STMICROELECTRONICS TDA7374B

TDA7374B
DUAL BRIDGE AUDIO AMPLIFIER FOR CAR RADIO
MINIMUM EXTERNAL COMPONENT COUNT
NO BOOTSTRAP CAPACITORS
NO BOUCHEROT CELLS
CLIP DETECTOR OUTPUT
HIGH OUTPUT POWER
FIXED GAIN
VERY LOW STAND-BY CURRENT (1µA typ)
NO SWITCH ON/OFF NOISE
PROTECTIONS:
OUTPUT AC/DC SHORT CIRCUIT TO GND
AND TO VS
VERY INDUCTIVE LOADS
OVERRATING CHIP TEMPERATURE
LOAD DUMP VOLTAGE
FORTUITOUS OPEN GND
REVERSE BATTERY
ESD
MULTIWATT 15
ORDERING NUMBERS: TDA7374BV
DESCRIPTION
The TDA7374B is a new technology class AB
Audio Dual Bridge Power Amplifier in Multiwatt
package designed for car radio applications.
Thanks to the fully complementary PNP/NPN output configuration the high power performances of
the TDA7374B are obtained without bootstrap capacitors.
TEST AND APPLICATION CIRCUIT
April 1995
1/13
TDA7374B
PIN CONNECTION (Top view)
ABSOLUTE MAXIMUM RATINGS
Symbol
Value
Unit
VS
DC Supply Voltage
28
V
VOP
Operating Supply Voltage
18
V
Peak Supply Voltage (t = 50ms)
50
V
IO
Output Peak Current (not rep. t = 100µs)
4.5
A
IO
Output Peak Current (rep. f > 10Hz)
3.5
A
Power Dissipation (Tcase = 85°C)
36
W
-40 to 150
°C
VPEAK
Ptot
Tstg, Tj
Parameter
Storage and Junction Temperature
THERMAL DATA
Symbol
Rth j-case
2/13
Description
Thermal Resistance Junction-case
Max
Value
Unit
1.8
°C/W
TDA7374B
ELECTRICAL CHARACTERISTICS (Refer to the test circuit; VS = 14.4V; RL = 4Ω, Tamb = 25°C,
f = 1kHz, unless otherwise specified)
Symbol
Parameter
VS
Supply Range
Id
Total Quiescent Drain Current
Test Condition
8
Output Power
R L = 4Ω; THD = 10%
R L = 4Ω PO = 0.1 to 10W
CT
Cross-Talk
f = 1kHz
f = 10kHz
R IN
Input Impedance
d
Voltage Gain
Voltage Gain Match.
EIN
Input Noise Voltage
R g = 0 to 10kΩ
Supply Voltage Rejection
R g = 0; f = 100Hz
f = 10kHz
ISB
VSB OFF
ST-BY Off Threshold Voltage
VOS
21
W
%
dB
dB
KΩ
dB
1
dB
10
µV
µV
3.5
48
dB
55
60
ST-BY Current
ST-BY On Threshold Voltage
V
mA
26
Stand-by Attenuation
VSB ON
18
0.5
Weight A
22Hz to 22KHz
Unit
150
10
GV
ASB
17
Max.
65
55
GV
SVR
Typ.
RL = ∞
Distortion
PO
Min.
dB
µA
1
1.5
V
200
mV
3.5
V
Output Offset Voltage
ICD OFF
Clipping Detector ”OFF”
Output Average Current
THD = 1% (*)
100
µA
ICD ON
Clipping Detector ”ON”
Output Average Current
THD = 10% (*)
190
µA
(*) Pin 10 Pulled-up to 5V with 10kΩ; RL = 4Ω
3/13
TDA7374B
TEST AND APPLICATION CIRCUIT
P.C. BOARD AND COMPONENT LAYOUT (1:1 scale)
B
4/13
TDA7374B
Figure 1: Quiescent Drain Current vs. Supply
Voltage
Figure 2: Quiescent Output Voltage vs. Supply
Voltage
Figure 3: Output Power vs. Supply Voltage
Figure 4: Distortion vs. Output Power
Figure 5: Output Power vs. Frequency
Figure 6: Supply Voltage Rejection vs.
Frequency for a Different values of C6
Capacitor
Rg
5/13
TDA7374B
Figure 7: Cross-Talk vs. Frequency
Figure 8: En Input vs. Rg
Rg
Rg
Figure 9: Stand-by Attenuation vs. Threshold
Voltage
Figure 10: Stand-by Attenuation vs. Input Voltage
Figure 11: Clipping Detector Average Current
(Pin 10) vs. Distortion
Figure 12: Total Power Dissipation and
Efficiency vs. Output Power
6/13
TDA7374B
OUTPUT STAGE
The fully complementary output stage was made
possible by the development of a new component: the ST exclusive power ICV PNP.
