Philips Stereo Amplifier TDA6103Q User Manual

INTEGRATED CIRCUITS  
DATA SHEET  
TDA6103Q  
Triple video output amplifier  
March 1994  
Preliminary specification  
File under Integrated Circuits, IC02  
Philips Semiconductors  
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
PINNING  
SYMBOL  
Vi1  
PIN  
DESCRIPTION  
inverting input 1  
1
2
3
4
5
6
7
8
9
V
V
i1  
1
2
3
4
5
6
7
8
9
i2  
i3  
Vi2  
inverting input 2  
inverting input 3  
ground, fin  
V
Vi3  
GND  
Vip  
GND  
non-inverting input  
supply voltage  
cathode output 3  
cathode output 2  
cathode output 1  
V
TDA6103Q  
ip  
VDD  
Voc3  
Voc2  
Voc1  
V
DD  
V
oc3  
V
oc2  
V
oc1  
MGA969  
Fig.2 Pin configuration.  
LIMITING VALUES  
In accordance with the Absolute Maximum Rating System (IEC 134). Voltages measured with respect to GND (pin 4);  
currents as specified in Fig.1; unless otherwise specified.  
SYMBOL  
VDD  
PARAMETER  
supply voltage  
CONDITIONS  
MIN.  
MAX.  
250  
UNIT  
0
0
V
V
V
V
A
Vi  
input voltage  
12  
+6  
VDD  
5
Vidm  
Voc  
differential mode input voltage  
cathode output voltage  
6  
0
IocsmL  
LOW non-repetitive peak cathode  
output current  
flashover discharge = 50 µC  
0
IocsmH  
HIGH non-repetitive peak cathode  
output current  
flashover discharge = 100 nC  
0
10  
A
Tstg  
Tj  
storage temperature  
junction temperature  
electrostatic handling  
human body model (HBM)  
machine model (MM)  
55  
20  
+150  
+150  
°C  
°C  
Ves  
tbf  
tbf  
V
V
HANDLING  
Inputs and outputs are protected against electrostatic discharge in normal handling. However, to be totally safe, it is  
desirable to take normal precautions appropriate to handling MOS devices (see “Handling MOS Devices”).  
QUALITY SPECIFICATION  
Quality specification “SNW-FQ-611 part E” is applicable and can be found in the “Quality reference pocketbook” (ordering  
number 9398 510 34011).  
March 1994  
3
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
THERMAL RESISTANCE  
SYMBOL  
PARAMETER  
THERMAL RESISTANCE  
Rth j-fin  
Rth h-a  
from junction to fin; note 1  
from heatsink to ambient  
11 K/W  
18 K/W  
Note  
1. An external heatsink is necessary.  
Thermal protection  
MGA972  
The internal thermal protection circuit gives a decrease of  
the slew rate at high temperatures: 10% decrease at  
130 °C and 30% decrease at 145 °C (typical values on the  
spot of the thermal protection circuit).  
6
5
P
tot  
(W)  
4
3
2
1
(1)  
(2)  
OUTPUTS  
5 K/W  
Thermal protection circuit  
6 K/W  
0
–50  
0
50  
100  
T
150  
o
(
C)  
amb  
MGA970  
FIN  
(1) Infinite heatsink.  
(2) No heatsink.  
Fig.3 Power derating curves.  
Fig.4 Equivalent thermal resistance network.  
March 1994  
4
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
CHARACTERISTICS  
Operating range: Tj = 20 to 150 °C; VDD = 180 to 210 V; Vip = 1 to 4 V.  
Test conditions (unless otherwise specified): Tamb = 25 °C; VDD = 200 V; Vip = 1.3 V; Voc1 = Voc2 = Voc3 = 12VDD;  
CL = 10 pF (CL consists of parasitic and cathode capacitance); Rth h-a = 18 K/W; measured in test circuit Fig.5.  
SYMBOL  
PARAMETER  
CONDITIONS  
MIN.  
7.0  
TYP.  
9.25  
MAX.  
