STMICROELECTRONICS TDA7360HS

TDA7360

22W BRIDGE / STEREO AUDIO AMPLIFIER
WITH CLIPPING DETECTOR
VERY FEW EXTERNAL COMPONENTS
NO BOUCHEROT CELLS
NO BOOSTRAP CAPACITORS
HIGH OUTPUT POWER
NO SWITCH ON/OFF NOISE
VERY LOW STAND-BY CURRENT
FIXED GAIN (20dB STEREO)
PROGRAMMABLE TURN-ON DELAY
CLIPPING DETECTOR
Protections:
OUTPUT AC-DC SHORT CIRCUIT
GROUND AND TO SUPPLY VOLTAGE
VERY INDUCTIVE LOADS
LOUDSPEAKER PROTECTION
OVERRATING CHIP TEMPERATURE
LOAD DUMP VOLTAGE
FORTUITOUS OPEN GROUND
ESD
MULTIWATT11V
MULTIWATT11H
ORDERING NUMBERS:
TDA7360
TDA7360HS
TO
DESCRIPTION
The TDA7360 is a new technology class AB

Audio Power Amplifier in the Multiwatt package
designed for car radio applications.
Thanks to the fully complementary PNP/NPN output configuration the high power performance of
the TDA7360 is obtained without bootstrap capacitors.
A delayed turn-on mute circuit eliminates audible
on/off noise, and a novel short circuit protection
system prevents spurious intervention with highly
inductive loads.
The device provides a circuit for the detection of
clipping in the output stages. The output, an open
collector, is able to drive systems with automatic
volume control.
APPLICATION CIRCUIT (BRIDGE)
October 1998
1/22
This is advanced information on a new product now in development or undergoing evaluation. Details are subject to change without notice.
TDA7360
PIN CONNECTION (Top view)
ABSOLUTE MAXIMUM RATINGS
Symbol
Parameter
Test Conditions
Unit
VS
Operating Supply Voltage
18
V
VS
DC Supply Voltage
28
V
VS
Peak Supply Voltage (for t = 50ms)
50
V
Io
Output Peak Current (non rep. for t = 100µs)
5
A
Io
Output Peak Current (rep. freq. > 10Hz)
4
A
Ptot
Power Dissipation at Tcase = 85°C
36
W
Tstg ,TJ
Storage and Junction Temperature
-40 to 150
°C
THERMAL DATA
Symbol
Rth j-case
2/22
Description
Thermal Resistance Junction-case
Max
Value
Unit
1.8
°C/W
TDA7360
ELECTRICAL CHARACTERISTICS (Refer to the test circuits, Tamb = 25°C, VS = 14.4V, f = 1KHz unless
otherwise specified)
Symbol
Parameter
VS
Supply Voltage Range
Id
Total Quiescent Drain Current
A SB
Stand-by attenuation
ISB
Stand-by Current
ICO
Clip Detector Average Current
Test Condition
Min.
Typ.
8
stereo configuration
60
Pin 2 pull up to 5V
with 10KΩ
d = 1%
d = 5%
Max.
