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HTP-420

Ref. No. 3808
042004
SERVICE MANUAL


5.1-CH HOME THEATER SPEAKER PACKAGE
MODEL HTP-420(B)/(S)
Powered Subwoofer
Front Speakers (L / R) Center Speaker Surround Speakers (L / R) "SKW-420"
"SKF-420F" "SKC-420C" "SKM-420S"




Black and Silver models
BMDD 120V AC, 60Hz SMDD 120V AC, 60Hz
BMDC 120V AC, 60Hz SMDC 120V AC, 60Hz
--- --- SMDT 120V AC, 60Hz
BMPA 230-240V AC, 50Hz SMPA 230-240V AC, 50Hz
--- --- SMGT 220-230V AC, 50/60Hz
--- --- SMPT 230-240V AC, 50Hz

SAFETY-RELATED COMPONENT
WARNING!!
COMPONENTS IDENTIFIED BY MARK ON THE
SCHEMATIC DIAGRAM AND IN THE PARTS LIST ARE
CRITICAL FOR RISK OF FIRE AND ELECTRIC SHOCK.
REPLACE THESE COMPONENTS WITH ONKYO
PARTS WHOSE PART NUMBERS APPEAR AS SHOWN
IN THIS MANUAL.
MAKE LEAKAGE-CURRENT OR RESISTANCE
MEASUREMENTS TO DETERMINE THAT EXPOSED
PARTS ARE ACCEPTABLY INSULATED FROM THE
SUPPLY CIRCUIT BEFORE RETURNING THE
APPLIANCE TO THE CUSTOMER.
HTP-420

SPECIFICATIONS



Powered Subwoofer (SKW-420) Center Speaker (SKC-420C)
Type : Bass-reflex with built-in Type : 2 Way Bass-reflex
power amplifier Impedance : 8 ohm
Input sensitivity/impedance : 220 mV / 15 k ohm Maximum input power : 100 W
Maximum output power : 150 W (Dynamic Power) Output sound pressure level : 84 dB/W/m
Frequency response : 30 Hz - 150 Hz Frequency response : 60 Hz - 50 kHz
Cabinet capacity : 1.15 cubic feet (32.5 L) Crossover frequency : 5 kHz
Dimensions (W x H x D) : 9-1/4" x 20-3/8" x 16-3/16" Cabinet capacity : 0.2 cubic feet (5.6 L)
(235 x 518 x 411 mm) Dimensions (W x H x D) : 17-1/8" x 5-1/8" x 7-1/16"
Weight : 28.2 lbs. (12.8 kg) (435 x 130 x 179 mm)
Driver unit : 8 inch Cone Woofer Weight : 7.5 lbs. (3.4 kg)
Power supply : Drivers unit : 4 inch Cone Woofer x 2
America : AC 120 V, 60 Hz 1 inch Balanced Dome tweeter
Others : AC 230-240 V, 50 Hz Terminal : Color-coded push type
AC 220-230 V, 50/60 Hz Other : Magnetic shielding
Power consumption :
America : 75 W
Australia : 77 W
Others : 77 W
Other : Auto Standby function



Front Speaker (SKF-420F) Surround Speaker (SKM-420S)

Type : 2-way Bass-reflex Type : 2-way Bass-reflex
Impedance : 8 ohm Impedance : 8 ohm
Maximum input power : 100 W Maximum input power : 100 W
Output sound pressure level : 84 dB/W/m Output sound pressure level : 82 dB/W/m
Frequency response : 60 Hz - 50 kHz Frequency response : 60 Hz - 50 kHz
Crossover frequency : 5 kHz Crossover frequency : 5 kHz
Cabinet capacity : 0.2 cubic feet (5.6L) Cabinet capacity : 0.08 cubic feet (2.3 L)
Dimensions (W x H x D) : 4-7/8" x 18-5/16" x 7-1/16" Dimensions (W x H x D) : 5-13/16" x 11" x 4-7/8"
(124 x 465 x 179 mm) (147 x 280 x 124 mm)
Weight : 7.5 lbs. (3.4 kg) Weight : 3.7 lbs. (1.7 kg)
Drivers unit : 4 inch Cone Woofer x 2 Drivers unit : 4 inch Cone Woofer
1 inch Balanced Dome tweeter 1 inch Balanced Dome tweeter
Terminal : Color-coded push type Terminal : Color-coded push type
Other : Magnetic shielding



