Datasheet
P’
R
Out 2
75 W
+
75 W
P’
R
Out 1
75 W
+
75 W
P’
B
Out 2
75 W
+
75 W
P’
B
Out 1
75 W
+
75 W
Y’
Out 2
75 W
+
75 W
Y’
Out 1
75 W
330 fm
(Note A)
+
75 W
5
8
7
6
1
2
3
4
Y’
P’
B
P’
R
THS7314
+
R
R
3.3 V
R
3.3 V
3.3 V
3.3 V
3.01MW
3.01MW
0.1 Fm
0.1 Fm
0.1 Fm
0.1 Fm
22 Fm
V
S+
GND
CH.2IN
CH.3IN
CH.1IN
CH.3OUT
CH.2OUT
CH.1OUT
DAC/
Encoder
3.3V
3.3V
3.3V
SDTV
480i/576i
Y’P’ P’
G’B’R’
B R
330 fm
(Note A)
330 fm
(Note A)
330 fm
(Note A)
330 fm
(Note A)
330 fm
(Note A)
THS7314
SLOS513A –DECEMBER 2006– REVISED MARCH 2011
www.ti.com
Lastly, due to 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. These capacitors have significantly large ESR (equivalent series
resistance), and their impedance at high frequencies is large due to the associated inductances involved with the
leads and construction. The small 0.1-μF to 0.01-μF capacitors help pass these high frequency (>1 MHz) signals
with much lower impedance than the large capacitors.
Although it is common to use the same capacitor values for all the video lines, the frequency bandwidth of the
chroma signal in a S-Video system are not required to go as low – or as high of a frequency – as the luma
channels. Thus the capacitor values of the chroma line(s) can be smaller – such as 0.1-μF.
A. Due to the high frequency content of the video signal, it is recommended, but not required, to add a 0.1-μF or 0.01-μF
capacitor in parallel with these large capators.
B. Current sinking DAC / Encoder shown. See the application notes.
Figure 34. Typical 480i/576i Y'P'
B
P'
R
AC-Input System Driving 2 AC-Coupled Video Lines
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