VISHAY M52759SP

M52759SP
Uniformity for CRT Display Monitor
REJ03F0197-0201
Rev.2.01
Mar 31, 2008
Description
M52759SP is semiconductor integrated circuit for uniformity of CRT display monitor.
It generates horizontal and vertical parabola waves and is able to revise contrast of CRT display monitor if it is used
with Video Pre.Amp. M52742SP that has uniformity circuit.
Features
• It can control phase of horizontal wave.
• It can changes the parabola wave unbalance.
• It contains the horizontal saw wave generator and Auto Gain Control circuit, so that it is able to keep the amplitude
constant if frequency change.
• It can changes the parabola wave unbalance.
• Frequency Band Width: horizontal
24 to 120 kHz
Vertical
50 to 185 Hz
• Input: horizontal
5 VP-P Pulse
Vertical
3.2 VP-P V Saw
Application
CRT display monitor
Recommended Operating Condition
Supply voltage range:
11.5 V to 12.5 V
Rated supply voltage:
12 V
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
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M52759SP
Block Diagram
Hbias
input
H-GND
H-pulse
input
20
19
18
17
16
VPH
input
Vref
output
15
14
13
H-Pulse
Delay
12
11
AGC DET
Vref
X2
Buffer
Para.Amp
+
V-VCC
SW
Para.Amp &
Limiter
X2
H-SAW
Generator
Buffer
1
2
3
4
5
6
V-GND
V-saw
input
Vbias
input
V-para
output
VGV
input
VGH
input
7
8
H-para
output
Pin Arrangement
M52759SP
V-GND
1
20 V-VCC
V-saw input
2
19 Hbias
Vbias
3
18 H-GND
V-para output
4
17 H-pulse input
VGV input
5
16 H-delay capacitor
VGH input
6
15 VPH input
H-para output
7
14 Reference voltage
H-saw retrace
8
13 Reference voltage resistor
H-saw trace
9
12 AGC trace capacitor
H-VCC 10
11 AGC retrace capacitor
(Top view)
Outline: PRDP0020BA-A (20P4B)
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
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9
10
H-VCC
M52759SP
Absolute Maximum Ratings
(Ta = 25°C, Surge capacity = 200 pF)
Item
Symbol
Ratings
Typ.
Max.
Unit
Supply voltage
Power dissipation
Operating temperature
Storage temperature
Recommended operating voltage
VCC
Pd
Topr
Tstg
Vopr


−20
−40





12.0
13.0
1237.6
+85
+150

V
mW
°C
°C
V
Recommended operating voltage range
Surge
Vopr'
Vsurge
11.5
±200


12.5

V
V
Min.
Thermal Derating
Power Dissipation Pd (mW)
1500
1237.6
1000
643.6
500
0
−20
0
25
50
75 85 100
125
Ambient Temperature Ta (°C)
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
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150
M52759SP
Electrical Characteristics
(Ta = 25°C, VCC = 12 V, unless otherwise noted)
Item
Symbol
Limits
Min.
Typ.
15.1
21.5
5.2
7.4
6.75
6.95

49
Max.
27.9
9.6
7.15

Circuit current 1
Circuit current 2
Reference voltage output
ICCH
ICCV
VREF
Reference voltage
temperature drift
Horizontal Block
H-pulse low input range
DREF
VIL
0.0

2.0
H-pulse high input range
VIH
3.0

H-pulse low input current
H-pulse high input current
H parabola width
IIL
IIH
TW
−5.0
−1.0
0.6
H parabola delay 1
TD1
H parabola delay 2
Unit
Test Conditions
Pin No.
mA
mA
V
(10) Measure
(20) Measure
(14) Measure
10
20
14
ppm/
deg
(14) Measure
14
V
(6) 2.4 V in
(7) Measure
(15) 3.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
VCC
−2.0
V
7
−0.6
0.0
0.8
−0.1
1.0
1.0
µA
µA
µs
(6) 2.4 V in
(7) Measure
(15) 3.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
(17) 0 V in, measure
(17) 5 V in, measure
0.1
0.3
0.5
µs
(6) 2.4 V in
(7) Measure
(15) 0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
TD2
0.4
0.6
0.8
µs
(6) 2.4 V in
(7) Measure
(15) 1.3 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
H parabola delay 3
TD3
2.9
3.1
3.3
µs
(6) 2.4 V in
(7) Measure
(15) 4.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
Delay temperature drift
DD