Specifications and appearance are subject to change
without prior notice.
HTP-420



EXPLODED VIEWS-1
SKW-420 : POWERED SUBWOOFER
SP06 A06 (POWER SWITCH) :
x 10 pcs. MDD type --- No
A02 MDC type --- No
A01 MDT type --- No
MDD type A06 MPA type --- Yes
MDC type MGT type --- Yes
MDT type MPT type --- Yes
Refer to "EXPLODED VIEWS-2"
MPA type

MGT type
MPT type A03
U03



U02
U01
A05 x 4 pcs.




A04
F903
F902





IC501---> Refer to "PRINTED CIRCUIT BOARD PARTS LIST"




HTP-420
HTP-420



EXPLODED VIEWS-2
SKW-420 : POWERED SUBWOOFER


SP01




SP02
x 4 pcs.




SP04
SP03




SP08




SP06




HTP-420
x 8 pcs. SP05
x 8 pcs.
HTP-420



EXPLODED VIEWS-3
SKF-420F / SKC-420C / SKM-420S
SP10 SP12

SP14

SP15



SP11 SP13

L:
INA ck
RM la
TE en / B
Gre
L: L:
INA ck INA
RM la RM ck
TE ite / B TE / Bla
Wh Red "SKC-420C"



"SKF-420F (L)" "SKF-420F (R)"


SP16 SP18




SP17 SP19




L: L:
INAk INA k
RM c RM ac
TE e / Bla TE y / Bl
Blu Gr a




HTP-420
"SKM-420S (L)" "SKM-420S (R)"
HTP-420



BLOCK DIAGRAM
SKW-420 : POWERED SUBWOOFER




HTP-420
HTP-420
A B C D
SCHEMATIC DIAGRAM
SKW-420 : POWERED SUBWOOFER


1




2




3
LINE
INPUT




OUTPUT
LEVEL




4
LED
RED : STANDBY
GREEN : ON




U02 INPUT PC BOARD U03 VR / LED PC BOARD U01 MA



AC 120V / 60Hz
AC 220-230V / 50Hz
POWER SWITCH* / C1** C913*** / C914***
5 MDD type --- No MDD type --- Yes
AC 230-240V / 50Hz

MDC type --- No MDC type --- Yes
MDT type --- No MDT type --- Yes
MPA type --- Yes MPA type --- No
MGT type --- Yes MGT type --- No
MPT type --- Yes MPT type --- No
HTP-420
E F G H




SPEAKER




MAIN PC BOARD

**
***
*
0Hz
0Hz ***
HTP-420
A B C D E F G H
SCHEMATIC DIAGRAM
SKW-420 : POWERED SUBWOOFER

SPEAKER
1




2




3
LINE
INPUT




OUTPUT
LEVEL




4
LED
RED : STANDBY
GREEN : ON




U02 INPUT PC BOARD U03 VR / LED PC BOARD U01 MAIN PC BOARD

**
***
*
AC 120V / 60Hz
AC 220-230V / 50Hz
POWER SWITCH* / C1** C913*** / C914*** ***
5 MDD type --- No MDD type --- Yes
AC 230-240V / 50Hz

MDC type --- No MDC type --- Yes
MDT type --- No MDT type --- Yes
MPA type --- Yes MPA type --- No
MGT type --- Yes MGT type --- No
MPT type --- Yes MPT type --- No
HTP-420



PC BOARD CONNECTION DIAGRAM
SKW-420 : POWERED SUBWOOFER



INPUT PC BOARD




MAIN PC BOARD




VR / LED PC BOARD





POWER SWITCH :
MDD type --- No
MDC type --- No
MDT type --- No




HTP-420
POWER SWITCH MPA type --- Yes
MGT type --- Yes
MPT type --- Yes
HTP-420
A B C D
PRINTED CIRCUIT BOARD VIEW
SKW-420 : POWERED SUBWOOFER