Unit
18
V
120
mA
100
µA
80
dB
70
µA
130
µA
12
11
8
6.5
W
W
W
W
STEREO
PO
d
SVR
CT
Output Power (each channel)
d = 10%
R L = 1.6Ω
R L = 2Ω
R L = 3.2Ω
R L = 4Ω
7
Distortion
PO = 0.1 to 4W R L = 3.2Ω
Supply Voltage Rejection
R g = 10KΩ
f = 100Hz
Crosstalk
f = 1KHz
f = 10KHz
C3 = 22µF
C3 = 100µF
0.05
62
55
dB
dB
KΩ
45
RI
Input Resistance
50
Voltage Gain
20
GV
Voltage Gain Match
EIN
Input Noise Voltage
Rg = 50Ω
R g = 10KΩ
Rg = ∞
%
dB
dB
GV
22 Hz to 22KHz
0.5
45
2.5
3
3.5
dB
1
dB
5
7
µV
µV
250
mV
BRIDGE
VOS
Output Offset Voltage
Po
Output Power
d
d = 10%; RL = 4Ω
d = 10%; RL = 3.2Ω
16
Distortion
Po = 0.1 to 10W; RL = 3.2Ω
Supply Voltage Rejection
R g = 10KΩ
f = 100Hz
0.05
1
%
62
RI
Input Resistance
50
KΩ
GV
Voltage Gain
26
dB
EIN
Input Noise Voltage
3.5
4
µV
µV
22Hz to 22KHz
Rg = 50Ω
R g = 10KΩ
45
W
W
dB
dB
SVR
C3 = 22µF
C3 = 100µF
20
22
3/22
TDA7360
Figure 1: STEREO Test and Appication Circuit
1000µF
1000µF
Figure 2: P.C. Board and Component Layout (STEREO) of the circuit of fig. 1 (1:1 scale)
4/22
TDA7360
Figure 3: BRIDGE Test and Appication Circuit
Figure 4: P.C. Board and Layout (BRIDGE) of the circuit of fig. 3 (1:1 scale)
5/22
TDA7360
RECOMMENDED VALUES OF THE EXTERNAL COMPONENTS (ref to the Stereo Test and Application Circuit)
Component
Recommended
Value
C1
0.22µF
C2
0.22µF
Larger than the Recomm.
Value
Smaller than the Recomm.
Value
Input
Decoupling
(CH1)
—
—
Input
Decoupling
(CH2)
—
—
Purpose
C3
100µF
Supply Voltage
Rejection
Filtering
Capacitor
Longer Turn-On Delay Time
- Worse Supply Voltage Rejection.
- Shorter Turn-On Delay Time
- Danger of Noise (POP)
C4
22µF
Stand-By
ON/OFF
Delay
Delayed Turn-Off by Stand-By
Switch
Danger of Noise (POP)
C5
220µF (min)
C6
100nF (min)
C7
2200µF
Supply By-Pass
Supply By-Pass
Output
Decoupling
CH2
Danger of Oscillations
Danger of Oscillations
-Decrease ofLow Frequency CutOff - Increase of Low Frequency Cut Off
- Longer Turn On Delay
- Shorter Turn On Delay
Figure 5: Output Power vs. Supply Voltage
(Stereo)
Figure 6: Output Power vs. Supply Voltage
(Stereo)
Figure 7: Output Power vs. Supply Voltage
(Stereo)
Figure 8: Output Power vs. Supply Voltage
(Bridge)
6/22
TDA7360
Figure 9: Output Power vs. Supply Voltage
(Bridge)
Figure 10: Drain Current vs Supply Voltage
(Stereo)
Figure 11: Distortion vs Output Power (Stereo)
Figure 12: Distortion vs Output Power (Stereo)
Figure 13: Distortion vs Output Power (Stereo)
Figure 14: Distortion vs Output Power (Bridge)
7/22
TDA7360
Figure 15: Distortion vs. Output Power
Figure 16: SVR vs. Frequency & C3 (Stereo)
Rg
Figure 17: SVR vs. Frequency & C3 (Bridge)
Figure 18: Crosstalk vs. Frequency (Stereo)
Rg
Rg
Figure 19: Power Dissipation & Efficiency vs.
Output Power (Stereo)
8/22
Figure 20: Power Dissipation & Efficiency vs.
Output Power (Stereo)
TDA7360
Figure 21: Power Dissipation & Efficiency vs.
Output Power (Bridge)
Figure 22: Power Dissipation & Efficiency vs.
Output Power (Bridge)
TO MINIMIZE THE OUTPUT NOISE AND OPTIMIZE SVR
SILENT MUTE/ST-BY FUNCTION FEATURING ABSENCE OF POP ON/OFF NOISE
HIGH SVR
STEREO/BRIDGE OPERATION WITHOUT
ADDITION OF EXTERNAL COMPONENT
AC/DC SHORT CIRCUIT PROTECTION (TO
GND, TO VS, ACROSS THE LOAD)
LOUDSPEAKER PROTECTION
DUMP PROTECTION
ESD PROTECTION
BLOCK DESCRIPTION
Polarization
The device is organized with the gain resistors directly connected to the signal ground pin i.e. without gain capacitors (fig. 23).
