues arise.
Be sure to use RMS power rather than instantaneous
power when conducting thermal analysis.
Note that the THS7373 can drive the line with
dc-coupling regardless of the input mode of
operation. The only requirement is to make sure the
video line has proper termination in series with the
output (typically 75 Ω). This requirement helps isolate
capacitive loading effects from the THS7373 output.
Failure to properly isolate capacitive loads may result
in ringing or oscillations. The stray capacitance
appearing directly at the THS7373 output pins should
be kept below 20 pF for the 9.5-MHz filter channels
and below 15 pF for the 36-MHz filter channels. One
way to help ensure this condition is satisfied is to
make sure the 75-Ω source resistor is placed next to
each THS7373 output pin. If a large ac-coupling
capacitor is used, the capacitor should be placed
after this resistor.
There are many reasons dc-coupling is desirable,
including reduced system cost, PCB area, no line tilt,
and no field tilt. A common question is whether or not
there are any drawbacks to using dc-coupling. There
are some potential issues that must be examined,
such as the dc current bias as discussed above.
Another potential risk is whether this configuration
meets industry standards. EIA-770 stipulates that the
back-porch shall be 0 V ± 1 V as measured at the
receiver. With a double-terminated load system, this
requirement implies a 0 V ± 2 V back-porch level at
the video amplifier output. The THS7373 can easily
meet this requirement without issue. However, in
Japan, the EIAJ CP-1203 specification stipulates a 0
V ± 0.1 V level with no video signal. This requirement
can be met with the THS7373 in shutdown mode, but
while active it cannot meet this specification without
output ac-coupling. AC-coupling the output essentially
ensures that the video signal works with any system
and any specification. For many modern systems,
however, dc-coupling can satisfy most needs.
OUTPUT MODE OF OPERATION:
AC-COUPLED
A very common method of coupling the video signal
to the line is with a large capacitor. This capacitor is
generally between 220 μF and 1000 μF, although
470 μF is very typical. The value of this capacitor
must be large enough to minimize the line tilt (droop)
and/or field tilt associated with ac-coupling as
described previously in this document. AC-coupling is
performed for several reasons, but the most common
is to ensure full interoperability with the receiving
video system. This approach ensures that regardless
of the reference dc voltage used on the transmitting
side, the receiving side re-establishes the dc
reference voltage to its own requirements.
In the same way as the dc output mode of operation
discussed previously, each line should have a 75-Ω
source termination resistor in series with the
ac-coupling capacitor. This resistor should be placed
next to the THS7373 output to minimize stray
capacitive effects. If two lines are to be driven, it is
best to have each line use its own capacitor and
resistor rather than sharing these components. This
configuration helps ensure line-to-line dc isolation and
eliminates the potential problems as described
previously. Using a single, 1000-μF capacitor for two
lines is permissible, but there is a chance for
interference between the two receivers along with the
capacitor potentially placing a capacitive load on the
THS7373 output.
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Lastly, because of the edge rates and frequencies of
operation, it is recommended (but not required) to
place a 0.1-μF to 0.01-μF capacitor in parallel with
the large 220-μF to 1000-μF capacitor. These large
value capacitors are most commonly aluminum
electrolytic. It is well-known that these capacitors
have significantly large equivalent series resistance
(ESR), and the impedance at high frequencies is
rather large as a result of the associated inductances
involved with the leads and construction. The small
0.1-μF to 0.01-μF capacitors help pass these
high-frequency signals (greater than 1 MHz) with
much lower impedance than the large capacitors.
Figure 103 shows a typical configuration where the
input is dc-coupled and the output is also ac-coupled.
relatively steep initial attenuation at the corner
frequency. The problem with this characteristic is that
the group delay rises near the corner frequency.
Group delay is defined as the change in phase
(radians/second) divided by a change in frequency.