11.5  
UNIT  
mA  
IDD  
quiescent supply current  
Ibias  
input bias current inverting inputs  
(pins 1, 2 and 3)  
5  
1  
3  
+1  
+1  
+50  
µA  
Ibias  
input bias current non-inverting  
input (pin 5)  
15  
50  
µA  
Vi(offset)  
input offset voltage  
(pins 1, 2 and 3)  
mV  
mV/K  
Vi(offset) differential input offset voltage  
temperature drift between pins 1  
and 5; 2 and 5; 3 and 5  
tbf  
Cicm  
common-mode input capacitance  
(pins 1, 2 and 3)  
5
pF  
pF  
pF  
V
Cicm  
common-mode input capacitance  
(pin 5)  
10  
1
Cidm  
differential mode input capacitance  
between 1 and 5; 2 and 5; 3 and 5  
Voc(min)  
minimum output voltage  
(pins 7, 8 and 9)  
V15 = V25 = V35 = 1 V  
5
10  
Voc(max) maximum output voltage  
(pins 7, 8 and 9)  
V15 = V25 = V35 = 1 V;  
note 1  
VDD 10 VDD 6  
V
GB  
gain-bandwidth product of  
open-loop gain:  
f = 500 kHz  
0.75  
GHz  
V
oc1, 2, 3 / Vi1-5, 2-5, 3-5  
BS  
BL  
tpd  
small signal bandwidth  
(pins 7, 8 and 9)  
Voc(p-p) = 60 V  
Voc(p-p) = 100 V  
6
5
7.5  
7
MHz  
MHz  
ns  
large signal bandwidth  
(pins 7, 8 and 9)  
cathode output propagation delay  
time 50% input to 50% output  
(pins 7, 8 and 9)  
Voc(p-p) = 100 V square  
wave; f < 1 MHz;  
tr = tf = 40 ns (pins 1, 2  
and 3); see Figs 7 and 8  
38  
tp  
difference in cathode output  
propagation time 50% input to  
Voc(p-p) = 100 V square  
wave; f < 1 MHz;  
10  
0
+10  
ns  
50% output (pins 7 and 8, 7 and 9 tr = tf = 40 ns (pins 1, 2  
and 8 and 9)  
and 3)  
tr  
tf  
cathode output rise time 10%  
output to 90% output  
(pins 7, 8 and 9)  
Voc = 50 to 150 V square  
wave; f < 1 MHz; tf = 40 ns  
(pins 1, 2 and 3); see Fig.7  
48  
48  
60  
60  
73  
73  
ns  
ns  
cathode output fall time 90% output Vo = 150 to 50 V square  
to 10% output (pins 7, 8 and 9)  
wave; f < 1 MHz; tr = 40 ns  
(pins 1, 2 and 3); see Fig.8  
March 1994  
5
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
SYMBOL  
PARAMETER  
CONDITIONS  
MIN.  
TYP.  
MAX.  
350  
UNIT  
ns  
ts  
settling time 50% input to  
(99% < output < 101%)  
Voc(p-p) = 100 V square  
wave; f < 1 MHz;  
tr = tf = 40 ns (pins 1, 2  
and 3); see Figs 7 and 8  
SR  
Ov  
slew rate between  
50 V to (VDD 50 V);(pins 7, 8 and square wave (p-p);  
V15 = V25 = V35 = 2 V  
1600  
5
V/µs  
%
9)  
f < 1 MHz; tr = tf = 40 ns  
(pins 1, 2 and 3)  
cathode output voltage overshoot  
(pins 7, 8 and 9)  
Voc(p-p) = 100 V square  
wave; f < 1 MHz;  
tr = tf = 40 ns (pins 1, 2  
and 3); see Figs 7 and 8  
SVRR  
supply voltage rejection ratio  
f < 50 kHz; note 2  
70  
dB  
Notes  
1. See also Fig.6 for the typical low-frequency response of Vi to Voc.  
2. The ratio of the change in supply voltage to the change in input voltage when there is no change in output voltage.  
needed (for this resistor-value, the CRT has to be  
connected to the main PCB). This addition produces an  
increase in the rise- and fall times of approximately 5 ns  
and a decrease in the overshoot of approximately 3%.  