0.08

ns/
deg
(6) 2.4 V in
(7) Measure
(15) 3.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
Pin 15 input current
I15
−5.0
−0.3
−0.1
µA
(17) 2.5 V in, measure
15
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
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(6) 2.4 V in
(7) Measure
(15) 3.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
17
17
7
M52759SP
Electrical Characteristics (cont.)
Item
Symbol
Limits
Typ.
−2.2
Max.
−1.8
Unit
V
(6) 1.8 V in
(7) Measure
(15) 0 V in
(17) fH = 96 kHz H-pulse in
(19) 5.7 V in
7
Test Conditions
Pin No.
H para. unbalance control 1
UHP1
Min.
−2.6
H para. unbalance control 2
UHP2
0.1
0.5
0.9
V
(6) 2.4 V in
(7) Measure
(15) 0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
H para. unbalance control 3
UHP3
1.7
2.1
2.5
V
(6) 1.8 V in
(7) Measure
(15) 0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.4 V in
7
H para. unbalance VCC.
character 1
VUHP1
−0.2
0.0
0.2
V
(6) 2.4 V in
(7) Measure
(15) 0 V in
(10) (20) 11.5 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
H para. unbalance VCC.
character 2
VUHP2
−0.2
0.0
0.2
V
(6) 2.4 V in
(7) Measure
(15) 0 V in
(10) (20) 12.5 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
H para. unbalance
temperature drift
DUHP

−2.2

mV/
deg
(6) 2.4 V in
(7) Measure
(15) 0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
H para. gain control 1
GHP1
0.2
0.4
0.6
VP-P
(6) 1.0 V in
(7) Measure
(15) 3.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
H para. gain control 2
GHP2
2.9
3.3
3.7
VP-P
(6) 2.5 V in
(7) Measure
(15) 3.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
H para. gain control 3
GHP3
5.3
6.0
6.7
VP-P
(6) 4.0 V in
(7) Measure
(15) 3.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 5 of 26
M52759SP
Electrical Characteristics (cont.)
Item
Symbol
Limits
Typ. Max.
0.0
0.2
H para. freq.
characteristics 1
FHP1
Min.
−0.2
H para. freq.
characteristics 2
FHP2
−0.2
0.0
H para. VCC
characteristics 1
VVHP1
−0.2
H para. VCC
characteristics 2
VVHP2
H para. size
temperature drift
DHP
Pin 6 input current
Pin 19 input current
Vertical Block
V parabola accuracy 1
Unit
Test Conditions
Pin No.
V
(6) 4.0 V in
(7) Measure
(15) 3.0 V in
(17) fH = 24 kHz H-pulse in
(19) 6.1 V in
7
0.2
V
(6) 4.0 V in
(7) Measure
(15) 3.0 V in
(17) fH = 120 kHz H-pulse in
(19) 6.1 V in
7
0.0
0.2
V
(6) 4.0 V in
(7) Measure
(15) 3.0 V in
(10) (20) 11.5 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
−0.2
0.0
0.2
V
(6) 4.0 V in
(7) Measure
(15) 3.0 V in
(10) (20) 12.5 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7