U01 MAIN PC BOARD
1




2




3




4




U02 INPUT PC BOARD U03 VR / LED PC BOARD

5
No PC board view
Look over the actual PC board on hand
® TDA7293

120V - 100W DMOS AUDIO AMPLIFIER WITH MUTE/ST-BY

VERY HIGH OPERATING VOLTAGE RANGE
(±50V) MULTIPOWER BCD TECHNOLOGY
DMOS POWER STAGE
HIGH OUTPUT POWER (100W @ THD =
10%, RL = 8, VS = ±40V)
MUTING/STAND-BY FUNCTIONS
NO SWITCH ON/OFF NOISE
VERY LOW DISTORTION
VERY LOW NOISE Multiwatt15V Multiwatt15H
SHORT CIRCUIT PROTECTED (WITH NO IN- ORDERING NUMBERS:
PUT SIGNAL APPLIED) TDA7293V TDA7293HS
THERMAL SHUTDOWN
CLIP DETECTOR class TV). Thanks to the wide voltage range and
MODULARITY (MORE DEVICES CAN BE to the high out current capability it is able to sup-
ply the highest power into both 4 and 8 loads.
EASILY CONNECTED IN PARALLEL TO
DRIVE VERY LOW IMPEDANCES) The built in muting function with turn on delay
simplifies the remote operation avoiding switching
on-off noises.
DESCRIPTION Parallel mode is made possible by connecting
The TDA7293 is a monolithic integrated circuit in more device through of pin11. High output power
Multiwatt15 package, intended for use as audio can be delivered to very low impedance loads, so
class AB amplifier in Hi-Fi field applications optimizing the thermal dissipation of the system.
(Home Stereo, self powered loudspeakers, Top-
Figure 1: Typical Application and Test Circuit


C7 100nF +Vs C6 1000µF

R3 22K
+Vs BUFFER DRIVER +PWVs
C2
R2 7 11 13
22µF
680 IN- 2
-
14 OUT
C1 470nF
IN+ 3
+
BOOT
R1 22K 12 LOADER
SGND 4 C5
22µF (*)
(**)
6
BOOTSTRAP
VMUTE R5 10K MUTE 10 5
MUTE THERMAL S/C VCLIP
CLIP DET
SHUTDOWN PROTECTION
VSTBY STBY 9 STBY
R4 22K
1 8 15
STBY-GND -Vs -PWVs

C3 10µF C4 10µF C9 100nF C8 1000µF
D97AU805A
-Vs
(*) see Application note
(**) for SLAVE function




January 2003 1/15
TDA7293

PIN CONNECTION (Top view)

15 -VS (POWER)
14 OUT
13 +VS (POWER)
12 BOOTSTRAP LOADER
11 BUFFER DRIVER
10 MUTE
9 STAND-BY
8 -VS (SIGNAL)
7 +VS (SIGNAL)
6 BOOTSTRAP
5 CLIP AND SHORT CIRCUIT DETECTOR
4 SIGNAL GROUND
3 NON INVERTING INPUT
2 INVERTING INPUT
1 STAND-BY GND


TAB CONNECTED TO PIN 8 D97AU806




ABSOLUTE MAXIMUM RATINGS
Symbol Parameter Value Unit
VS Supply Voltage (No Signal) ±60 V
V1 VSTAND-BY GND Voltage Referred to -VS (pin 8) 90 V
V2 Input Voltage (inverting) Referred to -VS 90 V
V2 - V3 Maximum Differential Inputs ±30 V
V3 Input Voltage (non inverting) Referred to -VS 90 V
V4 Signal GND Voltage Referred to -VS 90 V
V5 Clip Detector Voltage Referred to -VS 120 V
V6 Bootstrap Voltage Referred to -VS 120 V
V9 Stand-by Voltage Referred to -VS 120 V
V10 Mute Voltage Referred to -VS 120 V
V11 Buffer Voltage Referred to -VS 120 V
V12 Bootstrap Loader Voltage Referred to -VS 100 V
IO Output Peak Current 10 A
Ptot Power Dissipation Tcase = 70°C 50 W
Top Operating Ambient Temperature Range 0 to 70 °C
Tstg, Tj Storage and Junction Temperature 150 °C




THERMAL DATA
Symbol Description Typ Max Unit
Rth j-case Thermal Resistance Junction-case 1 1.5 °C/W