Cathode output  
The cathode output is protected against peak currents  
(caused by positive voltage peaks during high-resistance  
flash) of 5 A maximum with a charge content of 50 µC.  
VDD to GND must be decoupled:  
The cathode is also protected against peak currents  
(caused by positive voltage peaks during low-resistance  
flash) of 10 A maximum with a charge content of 100 nC.  
1. With a capacitor >20 nF with good HF behaviour (e.g.  
foil). This capacitance must be placed as close as  
possible to pins 6 and 4, but definitely within 5 mm.  
The DC voltage of VDD (pin 6) must be within the operating  
range of 180 to 210 V during the peak currents.  
2. With a capacitor >10 µF on the picture tube base print.  
Switch-off behaviour  
Flashover protection  
The switch-off behaviour of the TDA6103Q is controllable.  
This is due to the fact that the output pins of the  
TDA6103Q are still under control of the input pins for  
relative low-power supply voltages (approximately 30 V  
and higher).  
The TDA6103Q incorporates protection diodes against  
CRT flashover discharges that clamp the cathode output  
voltage up to a maximum of VDD + Vdiode. To limit the diode  
current, an external 1.5 kcarbon high-voltage resistor in  
series with the cathode output and a 2 kV spark gap are  
March 1994  
6
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
Test circuit  
C
par  
R4  
V
DD  
100 kΩ  
C11  
100 nF  
C
par  
V
R5  
oc1  
100 kΩ  
C13  
6.8  
pF  
R7  
2 MΩ  
C1  
C7  
6
C12  
3.2  
pF  
probe 1  
1
2
22 µF  
8.2 pF  
R1  
C14  
136  
pF  
V
R8  
100 kΩ  
i1  
C2  
V
9
in1  
1
667 Ω  
22 nF  
C3  
0.987  
mA  
C8  
V
oc2  
TDA6103Q  
22 µF  
C16  
6.8  
pF  
8.2 pF  
R2  
R9  
2 MΩ  
V
V
i2  
i3  
C4  
V
V
8
C15  
3.2  
pF  
in2  
probe 2  
2
667 Ω  
22 nF  
C5  
C17  
136  
pF  
0.987  
mA  
R10  
100 kΩ  
C9  
22 µF  
3
8.2 pF  
R3  
C6  
V
7
in3  
oc3  
3
667 Ω  
C19  
6.8  
pF  
22 nF  
0.987  
mA  
5
R11  
2 MΩ  
C18  
3.2  
pF  
probe 3  
4
C20  
136  
pF  
R12  
100 kΩ  
C10  
100  
nF  
C
par  
1.3 V  
R6  
100 kΩ  
MGA976  
Cpar = 70 fF.  
Fig.5 Test circuit with feedback factor 1150.  
March 1994  
7
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
MGA973  
200  
194  
188  
V
oc  
100  
5
0
0
1.2  
0.633  
0.583  
1.1 1.2  
V  
i
Fig.6 Typical low-frequency (f < 1 MHz) response of Vi1, 2,3 to Voc1, 2,3  
.
x
V
i
0
t
x
t
s
overshoot (in %)  
151  
149  
150  
140  
V
oc  
100  
60  
50  
t
t
r
MGA974  
t
pd  
Fig.7 Output voltage (pins 7, 8 and 9) rising edge as a function of the AC input signal.  
8
March 1994  
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
x
V
i
0
x
t
t
s
150  
140  
oc  
V
100  
overshoot (in %)  
51  
60  
50  
49  
t
t
f
MGA975  
t
pd  
Fig.8 Output voltage (pins 7, 8 and 9) falling edge as a function of the AC input signal.  