An increase in group delay corresponds to a time
domain pulse response that has overshoot and some
possible ringing associated with the overshoot. The
greater the variation in group delay, the greater the
pulse response overshoot will be.
The use of other type of filters, such as elliptic or
chebyshev, are not recommended for video
applications because of the very large group delay
variations near the corner frequency resulting in
significant overshoot and ringing. While these filters
may help meet the video standard specifications with
respect to amplitude attenuation, the group delay is
well beyond the standard specifications. Considering
this delay with the fact that video can go from a white
pixel to a black pixel over and over again, it is easy to
see that ringing can occur. Ringing typically causes a
display to have ghosting or fuzziness appear on the
edges of a sharp transition. On the other hand, a
Bessel filter has ideal group delay response, but the
rate of attenuation is typically too low for acceptable
image rejection. Thus, the Butterworth filter is a
respectable compromise for both attenuation and
group delay.
LOW-PASS FILTER
Each channel of the THS7373 incorporates a
sixth-order,
low-pass
filter.
These
video
reconstruction filters minimize DAC images from
being passed onto the video receiver. Depending on
the receiver design, failure to eliminate these DAC
images can cause picture quality problems because
of aliasing of the ADC. Another benefit of the filter is
to smooth out aberrations in the signal that DACs
typically have associated with the digital stepping of
the signal. This benefit helps with picture quality and
ensures that the signal meets video bandwidth
requirements.
Each filter has an associated Butterworth
characteristic. The benefit of the Butterworth
response is that the frequency response is flat with a
THS7373
(1)
0.1 mF
75 W
R
(1)
+3.3 V
(1)
0.1 mF
2
HD CH1 IN
HD CH1 OUT 13
3
HD CH2 IN
HD CH2 OUT 12
4
HD CH3 IN
HD CH3 OUT 11
5
GND
6
DISABLE
7
NC
75 W
75 W
(2)
330 mF
Y'/G' Out
3.65 MW
P'B
75 W
VS+ 10
HD BYPASS
9
NC
8
75 W
(2)
330 mF
P'B/B' Out
+
DAC/Encoder/SOC
Y’
R
CVBS IN
+
0.1 mF
CVBS OUT 14
1
CVBS
+
CVBS
(2)
330 mF
75 W
+3.3 V
R
75 W
3.65 MW
P'R
R
(2)
330 mF
P'R/R' Out
+
(1)
0.1 mF
To GPIO Controller
or GND
75 W
+3 V to +5 V
(1) This example shows an ac-coupled input. DC-coupling is also allowed as long as the DAC output voltage is within the allowable linear
input and output voltage range of the THS7373. To achieve dc-coupling, remove the 0.1-μF input capacitors and the 3.65-MΩ pull-up
resistors.
(2) This example shows ac-coupled outputs. DC-coupled outputs are also allowed by simply removing the series capacitors on each output.
Figure 103. Typical AC Input System Driving AC-Coupled Video Lines
38
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The THS7373 CVBS CVBS filter has a nominal
corner (–3 dB) frequency at 9.5-MHz and a –1-dB
passband typically at 8.2 MHz. This 9.5-MHz filter is
ideal for CVBS NTSC, PAL, and SECAM composite
video (CVBS) signals. The 9.5-MHz, –3-dB corner
frequency was designed to achieve 54 dB of
attenuation at 27 MHz—a common sampling
frequency between the DAC/ADC second and third
Nyquist zones found in many video systems. This
consideration is important because any signal that
appears around this frequency can also appear in the
baseband as a result of aliasing effects of an ADC
found in a receiver.
The THS7373 HD filters have a nominal corner
(–3-dB) frequency at 36MHz and a –1-dB passband
typically at 33 MHz. This 36-MHz filter is ideal for HD
720p, 1080i, up to 1080p30 Y’/P’B/P’R, broadcast
G’B’R’ signals, and computer R’G’B’ video signals.