−1.3

mV/
deg
(6) 4.0 V in
(7) Measure
(15) 3.0 V in
(17) fH = 96 kHz H-pulse in
(19) 6.1 V in
7
I6
I19
−5.0
0.1
−0.3
0.3
−0.1
5.0
µA
µA
(6) 2.4 V in, measure
(19) 6.1 V in, measure
6
19
AVP1
4.5
5.0
5.5
V
(2) 3.5 V in
(3) 3.5 V in
(4) Measure
(5) 2.3 V in
4
V parabola accuracy 2
AVP2
2.5
3.0
3.5
V
(2) 1.9 V in
(3) 3.5 V in
(4) Measure
(5) 2.3 V in
4
V parabola accuracy 3
AVP3
20
25
30
%
(2) 2.7 V in
(3) 3.5 V in
(4) Measure
(5) 2.3 V in
4
V parabola accuracy 4
AVP4
20
25
30
%
(2) 4.3 V in
(3) 3.5 V in
(4) Measure
(5) 2.3 V in
4
V parabola accuracy 5
AVP5
90
100
110
%
(2) 5.1 V in
(3) 3.5V in
(4) Measure
(5) 2.3 V in
4
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 6 of 26
M52759SP
Electrical Characteristics (cont.)
Item
Symbol
Limits
Typ. Max.
−2.5 −2.2
V para. unbalance
control 1
UVP1
Min.
−2.8
V para. unbalance
control 2
UVP2
−0.3
0
V para. unbalance
control 3
UVP3
2.2
V unbalance. VCC.
characteristics 1
VUVP1
V unbalance. VCC.
characteristics 2
Unit
Test Conditions
Pin No.
V
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 2.8 V in
(4) Measure
(5) 1.6 V in
4
0.3
V
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 2.3 V in
4
2.5
2.8
V
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 4.2 V in
(4) Measure
(5) 1.6 V in
4
−0.1
0.0
0.1
V
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 2.3 V in
(10) (20) 11.5 V in
4
VUVP2
−0.1
0.0
0.1
V
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 2.3 V in
(10) (20) 12.5 V in
4
V unbalance.
temperature drift
DUVP

0.5

mV/
deg
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 2.3 V in
4
V parabola amplitude 1
GVP1
0
0
0.3
VP-P
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 1.0 V in
4
V parabola amplitude 2
GVP2
2.1
2.4
2.7
VP-P
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 2.0 V in
4
V parabola amplitude 3
GVP3
4.2
4.7
5.2
VP-P
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 3.0 V in
4
V para. freq.
characteristics 1
FVP1
−0.1
0.0
0.1
V
(2) fV = 50 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 3.0 V in
4
V para. freq.
characteristics 2
FVP2
−0.1
0.0
0.1
V
(2) fV = 185 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 3.0 V in
4
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 7 of 26
M52759SP
Electrical Characteristics (cont.)
Item
Symbol
Limits
Typ. Max.
0.0
0.1
V para. VCC.
characteristics 1
VVP1
Min.
−0.1
V para. VCC.
characteristics 2
VVP2
−0.1
0.0
V para. temperature
drift
DVP

Pin 2 input current
Pin 3 input current
Pin 5 input current
I2
I3
I5
−5.0
−5.0
−5.0
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 8 of 26
Unit
Test Conditions
Pin No.
V
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 3.0 V in
(10) (20) 11.5 V in
4
0.1
V
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 3.0 V in
(10) (20) 12.5 V in
4
−2.2

mV/
deg
(2) fV = 70 Hz, 3.2 VP-P saw wave in
(3) 3.5 V in
(4) Measure
(5) 3.0 V in
4
−0.3
−0.3
−0.3
−0.1
−0.1
−0.1
µA
µA
µA
(2) 3.5 V in, measure
(3) 3.5 V in, measure
(5) 2.3 V in, measure
2
3
5
M52759SP
Switch and Voltage Condition
Switch
Symbol
ICCH
ICCV
VREF
DREF
VIL
VIH
IIL
IIH
TW
TD1
TD2
TD3
DD
I15
UHP1
UHP2
UHP3
VUHP1
VUHP2
DUHP
GHP1
GHP2
GHP3
FHP1
FHP2
VVHP1
VVHP2
DHP
I6
I19
AVP1
AVP2
AVP3
AVP4
AVP5
UVP1
UVP2
UVP3
VUVP1
VUVP2
DUVP
GVP1
GVP2
GVP3
FVP1
FVP2
VVP1
VVP2
DVP
I2
I3
I5
SW2
SW3
SW5
a
a
a
Voltage (V)
SW6 SW10 SW15 SW17 SW19 SW20
a
b
a
a
b
a
a
b
a
VCC
V2
V3
V5
V6
V15
V17
V19
12.0
3.5
3.5
2.5
2.4
3.0
0
6.1
a

b
0
5.0

a
b
a
b
a
1.8
2.4
1.8
2.4
11.5
12.5
12.0
1.0
2.5
4.0
0
1.3
4.0
3.0

0
0

5.7
6.1
6.4
6.1
3.0
11.5
12.5
12.0
b
a

2.4
b
b
a
2.3
1.9
2.7
4.3
5.1

b
11.5
12.5
12.0
2.8
3.5
4.2
3.5
1.6
2.3
1.6
2.3
1.0
2.0
3.0
11.5
12.5
12.0
c
a
3.5
b
a
b
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 9 of 26
2.3