March 1994  
9
 
X1  
C3  
R24  
R16  
1
2
3
185 V  
AQUA  
100 k  
R17  
47 Ω  
R5  
R9  
C6  
R25  
1.2 Ω  
V
ff  
10 µF  
(250 V)  
220 Ω  
3.3 kΩ  
4
R10  
680 Ω  
V
(GND)  
100 kΩ  
ff  
R13  
470 Ω  
TDA6103Q  
EHT  
1
2
3
4
5
6
7
8
9
C1  
X3  
R6  
4
3
2
1
C5  
R
G
R7  
R21  
3.3 kΩ  
100  
nF  
1.5 kΩ  
R19  
220  
470 Ω  
B
kR  
kG  
kB  
R12  
680 Ω  
GND  
A51EAL . . X02  
R22  
kΩ  
R15  
470 Ω  
1.5 kΩ  
R20  
1.5  
kΩ  
C4  
220 nF  
R23  
g1 g2 g3  
1.5 kΩ  
C2  
C7  
R4  
2.7 nF  
(500 V)  
R8  
R18  
470 Ω  
3.3 kΩ  
100 kΩ  
R11  
C8  
680 Ω  
2.7 nF  
(500 V)  
optional  
R26  
1.5 kΩ  
MGA977  
R14  
470 Ω  
C9  
1 nF  
(2000 V)  
V
g2  
X2  
AQUA  
X4  
Fig.9 Application diagram.  
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
V
GND  
4
DD  
6
to  
from  
input  
circuit  
differential  
stage  
TDA6103Q  
1,2,3  
(1)  
7,8,9  
V
bias  
from  
input  
circuit  
to  
to  
to  
differential  
stage  
differential  
stage  
differential  
stage  
5
MGA971  
(1) All pins have an energy protection for positive or negative overstress situations.  
Fig.10 Internal pin configuration.  
Dissipation  
Regarding dissipation, distinction must first be made between static dissipation (independent of frequency) and dynamic  
dissipation (proportional to frequency).  
The static dissipation of the TDA6103Q is due to voltage supply currents and load currents in the feedback network and  
CRT.  
The static dissipation equals:  
Pstat = VDD × IDD 3 × Voc × (Voc/Rfb IOC  
)
Rfb = value of feedback resistor.  
IOC = DC-value of cathode current.  
The dynamic dissipation equals:  
Pdyn = 3 × VDD × (CL + Cfb + Cint) × fi × Vo(p-p) ×δ  
CL = load capacitance.  
Cfb = feedback capacitance.  
Cint = internal load capacitance (4 pF).  
fi = input frequency.  
Vo(p-p) = output voltage (peak-to-peak value).  
δ = non-blanking duty-cycle.  
The IC must be mounted on the picture tube base print to minimize the load capacitance (CL).  
March 1994  
11  
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
PACKAGE OUTLINE  
22.00  
21.35  
21.4  
20.7  
15.1  
14.9  
3.85  
3.45  
2.75  
2.50  
(2x)  
3.4  
3.2  
1.75  
1.55  
fin  
8.7  
8.0  
5.9  
5.7  
4.4  
4.2  
18.5  
17.8  
6.48  
6.14  
5
1
2
3
4
6
7
8
9
1.1  
0.7  
0.76  
3.9  
3.4  
0.45  
0.25  
0.47  
0.38  
1.0  
0.3  
1.0  
0.7  
2.54  
(8x)  
2.54  
0.67  
0.50  
0.25  
(9x)  
M
1.40  
1.14  
o
o
65  
55  
1.40  
1.14  
MBC376 - 1  
Dimensions in mm.  
Fig.11 Plastic SIL-bent-to-DIL, medium power with fin, 9-pin (SOT111BE).  
March 1994  
12  
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
SOLDERING  
Plastic single in-line packages  
BY DIP OR WAVE  
The maximum permissible temperature of the solder is  
260 °C; this temperature must not be in contact with the  
joint for more than 5 s. The total contact time of successive  
solder waves must not exceed 5 s.  
