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(R)
STV9325
Vertical Deflection Booster for 2.5-APPTV/Monitor Applications with 70-V Flyback Generator
DATASHEET
Main Features
Power Amplifier Flyback Generator Stand-by Control Output Current up to 2.5 App Thermal Protection
HEPTAWATT (Plastic Package) ORDER CODE: STV9325
Description
The STV9325 is a vertical deflection booster designed for TV and monitor applications. This device, supplied with up to 35 V, provides up to 2.5 App output current to drive the vertical deflection yoke. The internal flyback generator delivers flyback voltages up to 75 V. In double-supply applications, a stand-by state will be reached by stopping the (+) supply alone.
Tab connected to pin 4
7 6 5 4 3 2 1 Input (Non Inverting) Output Stage Supply Output Ground Or Negative Supply Flyback Generator Supply Voltage Input (Inverting)
Output Stage Supply
6
Flyback Generator
3
Supply Voltage
2
Non-Inverting Input Inverting Input
Flyback Generator 7
+
Power Amplifier 5
Output
1
Thermal Protection
STV9325
4
Ground or Negative Supply
June 2004
Revision 1.5
Absolute Maximum Ratings
STV9325
1
Absolute Maximum Ratings
Symbol Parameter Value Unit
Voltage VS V5, V 6 V3 V1, V 7 Current I0 (1) I0 (2) I3 Sink I3 Source I3 ESD Susceptibility ESD1 ESD2 Temperature Ts Tj Storage Temperature Junction Temperature -40 to 150 +150 C C Human body model (100 pF discharged through 1.5 k) EIAJ Standard (200 pF discharged through 0 ) 2 300 kV V Output Peak Current at f = 50 to 200 Hz, t 10s - Note 4 Output Peak Current non-repetitive - Note 5 Sink Current, t<1ms - Note 3 Source Current, t < 1ms Flyback pulse current at f=50 to 200 Hz, t10s - Note 4 5 2 2 2 5 A A A A A Supply Voltage (pin 2) - Note 1 and Note 2 Flyback Peak Voltage - Note 2 Voltage at Pin 3 - Note 2, Note 3 and Note 6 Amplifier Input Voltage - Note 2, Note 6 and Note 7 40 75 -0.4 to (VS + 3) - 0.4 to (VS + 2) or +40 V V V V
Note:1. Usually the flyback voltage is slightly more than 2 x V S. This must be taken into consideration when setting VS. 2. Versus pin 4 3. V3 is higher than V S during the first half of the flyback pulse. 4. Such repetitive output peak currents are usually observed just before and after the flyback pulse. 5. This non-repetitive output peak current can be observed, for example, during the Switch-On/SwitchOff phases. This peak current is acceptable providing the SOA is respected (Figure 8 and Figure 9). 6. All pins have a reverse diode towards pin 4, these diodes should never be forward-biased. 7. Input voltages must not exceed the lower value of either VS + 2 or 40 volts.
2
Thermal Data
Symbol
RthJC TT TJ
Parameter
Junction-to-Case Thermal Resistance Temperature for Thermal Shutdown Recommended Max. Junction Temperature
Value
3 150 120
Unit
C/W C C
2/14
STV9325
Electrical Characteristics
3
Electrical Characteristics
(V S = 34 V, TAMB = 25C, unless otherwise specified)
Symbol
Supply VS I2 I6 Input I1 I7 VIR VI0 VI0/dt Output I0 V5L V5H Stand-by V5STBY
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
Fig.