The 36-MHz, –3-dB corner frequency was designed
to achieve 40 dB of attenuation at 74.25 MHz—a
common sampling frequency between the DAC/ADC
second and third Nyquist zones found in many video
systems.
Keep in mind that images do not stop at the DAC
sampling frequency, fS (for example, 27 MHz for
traditional CVBS DACs); they continue around the
sampling frequencies of 2x fS, 3x fS, 4x fS, and so on
(that is, 54-MHz, 81-MHz, 108-MHz, etc.). Because of
these multiple images, an ADC can fold down into the
baseband signal, meaning that the low-pass filter
must also eliminate these higher-order images. The
THS7373 filters are Butterworth filters and, as such,
do not bounce at higher frequencies, thus maintaining
good attenuation performance.
The filter frequencies were chosen to account for
process variations in the THS7373. To ensure the
required video frequencies are effectively passed, the
filter corner frequency must be high enough to allow
component variations. The other consideration is that
the attenuation must be large enough to ensure the
anti-aliasing/reconstruction filtering is sufficient to
meet the system demands. Thus, the selection of the
filter frequencies was not arbitrarily selected and is a
good compromise that should meet the demands of
most systems.
HD FILTER BYPASS MODE
The THS7373 has an HD filter bypass mode that
bypasses the HD channels internal filters, thus the
THS7373 effectively becomes a fixed gain 2-V/V
operational amplifier. Bypassing the HD filters results
in an amplifier supporting a 350-MHz bandwidth and
450-V/µs slew rate. This bypass supports 1080p60
signals along with computer R’G’B’ signals up to
QXGA or UWXGA resolution. This mode still uses the
dc + shift functionality along with the transparent
sync-tip-clamp function. Essentially, the only
difference in this mode is that the HD filters are
bypassed.
BENEFITS OVER PASSIVE FILTERING
Two key benefits of using an integrated filter system,
such as the THS7373, over a passive system are
PCB area and filter variations. The small TSSOP-14
package for four video channels is much smaller over
a passive RLC network, especially a six-pole passive
network. Additionally, consider that inductors have at
best ±10% tolerances (normally, ±15% to ±20% is
common) and capacitors typically have ±10%
tolerances. Using a Monte Carlo analysis shows that
the filter corner frequency (–3 dB), flatness (–1 dB), Q
factor (or peaking), and channel-to-channel delay
have wide variations. These variances can lead to
potential performance and quality issues in
mass-production environments. The THS7373 solves
most of these problems with the corner frequency
being essentially the only variable.
Another concern about passive filters is the use of
inductors. Inductors are magnetic components, and
are therefore susceptible to electromagnetic
coupling/interference (EMC/EMI). Some common
coupling can occur because of other video channels
nearby using inductors for filtering, or it can come
from nearby switched-mode power supplies. Some
other forms of coupling could be from outside sources
with strong EMI radiation and can cause failure in
EMC testing such as required for CE compliance.
One concern about an active filter in an integrated
circuit is the variation of the filter characteristics when
the ambient temperature and the subsequent die
temperature change. To minimize temperature
effects, the THS7373 uses low-temperature
coefficient resistors and high-quality, low-temperature
coefficient capacitors found in the BiCom3X process.
These filters have been specified by design to
account for process variations and temperature
variations to maintain proper filter characteristics.
This approach maintains a low channel-to-channel
time delay that is required for proper video signal
performance.
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Another benefit of the THS7373 over a passive RLC
filter is the input and output impedance. The input
impedance presented to the DAC varies significantly,
from 35 Ω to over 1.5 kΩ with a passive network, and
may cause voltage variations over frequency. The
THS7373 input impedance is 800 kΩ, and only the
2-pF input capacitance plus the PCB trace
capacitance impact the input impedance. As such,
the voltage variation appearing at the DAC output is
better controlled with a fixed termination resistor and
the high input impedance buffer of the THS7373.
On the output side of the filter, a passive filter again
has a large impedance variation over frequency.