The non inverting inputs of the amplifiers are connected to the SVR pin by means of resistor dividers, equal to the feedback networks. This allows
the outputs to track the SVR pin which is sufficiently slow to avoid audible turn-on and turn-off
transients.
SVR
The voltage ripple on the outputs is equal to the
one on SVR pin: with appropriate selection of
CSVR, more than 60dB of ripple rejection can be
obtained.
AMPLIFIER ORGANIZATION
The TDA7360 has been developed taking care of
the key concepts of the modern power audio amplifier for car radio such as: space and costs saving due to the minimized external count, excellent
electrical performances, flexibility in use, superior
reliability thanks to a built-in array of protections.
As a result the following performances has been
achieved:
NO NEED OF BOOTSTRAP CAPACITORS
EVEN AT THE HIGHEST OUTPUT POWER
LEVELS
ABSOLUTE STABILITY WITHOUT EXTERNAL COMPENSATION THANKS TO THE INNOVATIVE OUT STAGE CONFIGURATION,
ALSO ALLOWING INTERNALLY FIXED
CLOSED LOOP LOWER THAN COMPETITORS
LOW GAIN (20dB STEREO FIXED WITHOUT
ANY EXTERNAL COMPONENTS) IN ORDER
Delayed Turn-on (muting)
The CSVR sets a signal turn-on delay too. A circuit
is included which mutes the device until the voltage on SVR pin reaches ~2.5V typ. (fig. 25). The
mute function is obtained by duplicating the input
differential pair (fig. 24): it can be switched to the
signal source or to an internal mute input. This
feature is necessary to prevent transients at the
inputs reaching the loudspeaker(s) immediately
after power-on).
Fig. 25 represents the detailed turn-on transient
with reference to the stereo configuration.
At the power-on the output decoupling capacitors
are charged through an internal path but the device itself remains switched off (phase 1 of the
represented diagram).
When the outputs reach the voltage level of about
1V (this means that there is no presence of short
circuits) the device switches on, the SVR capacitor starts charging itself and the output tracks exactly the SVR pin.
During this phase the device is muted until the
SVR reaches the ”Play” threshold (~2.5V typ.), after that the music signal starts being played.
9/22
TDA7360
Stereo/Bridge Switching
There is also no need for external components for
changing from stereo to bridge configuration (figg.
23-26). A simple short circuit between two pins allows phase reversal at one output, yet maintaining the quiescent output voltage.
Stand-by
The device is also equipped with a stand-by funcFigure 23: Block Diagram; Stereo Configuration
Figure 24: Mute Function Diagram
10/22
tion, so that a low current, and hence low cost
switch, can be used for turn on/off.
Stability
The device is provided with an internal compensation wich allows to reach low values of closed
loop gain.
In this way better performances on S/N ratio and
SVR can be obtained.
TDA7360
Figure 25: Turn-on Delay Circuit
11/22
TDA7360
Figure 26: Block Diagram; Bridge Configuration
CLIP DETECTOR
The TDA7360 is equipped with an internal circuit
able to detect the output stage saturation providing a proper current sinking into an open collector
out. (pin2) when a certain distortion level is
reached at each output. This particular function
allows compression facility whenever the amplifier
is overdriven, so obtaining high quality sound at
all listening levels.
Figure 27: Dual Channel Distortion Detector
Figure 28: Output at Clipping Detector Pin vs.
Signal Distortion
12/22
TDA7360
Figure 29: ICV - PNP Gain vs. IC
Figure 30: ICV - PNP VCE(sat) vs. I C
OUTPUT STAGE
Poor current capability and low cutoff frequency
are well known limits of the standard lateral PNP.