Operating Supply Voltage Range (V2-V4) Pin 2 Quiescent Current Pin 6 Quiescent Current
Note 8 I3 = 0, I5 = 0 I3 = 0, I5 = 0, V6 =35v
10 5 8 19
35 20 50
V mA mA 1 1
Input Bias Current Input Bias Current Operating Input Voltage Range Offset Voltage Offset Drift versus Temperature
V1 = 1 V, V7 = 2.2 V V1 = 2.2 V, V7 = 1 V 0
- 0.6 - 0.6
-1.5 -1.5 VS - 2
A A
1
V mV
V/C
2 10
Operating Peak Output Current Output Saturation Voltage to pin 4 Output Saturation Voltage to pin 6
0o1.25 1.6 2.2
A V V 3 2
Output Voltage in Stand-by
V1 = V7 = VS = 0 See Note 9
VS - 2
V
Miscellaneous G VD5-6 VD3-2 V3SL V3SH Voltage Gain Diode Forward Voltage Between pins 5-6 Diode Forward Voltage between pins 3-2 Saturation Voltage on pin 3 Saturation Voltage to pin 2 (2nd part of flyback) I5 = 1.25 A I3 = 1.25 A I3 = 20 mA I3 = -1.25 A 80 1.5 1.5 0.4 1.8 2.1 2.1 1 2.6 dB V V V V 3
8. In normal applications, the peak flyback voltage is slightly greater than 2 x (VS - V 4). Therefore, (VS - V 4) = 35 V is not allowed without special circuitry. 9. Refer to Figure 4, Stand-by condition.
3/14
Electrical Characteristics
STV9325
Figure 1: Measurement of I 1, I2 and I6
+Vs I2 2
7
I6 6 5
2.2V
STV9325
S 1 4
39k (a) (b) I1 1V 5.6k
(a): I2 and I6 measurement (b): I1 measurement
Figure 2: Measurement of V5H
+Vs
2
7
6 V5H 5 - I5 4
2.2V
STV9325
1 1V
Figure 3: Measurement of V3L and V5L
+Vs 2
7
6 (b) 3
I3 or I5 (a)
1V
STV9325
5 1 2.2V 4 V3L V5L
(a): V5L measurement (b): V 3L measurement
4/14
STV9325
Application Hints
4
Application Hints
The yoke can be coupled either in AC or DC.
4.1
DC-coupled Application
When DC coupled (see Figure 4), the display vertical position can be adjusted with input bias. On the other hand, 2 supply sources (VS and -VEE ) are required. A Stand-by state will be reached by switching OFF the positive supply alone. In this state, where both inputs are the same voltage as pin 2 or higher, the output will sink negligible current from the deviation coil.
Figure 4: DC-coupled Application
+Vs
Vref Vertical Position Adjustment
VM Vm
R3
-VEE
4
(*) recommended:
Ly Ly ------------- < Rd < -----------20s 50s
4.1.1
Application Hints
For calculations, treat the IC as an op-amp, where the feedback loop maintains V 1 = V7.
000000000000000000
0000000000000000 000000000000000000
470F
0.1F R2
0.22F
000000000 000000000
470F
0.1F 6 Power Amplifier 7 +
CF (47 to 100F)
Output Voltage
3
2 Flyback Generator
Output Current Ip
000000000 000000000
5 1 Thermal Safety 1.5 Rd(*) Yoke Ly
R1
5/14
Application Hints
4.1.1.1 Centering
STV9325
Display will be centered (null mean current in yoke) when voltage on pin 7 is (R1 is negligible):
V7 2 x
+ --- -- - -- - - -- - - - -- --- -
4.1.1.2 Peak Current
Example: for V m = 2 V, VM = 5 V and IP = 1 A Choose R1 in the1 range, for instance R1=1
2 x IP x R1 V M V m
Then choose R2 or R3. For instance, if R2 = 10 k, then R3 = 15 k Finally, the bias voltage on pin 7 should be:
V +V 71 M m 1 V 7 = ------------------------ x ----------------- = --- x ------- = 1.4V 2 2.5 R 2 3 1 + ------R2
4.1.2
Ripple Rejection
When both ramp signal and bias are provided by the same driver IC, you can gain natural rejection of any ripple caused by a voltage drop in the ground (see Figure 5), if you manage to apply the same fraction of ripple voltage to both booster inputs. For that purpose, arrange an intermediate point in the bias resistor bridge, such that (R8 / R7) = (R3 / R2), and connect the bias filtering capacitor between the intermediate point and the local driver ground. Of course, R7 should be connected to the booster reference point, which is the ground side of R1.