EIA770 specifications require the return loss to be at
least 25 dB over the video frequency range of usage.
For a video system, this requirement implies that the
source impedance (which includes the source, series
resistor, and the filter) must be better than 75 Ω,
+9/–8 Ω. The THS7373 is an operational amplifier
that approximates an ideal voltage source, which is
desirable because the output impedance is very low
and can source and sink current. To properly match
the transmission line characteristic impedance of a
video line, a 75-Ω series resistor is placed on the
output. To minimize reflections and to maintain a
good return loss meeting EIA specifications, this
output impedance must maintain a 75-Ω impedance.
A passive filter impedance variation cannot ensure
this level of performance. On the other hand, the
THS7373 has approximately 0.8 Ω of output
40
impedance at 6.75 MHz for the 9.5-MHz filter and
approximately 1.4 Ω of output impedance at 30 MHz
for the 36-MHz filters. Thus, the system is matched
significantly better with a THS7373 compared to a
passive filter.
One final benefit of the THS7373 over a passive filter
is power dissipation. A DAC driving a video line must
be able to drive a 37.5-Ω load: the receiver 75-Ω
resistor and the 75-Ω impedance matching resistor
next to the DAC to maintain the source impedance
requirement. This requirement forces the DAC to
drive at least 1.25 VP (100% saturation CVBS)/37.5 Ω
= 33.3 mA. A DAC is a current-steering element, and
this amount of current flows internally to the DAC
even if the output is 0 V. Thus, power dissipation in
the DAC may be very high, especially when six
channels are being driven. Using the THS7373 with a
high input impedance and the capability to drive up to
two video lines per channel can reduce DAC power
dissipation significantly. This outcome is possible
because the resistance that the DAC drives can be
substantially increased. It is common to set this
resistance in a DAC by a current-setting resistor on
the DAC itself. Thus, the resistance can be 300 Ω or
more, substantially reducing the current drive
demands from the DAC and saving significant
amounts of power. For example, a 3.3-V,
four-channel DAC dissipates 440 mW alone for the
steering current capability (four channels × 33.3 mA ×
3.3 V) if it must drive a 37.5-Ω load. With a 300-Ω
load, the DAC power dissipation as a result of current
steering current would only be 55 mW (four channels
× 4.16 mA × 3.3 V).
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EVALUATION MODULE
To evaluate the THS7373, an evaluation module
(EVM) is available. The THS7373EVM allows for
testing the THS7373 in many different configurations.
Inputs and outputs include BNC connectors
commonly found in video systems, along with 75-Ω
input termination resistors, 75-Ω series source
termination resistors, and 75-Ω characteristic
impedance traces. Several unpopulated component
pads are found on the EVM to allow for different input
and output configurations as dictated by the user.
This EVM is designed to be used with a single supply
from 2.6 V up to 5 V.
The EVM default input configuration sets all channels
for dc input coupling. The input signal must be within
0 V to approximately 1.4 V for proper operation.
Failure to be within this range saturates and/or clips
the output signal. If the input range is beyond this, if
the signal voltage is unknown, or if coming from a
current sink DAC, then ac input configuration is
desired. This option is easily accomplished with the
EVM by simply replacing the Z1 through Z4 0-Ω
resistors with 0.1-μF capacitors.
For an ac-coupled input and sync-tip clamp (STC)
functionality commonly used for CVBS, s-video Y',
component Y' signals, and R'G'B' signals, no other
changes are needed. However, if a bias voltage is
needed after the input capacitor which is commonly
needed for s-video C', component P'B and P'R
signals, then a pull-up resistor should be added to the
signal on the EVM. This configuration is easily
achieved by simply adding a resistor to any of the
following resistor pads: RX1, RX3, RX5, or RX7. A
common value to use is 3.3 MΩ. Note that even
signals with embedded sync can also use bias mode
if desired.