2/15
TDA7293

ELECTRICAL CHARACTERISTICS (Refer to the Test Circuit VS = ±40V, RL = 8, Rg = 50 ;
Tamb = 25°C, f = 1 kHz; unless otherwise specified).
Symbol Parameter Test Condition Min. Typ. Max. Unit
VS Supply Range ±12 ±50 V
Iq Quiescent Current 50 100 mA
Ib Input Bias Current 0.3 1 µA
VOS Input Offset Voltage -10 10 mV
IOS Input Offset Current 0.2 µA
PO RMS Continuous Output Power d = 1%: 75 80 W
RL = 4; VS = ± 29V, 80
d = 10% 90 100 W
RL = 4 ; VS = ±29V 100
d Total Harmonic Distortion (**) PO = 5W; f = 1kHz 0.005 %
PO = 0.1 to 50W; f = 20Hz to 15kHz 0.1 %
ISC Current Limiter Threshold VS ± 40V 6.5 A
SR Slew Rate 5 10 V/µs
GV Open Loop Voltage Gain 80 dB
GV Closed Loop Voltage Gain (1) 29 30 31 dB
eN Total Input Noise A = curve 1 µV
f = 20Hz to 20kHz 3 10 µV
Ri Input Resistance 100 k
SVR Supply Voltage Rejection f = 100Hz; Vripple = 0.5Vrms 75 dB
TS Thermal Protection DEVICE MUTED 150 °C
DEVICE SHUT DOWN 160 °C
STAND-BY FUNCTION (Ref: to pin 1)
VST on Stand-by on Threshold 1.5 V
VST off Stand-by off Threshold 3.5 V
ATTst-by Stand-by Attenuation 70 90 dB
Iq st-by Quiescent Current @ Stand-by 0.5 1 mA
MUTE FUNCTION (Ref: to pin 1)
VMon Mute on Threshold 1.5 V
VMoff Mute off Threshold 3.5 V
ATTmute Mute AttenuatIon 60 80 dB
CLIP DETECTOR
Duty Duty Cycle ( pin 5) THD = 1% ; RL = 10K to 5V 10 %
THD = 10% ; 30 40 50 %
RL = 10K to 5V
ICLEAK PO = 50W 3 µA
SLAVE FUNCTION pin 4 (Ref: to pin 8 -VS)
VSlave SlaveThreshold 1 V
VMaster Master Threshold 3 V
Note (1): GVmin 26dB

Note: Pin 11 only for modular connection. Max external load 1M/10 pF, only for test purpose

Note (**): Tested with optimized Application Board (see fig. 2)




3/15
TDA7293

Figure 2: Typical Application P.C. Board and Component Layout (scale 1:1)




4/15
TDA7293

APPLICATION SUGGESTIONS (see Test and Application Circuits of the Fig. 1)
The recommended values of the external components are those shown on the application circuit of Fig-
ure 1. Different values can be used; the following table can help the designer.