The device may be mounted up to the seating plane, but  
the temperature of the plastic body must not exceed the  
specified storage maximum. If the printed-circuit board has  
been pre-heated, forced cooling may be necessary  
immediately after soldering to keep the temperature within  
the permissible limit.  
REPAIRING SOLDERED JOINTS  
Apply the soldering iron below the seating plane (or not  
more than 2 mm above it). If its temperature is below  
300 °C, it must not be in contact for more than 10 s; if  
between 300 and 400 °C, for not more than 5 s.  
DEFINITIONS  
Data sheet status  
Objective specification  
Preliminary specification  
Product specification  
This data sheet contains target or goal specifications for product development.  
This data sheet contains preliminary data; supplementary data may be published later.  
This data sheet contains final product specifications.  
Limiting values  
Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or  
more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation  
of the device at these or at any other conditions above those given in the Characteristics sections of the specification  
is not implied. Exposure to limiting values for extended periods may affect device reliability.  
Application information  
Where application information is given, it is advisory and does not form part of the specification.  
LIFE SUPPORT APPLICATIONS  
These products are not designed for use in life support appliances, devices, or systems where malfunction of these  
products can reasonably be expected to result in personal injury. Philips customers using or selling these products for  
use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such  
improper use or sale.  
March 1994  
13  
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
NOTES  
March 1994  
14  
 
Philips Semiconductors  
Preliminary specification  
Triple video output amplifier  
TDA6103Q  
NOTES  
March 1994  
15  
 
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Uruguay: Coronel Mora 433, MONTEVIDEO,  
Tel. (02)70-4044, Fax. (02)92 0601  
Indonesia: Philips House, Jalan H.R. Rasuna Said Kav. 3-4,  
P.O. Box 4252, JAKARTA 12950,  
Tel. (021)5201 122, Fax. (021)5205 189  
Ireland: Newstead, Clonskeagh, DUBLIN 14,  
Tel. (01)640 000, Fax. (01)640 200  
Italy: Viale F. Testi, 327, 20162 MILANO,  
Tel. (02)6752.1, Fax. (02)6752.3350  
Japan: Philips Bldg 13-37, Kohnan2-chome, Minato-ku, KOKIO 108,  
Tel. (03)3740 5101, Fax. (03)3740 0570  
Korea: (Republic of) Philips House, 260-199 Itaewon-dong,  
For all other countries apply to: Philips Semiconductors,  
International Marketing and Sales, Building BAF-1,  
P.O. Box 218, 5600 MD, EINDHOVEN, The Netherlands,  
Telex 35000 phtcnl, Fax. +31-40-724825  
Yongsan-ku, SEOUL, Tel. (02)794-5011, Fax. (02)798-8022  
Malaysia: No. 76 Jalan Universiti, 46200 PETALING JAYA,  
SELANGOR, Tel. (03)757 5511, Fax. (03)757 4880  
Mexico: Philips Components, 5900 Gateway East, Suite 200,  
EL PASO, TX 79905, Tel. 9-5(800)234-7381, Fax. (708)296-8556  
Netherlands: Postbus 90050, 5600 PB EINDHOVEN,  
Tel. (040)78 37 49, Fax. (040)78 83 99  
New Zealand: 2 Wagener Place, C.P.O. Box 1041, AUCKLAND,  
SCD29  
© Philips Electronics N.V. 1994  
All rights are reserved. Reproduction in whole or in part is prohibited without the  
prior written consent of the copyright owner.  
The information presented in this document does not form part of any quotation  
or contract, is believed to be accurate and reliable and may be changed without  
notice. No liability will be accepted by the publisher for any consequence of its  
use. Publication thereof does not convey nor imply any license under patent- or  
other industrial or intellectual property rights.  
Tel. (09)849-4160, Fax. (09)849-7811  
Norway: Box 1, Manglerud 0612, OSLO,  
Tel. (22)74 8000, Fax. (22)74 8341  
Printed in The Netherlands  
9397 730 00011  
Philips Semiconductors  
 

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