The EVM default output configuration sets all
channels for ac output coupling. The 470-μF and
0.1-μF capacitors work well for most ac-coupled
systems. However, if dc-coupled output is desired,
then replacing the 0.1-μF capacitors (C12, C14, C16,
and/or C17) with 0-Ω resistors works well. Removing
the 470-μF capacitors is optional, but removing them
from the EVM eliminates a few picofarads of stray
capacitance on each signal path which may be
desirable.
The THS7373 incorporates an easy method to
configure the bypass mode and the disable mode.
The use of JP1 controls the disable feature and JP4
controls the HD channels filter/bypass mode. While
there is a space on the EVM for JP2 and JP3, these
are not used for the THS7373.
Connection of JP1 to GND applies 0 V to the disable
pin and the THS7373 operates normally. Moving JP1
to +VS causes all channels of the THS7373 to be in
disable mode.
Connection of JP4 to GND places the THS7373 HD
channels in filter mode while moving JP4 to +VS
places the THS7373 HD channels in bypass mode.
The THS7373EVM also includes a method to improve
the ESD performance of all the analog inputs and
outputs beyond the ratings shown in the Absolute
Maximum Ratings table. By using very low cost
BAV99 diodes, the EVM has the ability to pass IEC
±8kV surge testing. Another common protection diode
commonly utilized is the BAT54S which also achieves
the same surge suppression performance as the
BAV99 diodes.
Figure 104 shows the THS7373EVM schematic.
Figure 105 and Figure 106 illustrate the two layers of
the EVM PCB, incorporating standard high-speed
layout practices. Table 6 lists the bill of materials as
the board comes supplied from Texas Instruments.
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+
+
+
+
+
+
Figure 104. THS7373EVM Schematic
42
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Figure 105. THS7373EVM PCB Top Layer
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Figure 106. THS7373EVM PCB Bottom Layer
44
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SBOS506 – DECEMBER 2009
THS7373EVM Bill of Materials
Table 6. THS7373EVM
ITEM
REF DES
QTY
DESCRIPTION
SMD SIZE
1
FB1, FB2
2
Bead, ferrite, 2.5A, 330 Ω
2
C24
1
Capacitor, 100 µF, tantalum, 10V, 10%, low
ESR
3
C35
1
Capacitor, 22 µF, tantalum, 16V, 10%, low
ESR
4
C1-C4,
C7-C10,
C19-C22
12
Open
0805
5
C5
1
Capacitor, 0.01 µF, ceramic, 100V, X7R
6
C12, C14, C16,
C17, C23,
C25-C34, C36
16
7
C6
8
MANUFACTURER
PART NUMBER
DISTRIBUTOR
PART NUMBER
(TDK) MPZ2012S331A
(DIGI-KEY)
445-1569-1-ND
C
(AVX) TPSC107K010R0100
(DIGI-KEY)
478-1765-1-ND
C
(AVX) TPSC226K016R0375
(DIGI-KEY)
478-1767-1-ND
0805
(AVX) 08051C103KAT2A
(DIGI-KEY)
478-1358-1-ND
Capacitor, 0.1 µF, ceramic, 50V, X7R
0805
(AVX) 08055C104KAT2A
(DIGI-KEY)
478-1395-1-ND
1
Capacitor, 1 µF, ceramic, 16V, X7R
0805
(TDK) C2012X7R1C105K
(DIGI-KEY)
445-1358-1-ND
C11, C13, C15,
C18
4
Capacitor, aluminum, 470 µF, 10V, 20%
(PANASONIC)
EEE-FP1A471AP
(DIGI-KEY)
PCE4526CT-ND
9
RX1-RX8
8
Open
0603
10
R6, R7, R14,
R15
4
Open
0805
11
Z1-Z4,
R18-R25
12
Resistor, 0 Ω
0805
(ROHM) MCR10EZHJ000
(DIGI-KEY)
RHM0.0ACT-ND
12
R1-R4, R9-R12
8