A novel design based upon the connection shown
in fig. 13 has then allowed the full exploitation of
its possibilities.
Figure 13: The new Output Stage
The clear advantages this new approach has over
classical output stages are as follows:
1 - Rail-to-Rail Output Voltage Swing With No
Need Of Bootstrap Capacitors.
The output swing is limited only by the Vcesat of
the output transistors, which are in the range of
0.6 Ohm each.
Classical solutions adopting composite PNP-NPN
for the upper output stage have higher saturation
loss on the top side of the waveform. This unbalanced saturation causes a significant power reduction. The only way to recover power consists
of the addition of expensive bootstrap capacitors.
2 - Absolute Stability Without Any External
Compensation.
Referring to the circuit of Fig. 13 the gain
VOUT/VIN is greater than unity, approximately 1 +
R2/R1. The DC Output (VCC/2) is fixed by an auxiliary amplifier common to all the channels).
By controlling the amount of this local feedback it
is possible to force the loop gain (A * β) to less
than unity at frequency for which the phase shift
is 180 Deg. This means that the output buffer is
intrinsically stable and not prone to oscillation.
Most remarkably, the above feature has been
achieved in spite of the very low closed loop gain
of the amplifier.
In contrast, with the classical PNP-NPN stage,
the solution adopted for reducing the gain at high
frequencies makes use of external RC networks,
namely the Boucherot cells.
OTHER OUTSTANDING CHARACTERISTICS:
Clipping Detector Output
The TDA7374B is equipped with an internal circuit able to detect the output stage saturation providing a proper current sinking into a open collector output (pin 10) when a certain distortion level
is reached at each output.
This particular function allows gain compression
facility whenever the amplifier is overdriven, thus
obtaining high quality sound at all listening levels.
Figure 14: Clipping Detection Waveforms
7/13
TDA7374B
Offset Control
The quiescent output voltage must be as close as
possible to its nominal value, so that less undistorted power would be available.
For this reason an input bias current compensation is implemented to riduce the voltage drop
across the input resistors, which appears amplified at the outputs.
Gain Internally Fixed to 26dB
Advantages of this design choice are in terms of:
components and space saving
output noise, supply voltage rejection and distortion optimization.
Silent Turn On/Off and Muting/Stand-by Function
The stand-by can be easily activated by means of
a CMOS level applied to pin 7 through a RC filter.
Under stand-by condition the device is turned off
completely (supply current= 1 µA TYP ; output attenuation= 90 dB TYP).
Every ON/OFF operation is virtually pop free.
Furthermore, at turn-on the device stays in muting
condition for a time determined by the value assigned to the SVR capacitor (T= Csvr * 7,000).
While in muting the device outputs becomes insensitive to any kinds of signal that may be present at the input terminals. In other words every
transient coming from previous stages produces
no unpleasantacoustic effect to the speakers.
Another situation under which the device is totally
muted is whenever the supply voltage drops
lower than 7V. This is helpful to pop suppression
during the turn-off by battery switch.
BUILT-IN PROTECTION SYSTEMS
Full Protection of Device and Loudspeakers
Against AC/DC Short Circuits (to Gnd, to Vs,
across the Speakers).
Reliable and safe operation in presence of all
kinds of short circuit involving the outputs is assured by a built-in protection system that operates
in the following way:
In case of overload, a SCR is activated as soon
as the current flowing through the output transistors overcomes a preset threshold value depending on the chip temperature. The SCR causes an
interruption of the supply current of the power
transistor.
Load Dump Voltage Surge
The TDA 7374 has a circuit which enables it to
withstand a voltage pulse train on pins 3 and 13,
of the type shown in fig. 16.
If the supply voltage peaks to more than 50V,
8/13
then an LC filter must be inserted between the
supply and pins 3 and 13, in order to assure that
the pulses at pins 3 and 13 will be held within the
limits shown.
A suggested LC network is shown in fig. 15.
With this network, a train of pulses with amplitude
up to 120V and width of 2ms can be applied at
point A. This type of protection is ON when the
supply voltage (pulse or DC) exceeds 18V. For
this reason the maximum operating supply voltage is 18V.
Figure 15
Polarity Inversion
Figure 16
High current (up to 10A) can be handled by the
device with no damage for a longer period than
the blow-out time of a quick 2A fuse (normally
connected in series with the supply). This features is added to avoid destruction, if during fitting
to the car, a mistake on the connection of the
supply is made.
Open Ground
When the radio is in the ON condition and the
ground is accidentally opened, a standard audio
amplifier will be damaged. On the TDA7374B protection diodes are included to avoid any damage.