0

6.1
M52759SP
Input Signal
5.0 V Typ
PG
(Input signal to pin 17)
VTH = 2.5 V
0 V Typ
Pulse width above 1 µs
Frequency 24 to 96 to 140 kHz
1.6 V
SG
(Input signal to pin 2)
3.5 V
1.6 V
Frequency 50 to 70 to 185 Hz
Electrical Characteristics Test Method
ICCH Circuit Current1
Measure the input current to pin 10.
ICCV Circuit Current2
Measure the input current to pin 20.
VREF Reference Voltage Output
Measure the output voltage at pin 14.
DREF Reference Voltage Temperature Drift
Measure temperature drift of pin 14. (−20°C to 85°C)
VIL H-pulse Low Input Range
Input horizontal pulse which low level is 2 V in pin 17 and confirm output horizontal signal at pin 7.
5.0 V
Input signal to pin 17
2.0 V
Output signal at pin 7
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 10 of 26
M52759SP
VIH H-pulse High Input Range
Input horizontal pulse which high level is 3 V in pin 17 and confirm output horizontal signal at pin 7.
3.0 V
Input signal to pin 17
0V
Output signal at pin 7
TW H Parabola Width
Measure the time width of retrace period at pin 7.
TW
Input signal to pin 17
TD1, TD2, TD3 H Parabola Delay
Measure the delay time from rise time of input signal to start of retrace period of output signal when the voltage of
pin 15 is 0 V, 1.3 V, and 4 V.
5.0 V
Input signal to pin 17
0V
TD1, TD2, TD3
Output signal at pin 7
DD Delay Temperature Drift
Measure the temperature drift of the delay time. (−20°C to 85°C)
I15 Pin 15 Input Current
Measure the input current to pin 15 when the voltage of pin 15 is 2.5 V.
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 11 of 26
M52759SP
UHP1, UHP2, UHP3 H para. Unbalance Control
UHPS is defined as the voltage of parabola start point. UHPE is defined as the voltage of parabola end point. UHP1, UHP2,
UHP3 is defined as follows
UHP1, UHP2, UHP3 = UHPS − UHPE
Measure the unbalance of parabola waveform at pin 4 when the voltage of pin 19 is 5.7 V, 6.1 V, and 6.4 V. Pin 6 is
controlled so that the amplitude of parabola is 3 VP-P constant.
UHPS
Output signal at pin 7
UHP
UHPE
VUHP1 H para. Unbalance VCC. Characteristics1
When the supply voltage of pin 10, 20 is 11.5 V, the unbalance of parabola waveform at pin 7 is defined as UHP11.5 V.
VUHP1 = UHP2 − UHP11.5 V
VUHP2 H para. Unbalance VCC. Characteristics2
When the supply voltage of pin 10, 20 is 12.5 V, the unbalance of parabola waveform at pin 7 is defined as UHP12.5 V.
VUHP2 = UHP2 − UHP12.5 V
DUHP H para. Unbalance Temperature Drift
Measure temperature drift of UHP2. (−20°C to 85°C)
GHP1 H Para. Gain Control1
Measure the amplitude of parabola waveform at pin 7 and it is defined as HP−6, 1.0 V.
GHP2 H Para. Gain Control2
The amplitude of parabola waveform at pin 7 is defined as HP−6, 2.5 V.
GHP3 H Para. Gain Control3