Resistor, 75 Ω, 1/8W, 1%
0805
(ROHM) MCR10EZHF75.0
(DIGI-KEY)
RHM75.0CCT-ND
13
R17
1
Resistor, 100 Ω, 1/8W, 1%
0805
(ROHM) MCR10EZHF1000
(DIGI-KEY)
RHM100CCT-ND
14
R13, R16
2
Resistor, 1k Ω, 1/8W, 1%
0805
(ROHM) MCR10EZHF1001
(DIGI-KEY)
RHM1.00KCCT-ND
15
R5, R8
2
Resistor, 100k Ω, 1/8W, 1%
0805
(ROHM) MCR10EZHF1003
(DIGI-KEY)
RHM100KCCT-ND
16
D1-D8
8
Diode, ultrafast
(FAIRCHILD) BAV99
(DIGI-KEY)
BAV99FSCT-ND
17
J9, J10
2
Jack, banana receptance, 0.25" diameter
hole
(SPC) 813
(NEWARK) 39N867
18
J1-J8
8
Connector, BNC, jack, 75 Ω
(AMPHENOL)
31-5329-72RFX
(NEWARK) 93F7554
19
J13, J14
2
Connector, RCA jack, yellow
(CUI) RCJ-044
(DIGI-KEY) CP-1421-ND
20
J11, J12
2
Connector, RCA, jack, R/A
(CUI) RCJ-32265
(DIGI-KEY) CP-1446-ND
21
TP5, TP6
2
Test point, black
(KEYSTONE) 5001
(DIGI-KEY) 5001K-ND
22
JP2, JP3
2
Open
3 pos.
23
JP1, JP4
2
Header, 0.1" CTRS, 0.025" square pins
3 pos.
(SULLINS) PBC36SAAN
(DIGI-KEY) S1011E-36-ND
24
JP1, JP4
2
Shunts
(SULLINS) SSC02SYAN
(DIGI-KEY) S9002-ND
25
U1
1
IC, THS7373
26
—
4
Standoff, 4-40 hex, 0.625" length
(KEYSTONE) 1808
(DIGI-KEY) 1808K-ND
27
—
4
Screw, Phillips, 4-40, 0.250"
(BF) PMS 440 0031 PH
(DIGI-KEY) H343-ND
28
—
1
Board, printed circuit
EDGE # 6512620 Rev.A
0805
F
PW
(TI) THS7373IPW
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EVALUATION BOARD/KIT IMPORTANT NOTICE
Texas Instruments (TI) provides the enclosed product(s) under the following conditions:
This evaluation board/kit is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION, OR EVALUATION PURPOSES
ONLY and is not considered by TI to be a finished end-product fit for general consumer use. Persons handling the product(s) must have
electronics training and observe good engineering practice standards. As such, the goods being provided are not intended to be complete
in terms of required design-, marketing-, and/or manufacturing-related protective considerations, including product safety and environmental
measures typically found in end products that incorporate such semiconductor components or circuit boards. This evaluation board/kit does
not fall within the scope of the European Union directives regarding electromagnetic compatibility, restricted substances (RoHS), recycling
(WEEE), FCC, CE or UL, and therefore may not meet the technical requirements of these directives or other related directives.
Should this evaluation board/kit not meet the specifications indicated in the User’s Guide, the board/kit may be returned within 30 days from
the date of delivery for a full refund. THE FOREGOING WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY SELLER TO BUYER
AND IS IN LIEU OF ALL OTHER WARRANTIES, EXPRESSED, IMPLIED, OR STATUTORY, INCLUDING ANY WARRANTY OF
MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE.
The user assumes all responsibility and liability for proper and safe handling of the goods. Further, the user indemnifies TI from all claims
arising from the handling or use of the goods. Due to the open construction of the product, it is the user’s responsibility to take any and all
appropriate precautions with regard to electrostatic discharge.