Inductive Load
A protection diode is provided to allow use of the
TDA7374B with inductive loads.
TDA7374B
DC Voltage
The maximum operating DC voltage for the
TDA7374B is 18V.
However the device can withstand a DC voltage
up to 28V with no damage. This could occur during winter if two batteries are series connected to
crank the engine.
Figure 17: Maximum Allowable Power
Dissipation vs. Ambient Temperature
Thermal Shut-down
The presence of a thermal limiting circuit offers
the following advantages:
1)an overload on the output (even if it is permanent), or an excessive ambient temperature
can be easily withstood.
2)the heatsink can have a smaller factor of
safety compared with that of a conventional
circuit. There is no device damage in case of
excessive junction temperature: all happens
is that Po (and therefore Ptot) and Id are reduced.
The maximum allowable power dissipation depends upon the size of the external heatsink (i.e.
its thermal resistance); Fig. 17 shows the dissipable power as a function of ambient temperature
for different thermal resistance.
Loudspeaker Protection
The TDA7374B guarantees safe operations even
for the loudspeaker in case of accidental shortcircuit.
Whenever a single OUT to GND, OUT to VS short
circuit occurs both the outputs are switched OFF
so limiting dangerous DC current flowing through
the loudspeaker.
9/13
TDA7374B
CLIPPING DETECTOR
Fig 19 shows an application using the TDA7374B
in combination with the SGS-THOMSON audioprocessor TDA7302.
The output clipping is recognized by the microprocessor (in this application it is simulated by a PC).
The detailed way to operate of the system is represented by the flow-chart of fig.18.
The controller detects when the clipping is active
(minimun detection width fixed by a C29 = 12 nF
external capacitor), and reduces the volume (or
bass ) by step of 2 dB (with a programmable waiting time), until no more clipping is detected.
Then the controller waits for a programmable time
before increasing the volume again by step of 2
dB until clipping is again detected or the panel selected volume is reached.
Practical advantages of this application is a better
sound quality deriving from operation under no
clipping conditions, which also means the availability of higher undistorted power.
Figure: 18: Clipping Detector Control Routine
10/13
WHAT IS NEEDED FOR A DEMONSTRATION
- a XT or AT IBM compatible PC, supplied with
EGA card
- a SGS-THOMSON audioprocessor application disk
- a TDA 7302 + TDA7374B board
- a connector from audioprocessor board to PC
parallel port
GENERAL INFORMATION
In the application shown in fig 18 the TDA7302
audioprocessor works on PC XT or AT IBM compatible.
Control is accomplished by serial bus ( S-bus or
I2C-bus or SPI bus) sent to the test board through
the PC parallel port.
The PC simulates the behaviour of the microprocessor in a real application (for example in a car
radio) and the buffer is necessary only in this application for protecting the PC.
TDA7374B
TDA7374B
Figure 19: Application with TDA7302 + TDA7374B
11/13
TDA7374B
MULTIWATT15 (Vertical) PACKAGE MECHANICAL DATA
DIM.
mm
MIN.
TYP.
MIN.
TYP.
MAX.
A
5
0.197
B
2.65
0.104
C
1.6
D
0.063
1
0.039
E
0.49
0.55
0.019
0.022
F
0.66
0.75
0.026
0.030
G
1.02
1.27
1.52
0.040
0.050
0.060
G1
17.53
17.78
18.03
0.690
0.700
0.710
H1
19.6
0.772
H2
12/13
inch
MAX.
20.2
0.795
L
21.9
22.2
22.5
0.862
0.874
L1
21.7
22.1
22.5
0.854
0.870
0.886
L2
17.65
18.1
0.695
L3
17.25
17.5
17.75
0.679
0.689
0.699
L4
10.3
10.7
10.9
0.406
0.421
0.429
L7
2.65
2.9
0.104
M
4.25
4.55
4.85
0.167
0.179
M1
4.63
5.08
5.53
0.182
0.200
S
1.9
2.6
0.075
0.102
S1
1.9
2.6
0.075
0.102
Dia1
3.65
3.85
0.144
0.152
0.886
0.713
0.114
0.191
0.218
TDA7374B
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics 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 SGS-THOMSON Microelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied.
SGS-THOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of SGS-THOMSON Microelectronics.
 1995 SGS-THOMSON Microelectronics - All Rights Reserved
SGS-THOMSON Microelectronics GROUP OF COMPANIES
Australia - Brazil - France - Germany - Hong Kong - Italy - Japan - Korea - Malaysia - Malta - Morocco - The Netherlands - Singapore Spain - Sweden - Switzerland - Taiwan - Thaliand - United Kingdom - U.S.A.
13/13