The amplitude of parabola waveform at pin 7 is defined as HP−6, 4.0 V.
FHP1 H Para. Freq. Characteristics1
When the frequency of input signal in pin 17 is 96 kHz, the amplitude of parabola waveform at pin 7 is defined as HP96
kHz. When the frequency of input signal is 24 kHz, the amplitude of parabola waveform is defined as HP24 kHz.
FHP1 = HP96 kHz − HP24 kHz
FHP2 H Para. Freq. Characteristics2
When the frequency of input signal in pin 17 is 140 kHz, the amplitude of parabola waveform at pin 7 is defined as
HP120 kHz.
FHP2 = HP96 kHz − HP140 kHz
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 12 of 26
M52759SP
VVHP1 H Para. VCC. Characteristics1
When the supply voltage of pin 10, 20 is 12.0 V, the amplitude of parabola waveform at pin 7 is defined as HP12.0 V.
When the supply voltage is 11.5 V, the amplitude of parabola waveform is defined as HP11.5 V.
VVHP1 = HP12.0 V − HP11.5 V
VVHP2 H Para. VCC. Characteristics2
When the supply voltage of pin 10, 20 is 12.5 V, the amplitude of parabola waveform at pin 7 is defined as HP12.5 V.
VVHP2 = HP12.0 V − HP12.5 V
DHP H Para. Size Temperature Drift
Measure the temperature drift of HP96 kHz. (−20°C to 85°C)
I6 Pin 6 Input Current
Measure the input current to pin 6 when voltage of pin 6 is 2.4 V.
I19 Pin 19 Input Current
Measure the input current to pin 19 when voltage of pin 19 is 6.1 V.
AVP1 V Parabola Accuracy1
Measure the output voltage at pin 4 and it is defined as VP−2, 3.5 V.
AVP2 V Parabola Accuracy2
The output voltage at pin 4 is defined as VP−2, 1.9 V.
AVP2 = VP−2, 1.9 V − VP−2, 3.5 V
AVP3 V Parabola Accuracy3
The output voltage at pin 4 is defined as VP−2, 2.7 V.
AVP3 =
VP−2, 2.7 V − VP−2, 3.5 V
× 100 (%)
VP−2, 1.9 V − VP−2, 3.5 V
AVP4 V Parabola Accuracy4
The output voltage at pin 4 is defined as VP−2, 4.3 V.
AVP4 =
VP−2, 4.3 V − VP−2, 3.5 V
× 100 (%)
VP−2, 1.9 V − VP−2, 3.5 V
AVP5 V Parabola Accuracy5
The output voltage at pin 4 is defined as VP−2, 5.1 V.
AVP5 =
VP−2, 5.1 V − VP−2, 3.5 V
× 100 (%)
VP−2, 1.9 V − VP−2, 3.5 V
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 13 of 26
M52759SP
UVP1, UVP2, UVP3 V Para. Unbalance Control
UVPS is defined as the voltage of parabola start point. UVPE is defined as the voltage of parabola end point. UVP1, UVP2,
UVP3 is defined as follows
UVP1, UVP2, UVP3 = UVPS − UVPE
Measure the unbalance of parabola waveform at pin 4 when the voltage of pin 3 is 2.8 V, 3.5 V, and 4.2 V. Pin 5 is
controlled so that the amplitude of parabola is 3 VP-P constant.
UVPS
Output signal at pin 7
UVPE
VUVP1 V Unbalance VCC. Characteristics1
When the supply voltage of pin 10, 20 is 11.5 V, the unbalance of parabola waveform at pin 4 is defined as UVP11.5 V.
VUHP1 = UVP2 − UVP11.5 V
VUVP2 V Unbalance VCC. Characteristics2