EXCEPT TO THE EXTENT OF THE INDEMNITY SET FORTH ABOVE, NEITHER PARTY SHALL BE LIABLE TO THE OTHER FOR ANY
INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES.
TI currently deals with a variety of customers for products, and therefore our arrangement with the user is not exclusive.
TI assumes no liability for applications assistance, customer product design, software performance, or infringement of patents or
services described herein.
Please read the User’s Guide and, specifically, the Warnings and Restrictions notice in the User’s Guide prior to handling the product. This
notice contains important safety information about temperatures and voltages. For additional information on TI’s environmental and/or
safety programs, please contact the TI application engineer or visit www.ti.com/esh.
No license is granted under any patent right or other intellectual property right of TI covering or relating to any machine, process, or
combination in which such TI products or services might be or are used.
FCC Warning
This evaluation board/kit is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION, OR EVALUATION PURPOSES
ONLY and is not considered by TI to be a finished end-product fit for general consumer use. It generates, uses, and can radiate radio
frequency energy and has not been tested for compliance with the limits of computing devices pursuant to part 15 of FCC rules, which are
designed to provide reasonable protection against radio frequency interference. Operation of this equipment in other environments may
cause interference with radio communications, in which case the user at his own expense will be required to take whatever measures may
be required to correct this interference.
EVM WARNINGS AND RESTRICTIONS
It is important to operate this EVM within the input voltage range of 2.6 V to 5.5 V single-supply and the output voltage range of 0 V to
5.5 V.
Exceeding the specified input range may cause unexpected operation and/or irreversible damage to the EVM. If there are questions
concerning the input range, please contact a TI field representative prior to connecting the input power.
Applying loads outside of the specified output range may result in unintended operation and/or possible permanent damage to the EVM.
Please consult the EVM User's Guide prior to connecting any load to the EVM output. If there is uncertainty as to the load specification,
please contact a TI field representative.
During normal operation, some circuit components may have case temperatures greater than +85°C. The EVM is designed to operate
properly with certain components above +85°C as long as the input and output ranges are maintained. These components include but are
not limited to linear regulators, switching transistors, pass transistors, and current sense resistors. These types of devices can be identified
using the EVM schematic located in the EVM User's Guide. When placing measurement probes near these devices during operation,
please be aware that these devices may be very warm to the touch.
Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265
Copyright © 2009, Texas Instruments Incorporated
46
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Copyright © 2009, Texas Instruments Incorporated
Product Folder Link(s): THS7373
PACKAGE OPTION ADDENDUM
www.ti.com
1-Jan-2010
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
THS7373IPW
ACTIVE
TSSOP
PW
14
THS7373IPWR
ACTIVE
TSSOP
PW
14
90
Lead/Ball Finish
MSL Peak Temp (3)
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
2000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is
provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on
incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited
information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI
to Customer on an annual basis.
Addendum-Page 1
MECHANICAL DATA
MTSS001C – JANUARY 1995 – REVISED FEBRUARY 1999
PW (R-PDSO-G**)
PLASTIC SMALL-OUTLINE PACKAGE
14 PINS SHOWN
0,30
0,19
0,65
14
0,10 M
8
0,15 NOM
4,50
4,30
6,60
6,20
Gage Plane
0,25
1
7
0°– 8°
A
0,75
0,50
Seating Plane
0,15
0,05
1,20 MAX
PINS **
0,10
8
14
16
20
24
28
A MAX
3,10
5,10
5,10
6,60
7,90
9,80
A MIN
2,90
4,90
4,90
6,40
7,70
9,60
DIM
4040064/F 01/97
NOTES: A.
B.
C.
D.
All linear dimensions are in millimeters.
This drawing is subject to change without notice.
Body dimensions do not include mold flash or protrusion not to exceed 0,15.
Falls within JEDEC MO-153
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