LARGER THAN SMALLER THAN
COMPONENTS SUGGESTED VALUE PURPOSE
SUGGESTED SUGGESTED

R1 (*) 22k INPUT RESISTANCE INCREASE INPUT DECREASE INPUT
IMPEDANCE IMPEDANCE

R2 680 CLOSED LOOP GAIN DECREASE OF GAIN INCREASE OF GAIN
SET TO 30dB (**)
R3 (*) 22k INCREASE OF GAIN DECREASE OF GAIN

R4 22k ST-BY TIME LARGER ST-BY SMALLER ST-BY
CONSTANT ON/OFF TIME ON/OFF TIME;
POP NOISE

R5 10k MUTE TIME LARGER MUTE SMALLER MUTE
CONSTANT ON/OFF TIME ON/OFF TIME

C1 0.47µF INPUT DC HIGHER LOW
DECOUPLING FREQUENCY
CUTOFF

C2 22µF FEEDBACK DC HIGHER LOW
DECOUPLING FREQUENCY
CUTOFF

C3 10µF MUTE TIME LARGER MUTE SMALLER MUTE
CONSTANT ON/OFF TIME ON/OFF TIME

C4 10µF ST-BY TIME LARGER ST-BY SMALLER ST-BY
CONSTANT ON/OFF TIME ON/OFF TIME;
POP NOISE

C5 22µFXN (***) BOOTSTRAPPING SIGNAL
DEGRADATION AT
LOW FREQUENCY

C6, C8 1000µF SUPPLY VOLTAGE
BYPASS

C7, C9 0.1µF SUPPLY VOLTAGE DANGER OF
BYPASS OSCILLATION

(*) R1 = R3 for pop optimization

(**) Closed Loop Gain has to be 26dB

(***) Multiplay this value for the number of modular part connected


Slave function: pin 4 (Ref to pin 8 -VS) Note:
If in the application, the speakers are connected
via long wires, it is a good rule to add between
MASTER the output and GND, a Boucherot Cell, in order to
-VS +3V avoid dangerous spurious oscillations when the
speakers terminal are shorted.
UNDEFINED The suggested Boucherot Resistor is 3.9/2W
-VS +1V
and the capacitor is 1µF.

SLAVE
-VS
D98AU821



5/15
TDA7293

INTRODUCTION frequency response; moreover, an accurate con-
trol of quiescent current is required.
In consumer electronics, an increasing demand
has arisen for very high power monolithic audio A local linearizing feedback, provided by differen-
amplifiers able to match, with a low cost, the per- tial amplifier A, is used to fullfil the above require-
formance obtained from the best discrete de- ments, allowing a simple and effective quiescent
signs. current setting.
The task of realizing this linear integrated circuit Proper biasing of the power output transistors
in conventional bipolar technology is made ex- alone is however not enough to guarantee the ab-
tremely difficult by the occurence of 2nd break- sence of crossover distortion.
down phoenomenon. It limits the safe operating While a linearization of the DC transfer charac-
area (SOA) of the power devices, and, as a con- teristic of the stage is obtained, the dynamic be-
sequence, the maximum attainable output power, haviour of the system must be taken into account.
especially in presence of highly reactive loads. A significant aid in keeping the distortion contrib-
Moreover, full exploitation of the SOA translates uted by the final stage as low as possible is pro-
into a substantial increase in circuit and layout vided by the compensation scheme, which ex-
complexity due to the need of sophisticated pro- ploits the direct connection of the Miller capacitor
tection circuits. at the amplifier's output to introduce a local AC
To overcome these substantial drawbacks, the feedback path enclosing the output stage itself.
use of power MOS devices, which are immune
from secondary breakdown is highly desirable. 2) Protections
The device described has therefore been devel- In designing a power IC, particular attention must
oped in a mixed bipolar-MOS high voltage tech- be reserved to the circuits devoted to protection
nology called BCDII 100/120. of the device from short circuit or overload condi-
tions.
1) Output Stage Due to the absence of the 2nd breakdown phe-
The main design task in developping a power op- nomenon, the SOA of the power DMOS transis-
erational amplifier, independently of the technol- tors is delimited only by a maximum dissipation
ogy used, is that of realization of the output stage. curve dependent on the duration of the applied
stimulus.
The solution shown as a principle shematic by
Fig3 represents the DMOS unity - gain output In order to fully exploit the capabilities of the
buffer of the TDA7293. power transistors, the protection scheme imple-
mented in this device combines a conventional
This large-signal, high-power buffer must be ca- SOA protection circuit with a novel local tempera-
pable of handling extremely high current and volt- ture sensing technique which " dynamically" con-
age levels while maintaining acceptably low har- trols the maximum dissipation.
monic distortion and good behaviour over
Figure 3: Principle Schematic of a DMOS unity-gain buffer.




6/15
TDA7293

Figure 4: Turn ON/OFF Suggested Sequence

+Vs
(V)
+40




-40




-Vs
VIN
(mV)


VST-BY
PIN #9 5V
(V)




VMUTE 5V
PIN #10
(V)




IQ
(mA)