When the supply voltage of pin 10, 20 is 12.5 V, the unbalance of parabola waveform at pin 4 is defined as UVP 12.5 V.
VUVP2 = UVP2 − UVP12.5 V
DUVP V Unbalance Temperature Drift
Measure temperature drift of UVP2 (−20°C to 85°C)
GVP1, GVP2, GVP3 V Parabola Amplitude
Measure the amplitude of parabola waveform at pin 4 when the voltage of pin 5 is 1 V, 2 V, and 3 V.
FVP1 V Para. Freq. Characteristics1
When the frequency of input signal in pin 2 is 70 Hz, the amplitude of parabola waveform at pin 4 is defined as VP70 Hz.
When the frequency of input signal is 50 Hz, the amplitude of parabola waveform is defined as VP50 Hz.
FVP1 = VP70 Hz − VP50 Hz
FVP2 V Para. Freq. Characteristics2
When the frequency of input signal in pin 2 is 185 Hz, the amplitude of parabola waveform at pin 4 is defined as VP185
Hz.
FVP2 = VP70 Hz − VP185 Hz
VVP1 V Para. VCC. Characteristics1
When the voltage of pin 10, 20 is 12.0 V, the amplitude of parabola waveform is defined as VP12.0 V. When the voltage
is 11.5 V, the amplitude of parabola waveform is defined as VP11.5 V.
VVP1 = VP12.0 V − VP11.5 V
VVP2 V Para. VCC. Characteristics2
When the voltage of pin 10, 20 is 12.5 V, the amplitude of parabola waveform is defined as VP12.5 V.
VVP2 = VP12.0 V − VP12.5 V
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 14 of 26
M52759SP
DVP V Para. Temperature Drift
Measure temperature drift of VP70 Hz. (−20°C to 85°C)
I2 Pin 2 Input Current
Measure the input current to pin 2 when the voltage of pin 2 is 3.5 V.
I3 Pin 3 Input Current
Measure the input current to pin 3 when the voltage of pin 3 is 3.5 V.
I5 Pin 5 Input Current
Measure the input current to pin 5 when the voltage of pin 5 is 2.4 V.
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 15 of 26
M52759SP
Test Circuit
VCC
11.5 V
12.0 V
12.5 V
20
A
H-Pulse
a
b
a
SW19
SW17
19
18
b
17
V
a
SW15
16
15
14
H-Pulse
Delay
12
11
AGC DET
Vref
X2
Buffer
Para.Amp
13
0.01 µF
0.01 µF
+
33 µF
b
2.5 V
A
7V
a
b
V15
0V
1.3 V
3.0 V
4.0 V
1 µF
A
SW20
100 pF
6.1 V
A
V17
0V
5.0 V
6.8 k
V19
5.7 V
6.1 V
6.4 V
+
V19
0V
5.7 V
6.1 V
6.4 V
SW
X2
Para.Amp &
Limiter
H-SAW
Generator
SW2
V2 a
1.9 V
2.7 V
3.5 V
4.3 V
5.1 V
c
4
5
SW3
a
b
b
A
SW5
Osc Scope
Dig-vol
a
3.5 V
b
A
2.8 V
3.5 V
4.2 V
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 16 of 26
SW6
a
A
b
Osc Scope
A
2.3 V
1V
2V
3V
7
Hout
V6
V5
3.5 V
V-saw
6
2.4 V
1.0 V
2.4 V
2.5 V
4.0 V
8
9
10
+
a
33 µF
3
100 pF
2
100 pF
1
0.01 µF
Buffer
b SW10
A
M52759SP
Typical Characteristics
Horizontal Block
Delay Control Voltage vs. Delay Time
3.5
Pin 7 Delay Time (µs)
3.0
Pin 17 input
2.5
Delay time
2.0
1.5
Pin 7 Output
1.0
0.5
0
0
Usable
range
0.5
1
1.3
Unusable
range
2
3
4
5
Usable range
Pin 15 Delay Control Voltage (V)