Composite PNP-NPN power output stages have
been widely used, regardless their high saturation
drop. This drop can be overcome only at the expense of external components, namely, the bootstrap capacitors. The availability of 4A isolated
collector PNP (ICV PNP) adds versatility to the
design. The performance of this component, in
terms of gain, VCEsat and cut-off frequency, is
shown in fig. 29, 30, 31 respectively. It is realized
in a new bipolar technology, characterized by topbottom isolation techniques, allowing the implementation of low leakage diodes, too. It guarantees BVCEO > 20V and BVCBO > 50V both for
NPN and PNP transistors. Basically, the connection shown in fig. 32 has been chosen. First of all
because its voltage swing is rail-to-rail, limited
only by the VCEsat of the output transistors,
which are in the range of 0.3Ω each. Then, the
gain VOUT/VIN is greater than unity, approximately 1+R2/R1. (VCC/2 is fixed by an auxiliary
amplifier common to both channel). It is possible,
controlling the amount of this local feedback, to
force the loop gain (A * β) to less than unity at frequencies for which the phase shift is 180°. This
means that the output buffer is intrinsically stable
and not prone to oscillation.
Figure 32: The New Output Stage
Figure 31: ICV - PNP cut-off frequency vs. IC
In contrast, with the circuit of fig. 33, the solution
adopted to reduce the gain at high frequencies is
the use of an external RC network.
AMPLIFIER BLOCK DIAGRAM
The block diagram of each voltage amplifier is
shown in fig. 34. Regardless of production
spread, the current in each final stage is kept low,
with enough margin on the minimum, below which
cross-over distortion would appear.
13/22
TDA7360
Figure 33: A Classical Output Stage
Figure 34: Amplifier Block Diagram
BUILT-IN PROTECTION SYSTEMS
Short Circuit Protection
The maximum current the device can deliver can
be calculated by considering the voltage that may
be present at the terminals of a car radio amplifier
and the minimum load impedance.
Apart from consideration concerning the area of
the power transistors it is not difficult to achieve
peak currents of this magnitude (5 A peak).
However, it becomes more complicated if AC and
DC short circuit protection is also required.In particular, with a protection circuit which limits the
output current following the SOA curve of the output transistors it is possible that in some conditions (highly reactive loads, for example) the protection circuit may intervene during normal
operation. For this reason each amplifier has
been equipped with a protection circuit that intervenes when the output current exceeds 4A
Fig 35 shows the protection circuit for an NPN
power transistor (a symmetrical circuit applies to
PNP).The VBE of the power is monitored and
gives out a signal,available through a cascode.
This cascode is used to avoid the intervention of
the short circuit protection when the saturation is
14/22
below a given limit.
The signal sets a flip-flop which forces the amplifier
outputs into a high impedance state.
In case of DC short circuit when the short circuit
is removed the flip-flop is reset and restarts the
circuit (fig. 39). In case of AC short circuit or load
shorted in Bridge configuration, the device is continuously switched in ON/OFF conditions and the
current is limited.
Figure 35: Circuitry for Short Circuit Detection
TDA7360
Load Dump Voltage Surge
The TDA 7360 has a circuit which enables it to
withstand a voltage pulse train on pin 9, of the type
shown in fig. 37.
If the supply voltage peaks to more than 50V, then
an LC filter must be inserted between the supply
and pin 9, in order to assure that the pulses at pin 9
will be held within the limits shown.
A suggestedLC network is shown in fig. 36.
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 supplyvoltage
(pulse or DC) exceeds 18V. For this reason the maximum operating supply voltage is 18V.
Figure 36
Figure 37
Polarity Inversion
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 TDA7360 protection diodes are included to avoid any damage.
ing winter if two batteries are series connected to
crank the engine.
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 the 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. 38 shows the dissipable power as a function of ambient temperature
for different thermal resistance.
Figure 38: Maximum Allowable Power
Dissipation vs. Ambient Temperature
Loudspeaker Protection
The TDA7360 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.
Figure 39: Restart Circuit
DC Voltage
The maximum operating DC voltage for the
TDA7360 is 18V.
However the device can withstand a DC voltage
up to 28V with no damage. This could occur dur15/22
TDA7360
APPLICATION HINTS
This section explains briefly how to get the best
from the TDA7360 and presents some application
circuits with suggestions for the value of the components.These values can change depending on
the characteristics that the designer of the car radio wants to obtain,or other parts of the car radio
that are connected to the audio block.