Figure 5: Ripple Rejection
Reference Voltage
Power Amplifier 7 + 5 1 Thermal Safety 4 Rd Yoke Ly
R9
R8
R7
Ramp Signal
R3 R2
Source of Ripple
6/14
00000000
Driver Ground
000000
- -- = ---------------------------- = -------
From equation of peak current:
=
IP
------------------------ = +
R2 R 3
VM
Vm
R2
R2
R3
( VM Vm ) R2 ---------------------------- x -----------------R 1 xR 3 2
-
2 3
6
3
2 Flyback Generator
00000000 00000000
R1
STV9325
Application Hints
4.2
AC-Coupled Applications
In AC-coupled applications (See Figure 6), only one supply (VS ) is needed. The vertical position of the scanning cannot be adjusted with input bias (for that purpose, usually some current is injected or sunk with a resistor in the low side of the yoke).
Figure 6: AC-coupled Application
Vm
(*) recommended:
Ly Ly ------------ < Rd < ------------50s 20s
4.2.1
Application Hints
Gain is defined as in the previous case:
p 2 R1 x R3 VM Vm R2
Choose R1 then either R2 or R3. For good output centering, V 7 must fulfill the following equation:
VS VM + Vm ------- V ------------------------ V V 7 7 7 2 2 --------------------- = ------------------------------------- + ------R +R R R 4 5 3 2
or

VM + Vm VS 1 1 1 V x ------- + ------- + --------------------- = ------------------------------ + -----------------------7 R2 R + R 2 (R 4 + R5 ) 2 x R3 R 3 4 5

---------------------
I
x
000000000
00000000
R5
Cs
R2 R1
000000000
4
R4
0.22F
VM
R3
----------------------- = -
-
000000000
-
000000000 000000000 000000000
470F
0.1F 6
CF (47 to 100F)
+Vs
Output Voltage
3
2 Flyback Generator
Output Current Ip
Power Amplifier 7 + 5 1 Thermal Safety 1.5 Rd(*)
Yoke Ly
CL
7/14
Application Hints
STV9325
CS performs an integration of the parabolic signal on CL, therefore the amount of S correction is set by the combination of CL and Cs.
4.3
Application with Differential-output Drivers
Certain driver ICs provide the ramp signal in differential form, as two current sources i + and i- with opposite variations.
Figure 7: Using a Differential-output Driver
+Vs
Differential output driver IC Power Amplifier ip icm
+
R7 1
icm
-
-VEE
4
Let us set some definitions:
icm is the common-mode current:
1 i cm = -- ( i + + i - ) 2
at peak of signal, i+ = icm + ip and i- = icm - ip, therefore the peak differential signal is ip - (ip) = 2 ip, and the peak-peak differential signal, 4ip.
The application is described in Figure 7 with DC yoke coupling. The calculations still rely on the fact that V1 remains equal to V7.
8/14
000000000000000000
(*) recommended:
Ly Ly ------------- < Rd < ------------20 s 50s
000000000000000000 000000000000000000
470F
0.1F R2
0.22F
-ip
000000000 000000000 000000000
470F
0.1F 6
CF (47 to 100F)
Output Voltage
3
2
Flyback Generator
Output Current Ip
7
+
5
-
Thermal Safety
1.5
Rd(*)
Yoke Ly
R1
STV9325 4.3.1 Centring
Application Hints
When idle, both driver outputs provide icm and the yoke current should be null (R1 is negligible), hence:
i cm R 7 = i cm R 2 therefore R 7 = R 2
4.3.2
Peak Current
Scanning current should be IP when positive and negative driver outputs provide respectively icm - ip and icm + ip, therefore
Choose R1 in the 1 range, the value of R2 = R7 follows. Remember that i is one-quarter of driver peak-peak differential signal! Also check that the voltages on the driver outputs remain inside allowed range.
Example: for icm = 0.4mA, i = 0.2mA (corresponding to 0.8mA of peak-peak differential current), Ip = 1A Choose R1 = 0.75, it follows R2 = R7 = 1.875k.