H Unbalance Control Bias Voltage vs.
H Parabola Unbalance
Pin 6 is controlled as the amplitude of parabola is 3 VP-P constant
Pin 7 H Parabola Unbalance (V)
Pin 7 output
2
1
0
−1
−2
5.7
5.9
6.1
6.3
6.5
Pin 19 H Unbalance Control Bias Voltage (V)
Pin 7 H Parabola Amplitude (VP-P)
H Gain Control Voltage vs.
H Parabola Amplitude
7
Pin 19 = 6.1 V const.
6
5
4
3
2
1
0
0
1
2
3
4
Pin 6 H Gain Control Voltage (V)
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 17 of 26
5
M52759SP
Vertical Block
V Para DC Output Voltage Ratio
Pin 4 Output Voltage Ratio (%)
100
Pin 3 = 3.5 V const.
Pin 5 = 2.3 V const.
75
50
Output ratio =
Pin 4out − Pin 4out@Pin 4 = 3.5 V
× 100 (%)
Pin 4out@Pin 2 = 1.9 V − Pin 4out@Pin 2 = 3.5 V
25
0
1.9
2.7
3.5
4.3
5.1
Pin 2 Input Voltage (V)
V Unbalance Control Bias Voltage vs.
V Parabola Unbalance
Pin 4 V Parabola Unbalance (V)
3
Pin 5 is controlled as the amplitude of parabola is 3 VP-P constant
Pin 4 output
2
1
0
−1
−2
−3
2.5
3.0
3.5
4.0
4.5
Pin 3 V Unbalance Control Bias Voltage (V)
V Para Amp Gain Control Voltage vs.
Output Amplitude
Pin 4 V Para Amplitude (VP-P)
5
Pin 2 3.2 VP-P sawtooth wave input
4
3
2
1
0
0
1
2
3
4
Pin 5 V Para Amp Gain Control Voltage (V)
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 18 of 26
M52759SP
Timing Chart
Horizontal Block
3.0 ≤ VIH ≤ (VCC − 2.0 V)
Pin 17 H-pulse input
VTH = 2.5 V
VIL ≤ 2.0 V
Pulse width to 3 µs
Internal H-pulse
Pulse delay
Pulse width to 0.8 µs
Pin 8 output
Pin 7 output
Vertical Block
Pin 2 input
1.6 V
1.6 V
Pin 4 output
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 19 of 26
Pin 3 input
voltage = 3.5 V
M52759SP
Application Example
1.8 k 100 p
1k
Flyback
Pulse in
3.9 k
20
19
18
17
15
14
13
11
AGC DET
X2
Buffer
Para.Amp
12
Vref
H-Pulse
0.01 µF
VPH
16
1 µF
Hbias
6.8 k
100 pF
V-VCC
0.01 µF
0.01 µF
+
VCC 12 V
+
33 µF
1k
SW
Para.Amp
X2
H-SAW
Buffer
Vbias
7
VGV
(V Gain)
8
Hout
10
9
VGH
(H Gain)
V-saw
input
V
Uniformity in
M52742SP
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 20 of 26
CRT
Monitor
+
HVCC
0.01 µF
6
47 µ
5
Vout
100 pF
0.01 µF
4
100 pF
3
0.01 µF
2
0.01 µF
1
V-GND
M52759SP
17
VPH
16
14
H-Pulse
Delay
13
1 µF
12
11
AGC DET
Vref
X2
Buffer
Para.Amp
6.8 k
1%
1%
15
0.01 µF
H-pulse input
0.01 µF
H-GND
18
100 pF
0.01 µF
Hbias
19
C∆
0.01 µF
20
+
V-VCC
1%
1%
The total resistance is above 10 kΩ
+
33 µF
10 µH
12.0 V
SW
Para.Amp &
Limiter
H-SAW
Generator
7
Hout
8
9
2 VP-P
3.2 VP-P
above 10 kΩ
2.2 µF
10
H-VCC
+
10 µH
6
VGH
(H Gain)
0.01 µF
0.01 µF
5
VGV
(H Gain)
100 pF
4
Vout
C∆
3
Vbias
0.01 µF
2
V-saw
input
0.01 µF
1
V-GND
100 pF
Buffer
C∆
X2
1%
1%
4.7 µF
H/V
Deflection
IC
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 21 of 26
DAC
above 10 kΩ
V
M52759SP
Pin Description
Pin No.
1
2
Name
V-GND
Vsawi
DC Voltage (V)