To optimize the performance of the audio part it is
useful (or indispensable) to analyze also the parts
outside this block that can have an interconnection with the amplifier.
This method can provide components and system
cost saving.
Reducing Turn On-Off Pop
The TDA7360 has been designed in a way that
the turn on(off) transients are controlled through
the charge(discharge) of the Csvr capacitor.
As a result of it, the turn on(off) transient spectrum contents is limited only to the subsonic
range.The following section gives some brief
notes to get the best from this design feature(it
will refer mainly to the stereo application which
appears to be in most cases the more critical from
the pop viewpoint.The bridge connection in
fact,due to the common mode waveform at the
outputs,does not give pop effect).
TURN-ON
Fig 40 shows the output waveform (before and
after the ”A” weighting filter) compared to the
value of Csvr.
Better pop-on performance is obtained with
higher Csvr values (the recommended range is
from 22uF to 220uF).
The turn-on delay (during which the amplifier is in
mute condition) is a function essentially of : Cout ,
Csvr .
Being:
T1 ≈ 120 • Cout
T2 ≈ 1200 • Csvr
The turn-on delay is given by:
T1+T2 STEREO
T2 BRIDGE
The best performance is obtained by driving the
st-by pin with a ramp having a slope slower than
2V/ms
16/22
Figure 40:
a) Csvr = 22 µF
b) Csvr = 47 µF
c) Csvr = 100 µF
TDA7360
TURN-OFF
A turn-off pop can occur if the st-by pin goes low
with a short time constant (this can occur if other
car radio sections, preamplifiers,radio.. are supplied through the same st-by switch).
This pop is due to the fast switch-off of the internal current generator of the amplifier.
If the voltage present across the load becomes
rapidly zero (due to the fast switch off) a small
pop occurs, depending also on Cout,Rload.
The parameters that set the switch off time constant of the st-by pin are:
♦ the st-by capacitor (Cst-by)
♦ the SVR capacitor (Csvr)
♦ resistors connected from st-by pin to ground
(Rext)
The time constant is given by :
T ≈ Csvr • 2000Ω // Rext + Cst-by • 2500Ω // Rext
The suggested time constants are :
T > 120ms with Cout=1000µF,RL = 4ohm,stereo
T > 170ms with Cout=2200µF,RL = 4ohm,stereo
If Rext is too low the Csvr can become too high
and a different approach may be useful (see next
section).
Figg 41, 42 show some types of electronic
switches (µP compatible) suitable for supplying
the st-by pin (it is important that Qsw is able to
saturate with VCE ≤ 150mV).
Also for turn off pop the bridge configuration is suFigure 41
perior, in particular the st-by pin can go low faster.
GLOBAL APPROACH TO SOLVING POP
PROBLEM BY USING THE MUTING/TURN ON
DELAY FUNCTION
In the real case turn-on and turn-off pop problems
are generated not only by the power amplifier,but
also (very often) by preamplifiers,tone controls,radios etc. and transmitted by the power amplifier to
the loudspeaker.
A simple approach to solving these problems is to
use the mute characteristics of the TDA7360.
If the SVR pin is at a voltage below 1.5 V, the
mute attenuation (typ) is 30dB .The amplifier is in
play mode when Vsvr overcomes 3.5 V.
With the circuit of fig 43 we can mute the amplifier
for a time Ton after switch-on and for a time Toff
after switch-off.During this period the circuitry that
precedes the power amplifier can produce spurious spikes that are not transmitted to the loudspeaker. This can give back a very simple design
of this circuitry from the pop point of view.
A timing diagram of this circuit is illustrated in fig
44. Other advantages of this circuit are:
- A reduced time constant allowance of stand-by
pin turn off.Consequently it is possible to drive all
the car-radio with the signal that drives this pin.
-A better turn-off noise with signal on the output.
To drive two stereo amplifiers with this circuit it is
possible to use the circuit of fig 45.