4.3.3
Ripple Rejection
Make sure to connect R7 directly to the ground side of R1.
4.3.4
Secondary Breakdown Diagrams
Figure 8: Output Transistor Safe Operating Area (SOA) for Secondary Breakdown
The diagram has been arbitrarily limited to max I0 (2 A).
-
cm
-
(i
i) R
7
= I R + (i + i ) R and since R7 = R2: p 1 cm 2
Ip ---- = i
2R 7 ---------R1
9/14
Mounting Instructions
STV9325
Figure 9: Secondary Breakdown Temperature Derating Curve (ISB = Secondary Breakdown Current)
5
Mounting Instructions
The power dissipated in the circuit is removed by adding an external heatsink. With the HEPTAWATTTM package, the heatsink is simply attached with a screw or a compression spring (clip). A layer of silicon grease inserted between heatsink and package optimizes thermal contact. In DCcoupled applications we recommend to use a silicone tape between the device tab and the heatsink to electrically isolate the tab.
Figure 10: Mounting Examples
10/14
STV9325
Pin Configuration
6
Pin Configuration
Figure 11: Pins 1 and 7
2
1
7
Figure 12: Pin 3 & Pins 5 and 6
2
6 2
5 3
4
11/14
Package Mechanical Data
STV9325
7
Package Mechanical Data
Figure 13: 7-pin Heptawatt Package
L E L1 M1 A C D1 L2 L5 L3
E E1 F
D
M H2
V4
L9
H3
Dia.
G
G1
G2
F L10 L11 L7 L6 L4 H2
Table 1: Heptawatt Package mm Dim. Min.
A C D D1 E E1 F G G1 G2 H2 H3 L 10.05 16.70 16.90 2.40 1.20 0.35 0.70 0.60 2.34 4.88 7.42 2.54 5.08 7.62
inches Max.
4.8 1.37 2.80 1.35 0.55 0.97 0.80 2.74 5.28 7.82 10.40 10.40 17.10 0.396 0.657 0.668 0.094 0.047 0.014 0.028 0.024 0.095 0.193 0.295 0.100 0.200 0.300
Typ.
Min.
Typ.
Max.
0.189 0.054 0.110 0.053 0.022 0.038 0.031 0.105 0.205 0.307 0.409 0.409 0.673
12/14
STV9325
Table 1: Heptawatt Package (Continued) mm Dim. Min.
L1 L2 L3 L4 L5 L6 L7 L9 L10 L11 M M1 V4 Dia. 3.65 3.85 2.10 4.30 2.55 4.83 2.80 5.08 2.60 15.10 6.00 2.80 15.50 6.35 0.20 2.70 4.80 3.05 5.33 40 (Typ.) 0.144 0.082 0.169 0.100 0.190 21.24 22.27
Package Mechanical Data
inches Max.
21.84 22.77 1.29 3.00 15.80 6.60 0.102 0.594 0.0236 0.110 0.610 0.250 0.008 0.106 0.190 0.110 0.200 0.120 0.210 0.152
Typ.
14.92 21.54 22.52
Min.
0.386 0.877
Typ.
0.587 0.848 0.891
Max.
0.860 0.896 0.051 0.118 0.622 0.260
13/14
Revision History
STV9325
8
Revision History
Table 2: Summary of Modifications Version
1.0 1.1 1.2 1.3 1.4 1.5
Date
April 2003 April 2003 November 2003 December 2003 April 2004 June 2004 First Issue.
Description
Correction to Section 4.1.1.2: Peak Current. Creation of new title, Section 4.3.4: Secondary Breakdown Diagrams. Datasheet status changed to preliminary data. Modification to Figure 11. Flyback voltage value changed on page 1. Datasheet status changed to datasheet.
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics. The ST logo is a registered trademark of STMicroelectronics All other names are the property of their respective owners (c) 2004 STMicroelectronics - All rights reserved STMicroelectronics GROUP OF COMPANIES Australia - Belgium - Brazil - Canada - China - Czech Republic - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan - Malaysia - Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States www.st.com
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