3.5 V
Peripheral Circuit

Function
GND of vertical block
Vertical sawtooth wave input pin.
V-VCC
50 µA
Vbias
1k
2
V-GND
3
Vbias
2.8 to 4.2 V
V-VCC
50 µA
Vertical parabola unbalance control bias
voltage input pin.
Input voltage range is 2.8 to 4.2 V
1k
3
V-GND
4
Vout
5 V (Bottom)
Vertical parabola wave output pin.
V-VCC
200
Bottom voltage = 5 V (fixed)
4
Amplitude is possible to control by pin 5
1 mA
V-GND
5
VGV
1.0 to 3.0 V
V-VCC
50 µA
Vertical parabola wave gain control
voltage input pin. Input voltage range is
1.0 to 3.0 V.
1k
5
V-GND
6
VGH
1.0 to 4.0 V
H-VCC
50 µA
1k
6
H-GND
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 22 of 26
Horizontal parabola wave gain control
voltage input pin. Input voltage range is
1.0 to 4.0 V.
M52759SP
Pin Description (cont.)
Pin No.
7
Name
Hout
DC Voltage (V)
2.4 to 9.2 V
Peripheral Circuit
Function
Horizontal parabola wave output pin.
H-VCC
200
Amplitude is possible to control by
pin 6
7
1 mA
H-GND
8
Cret
7.1 V
(Top)
4.9 V
(Bottom)
H-VCC
0.25 mA
Connection pin of horizontal retrace
capacitor.
Recommended capacitance is
100 pF.
8
7.1 V
1.5 k
H-GND
9
Ctrc
7.1 V
(Top)
4.9 V
(Bottom)
60 µA
4.9 V
37 µA
Connection pin of horizontal trace
capacitor.
Recommended capacitance is
100 pF.
H-VCC
9
7.1 V
2k
510
2k
4.9 V
70 µA
H-GND
10
11
H-VCC
CAGCr
12.0 V
2.5 V

Connection pin of horizontal sawtooth
wave AGC retrace capacitor.
Recommended capacitance is
0.01 µF.
H-VCC
11
1.5 k
H-GND
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 23 of 26
VCC of horizontal block.
M52759SP
Pin Description (cont.)
Pin No.
12
Name
CAGC
DC Voltage (V)
4.0 V
Peripheral Circuit
Function
Connection pin of horizontal AGC
capacitor.
Recommended capacitance is 1 µF.
H-VCC
12
7.5 k
1.5 k
H-GND
13
Vrefr
1.28 V
Connection pin of reference current
source resister.
Recommended resistance is 6.8
kΩ.
H-VCC
4k
13
H-GND
14
Vrefo
7.0 V
Reference voltage output for
horizontal pulse delay circuit.
Should be connect more than 10 kΩ
external resister.
H-VCC
10 p
14
50 µA
H-GND
15
VPH
0 to 0.5 V
1.3 to 4.0 V
0.2 mA
H-VCC
50 µA
15
Delay adjustment voltage input pin
of horizontal pulse. Input voltage
range is 1.3 to 4.0 V.
At 0 to 0.5 V, delay is minimized.
(0.5 to 1.3 V is unusable range.)
1k
H-GND
16
Chpd
0V
(Bottom)
H-VCC
2k
2k
50 µA
Connection pin of horizontal pulse
delay timing capacitor.
Recommended capacitance is 100
pF.
0.5 to 5.0 VP-P
H
16
H-GND
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 24 of 26
1k
0V
M52759SP
Pin Description (cont.)
Pin No.
17
Name
HPin
DC Voltage (V)

Peripheral Circuit
H-VCC
50 µA
17
1k
Function
Horizontal pulse input pin.
Low input level is less than 2.0 V,
and high is 3.0 to 10 V.
(at VCC = 12 V)
50 k
H-GND
18
19
H-GND
Hbias

5.7 to 6.4 V

GND of horizontal block
Horizontal parabola unbalance
control bias voltage input pin. Input
voltage range is 5.7 to 6.4 V.
H-VCC
1k
19
1p
50 µA
H-GND
20
V-VCC
12.0 V
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 25 of 26

VCC of vertical block
M52759SP
Package Dimensions
RENESAS Code
PRDP0020BA-A
Previous Code
20P4B
MASS[Typ.]
1.0g
11
1
10
c
*1
E
20
e1
JEITA Package Code
P-SDIP20-6.3x19-1.78
NOTE)
1. DIMENSIONS "*1" AND "*2"
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION "*3" DOES NOT
INCLUDE TRIM OFFSET.
*2
A
A2
D
L
A1
Reference
Symbol
*3 b
3
e
SEATING PLANE
bp
e1
D
E
A
A1
A2
bp
b3
c
e
L
REJ03F0197-0201 Rev.2.01 Mar 31, 2008
Page 26 of 26
Dimension in Millimeters
Min Nom Max
7.32 7.62 7.92
18.8 19.0 19.2
6.15 6.3 6.45
4.5
0.51
3.3
0.38 0.48 0.58
0.9 1.0 1.3
0.22 0.27 0.34
0°
15°
1.528 1.778 2.028
3.0
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