Figure 42
17/22
TDA7360
Figure 43
Figure 44
18/22
TDA7360
Figure 45
BALANCED INPUT IN BRIDGE CONFIGURATION
A helpful characteristic of the TDA7360 is that,in
bridge configuration, a signal present on both the
input capacitors is amplified by the same amount
and it is present in phase at the outputs,so this
signal does not produce effects on the load.The
typical value of CMRR is 46 dB.
Looking at fig 46, we can see that a noise signal
from the ground of the power amplifier to the
ground of the hypothetical preamplifier is amplified of a factor equal to the gain of the amplifier
(2 * Gv).
Using a configuration of fig. 47 the same ground
noise is present at the output multiplied by the
factor 2 * Gv/200.
This means less distortion,less noise (e.g. motor
cassette noise ) and/or a simplification of the layout of PC board.
The only limitation of this balanced input is the
maximum amplitude of common mode signals
(few tens of millivolt) to avoid a loss of output
power due to the common mode signal on the
output, but in a large number of cases this signal
is within this range.
Figure 46
Figure 47
19/22
TDA7360
DIM.
mm
MIN.
TYP.
inch
MAX.
MIN.
TYP.
MAX.
A
5
0.197
B
C
2.65
1.6
0.104
0.063
D
1
0.039
E
0.49
F
G
0.88
1.45
G1
16.75
H1
H2
19.6
L
21.9
22.2
22.5
L1
21.7
22.1
L2
17.4
L3
L4
17.25
10.3
L7
2.65
M
M1
S
0.55
0.019
0.022
1.7
0.95
1.95
0.035
0.057
0.067
0.037
0.077
17
17.25
0.659
0.669
0.679
0.862
0.874
0.886
22.5
0.854
0.87
0.886
18.1
0.685
17.5
10.7
17.75
10.9
0.679
0.406
0.689
0.421
0.699
0.429
2.9
0.104
4.25
4.55
4.85
0.167
0.179
0.191
4.73
1.9
5.08
5.43
2.6
0.186
0.075
0.200
0.214
0.102
0.772
20.2
0.795
0.713
0.114
S1
1.9
2.6
0.075
0.102
Dia1
3.65
3.85
0.144
0.152
20/22
OUTLINE AND
MECHANICAL DATA
Multiwatt11 V
TDA7360
DIM.
A
B
C
E
E1
F
G
G.1
G2
G3
G4
G5
H1
H2
L1
L2
L3
L4
L5
(Inner)
L5
(Outer)
L7
R
S
S1
Dia1
MIN.
4.373
mm
TYP.
4.5
0.49
1.007
0.88
1.5
16.82
6.61
13.41
3.2
10.01
19.6
0.515
1.037
0.9
1.7
17.02
6.807
13.61
3.4
10.21
MAX.
4.627
2.65
1.6
0.55
1.07
0.95
1.9
17.22
7.01
13.81
3.6
10.41
19.28
3.61
17.25
10.3
19.58
3.81
17.5
10.6
3.4
3.6
2.65
0.75
1.9
1.9
3.65
inch
TYP.
0.177
0.019
0.040
0.035
0.059
0.662
0.260
0.528
0.126
0.394
0.772
0.020
0.041
0.035
0.067
0.670
0.268
0.536
0.134
0.402
MAX.
0.182
0.104
0.063
0.022
0.042
0.037
0.075
0.678
0.276
13.810
0.142
0.410
20.2
19.88
4.01
17.75
10.9
0.759
0.142
0.679
0.406
0.771
0.150
0.689
0.417
0.795
0.783
0.158
0.699
0.429
3.75
4
0.134
0.148
0.157
3.9
4.2
0.142
0.154
4.200
2.9
1.25
2.6
2.6
3.85
0.104
0.030
0.075
0.075
0.144
1
MIN.
0.172
0.114
0.049
0.102
0.102
0.152
0.039
V
R
OUTLINE AND
MECHANICAL DATA
Multiwatt11 H (Short leads)
V
G5
V
G4
R
A
B
C
L5
V
L1
E
L2
X
G1
L3
H2
L4
N
L7
F
G
H2
G3
G2
DETAIL X
F
E
E1
H1
0.25min
0.50max
Dia.1
R1
P
S1
S
60 to 90
MULT11LHM
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TDA7360
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