VOUT
(V)
OFF

ST-BY
PLAY ST-BY OFF

MUTE MUTE
D98AU817




In addition to the overload protection described mute functions, independently driven by two
above, the device features a thermal shutdown CMOS logic compatible input pins.
circuit which initially puts the device into a muting The circuits dedicated to the switching on and off
state (@ Tj = 150 oC) and then into stand-by (@ of the amplifier have been carefully optimized to
Tj = 160 oC). avoid any kind of uncontrolled audible transient at
Full protection against electrostatic discharges on the output.
every pin is included. The sequence that we recommend during the
ON/OFF transients is shown by Figure 4.
Figure 5: Single Signal ST-BY/MUTE Control The application of figure 5 shows the possibility of
Circuit using only one command for both st-by and mute
functions. On both the pins, the maximum appli-
cable range corresponds to the operating supply
voltage.
MUTE STBY
MUTE/ 20K
APPLICATION INFORMATION
ST-BY
10K 30K HIGH-EFFICIENCY
10µF 10µF Constraints of implementing high power solutions
1N4148 are the power dissipation and the size of the
D93AU014 power supply. These are both due to the low effi-
ciency of conventional AB class amplifier ap-
proaches.
Here below (figure 6) is described a circuit pro-
posal for a high efficiency amplifier which can be
3) Other Features adopted for both HI-FI and CAR-RADIO applica-
The device is provided with both stand-by and tions.

7/15
TDA7293

The TDA7293 is a monolithic MOS power ampli- The main advantages offered by this solution are:
fier which can be operated at 100V supply voltage - High power performances with limited supply
(120V with no signal applied) while delivering out- voltage level.
put currents up to ±6.5 A.
This allows the use of this device as a very high - Considerably high output power even with high
power amplifier (up to 180W as peak power with load values (i.e. 16 Ohm).
T.H.D.=10 % and Rl = 4 Ohm); the only drawback With Rl= 8 Ohm, Vs = ±25V the maximum output
is the power dissipation, hardly manageable in power obtainable is 150 W, while with Rl=16
the above power range. Ohm, Vs = ±40V the maximum Pout is 200 W.
The typical junction-to-case thermal resistance of
the TDA7293 is 1 oC/W (max= 1.5 oC/W). To
avoid that, in worst case conditions, the chip tem- APPLICATION NOTE: (ref. fig. 7)
perature exceedes 150 oC, the thermal resistance
of the heatsink must be 0.038 oC/W (@ max am- Modular Application (more Devices in Parallel)
bient temperature of 50 oC). The use of the modular application lets very high
As the above value is pratically unreachable; a power be delivered to very low impedance loads.
high efficiency system is needed in those cases The modular application implies one device to act
where the continuous RMS output power is higher as a master and the others as slaves.
than 50-60 W. The slave power stages are driven by the master
The TDA7293 was designed to work also in device and work in parallel all together, while the in-
higher efficiency way. put and the gain stages of the slave device are dis-
For this reason there are four power supply pins: abled, the figure below shows the connections re-
two intended for the signal part and two for the quired to configure two devices to work together.
power part.
T1 and T2 are two power transistors that only
operate when the output power reaches a certain The master chip connections are the same as
threshold (e.g. 20 W). If the output power in- the normal single ones.
creases, these transistors are switched on during The outputs can be connected together with-
the portion of the signal where more output volt- out the need of any ballast resistance.
age swing is needed, thus "bootstrapping" the The slave SGND pin must be tied to the nega-
power supply pins (#13 and #15). tive supply.
The current generators formed by T4, T7, zener The slave ST-BY and MUTE pins must be con-
diodes Z1, Z2 and resistors R7,R8 define the nected to the master ST-BY and MUTE pins.
minimum drop across the power MOS transistors The bootstrap lines must be connected to-
of the TDA7293. L1, L2, L3 and the snubbers C9,
R1 and C10, R2 stabilize the loops formed by the gether and the bootstrap capacitor must be in-
"bootstrap" circuits and the output stage of the creased: for N devices the boostrap capacitor
TDA7293. must be 22µF times N.
By considering again a maximum average The slave IN-pin must be connected to the
output power (music signal) of 20W, in case negative supply.
of the high efficiency application, the thermal
resistance value needed from the heatsink is THE BOOTSTRAP CAPACITOR
2.2 oC/W (Vs =±50 V and Rl= 8 Ohm). For compatibility purpose with the previous de-
All components (TDA7293 and power transis- vices of the family, the boostrap capacitor can be
tors T1 and T2) can be placed on a 1.5 oC/W connected both between the bootstrap pin (6) and
heatsink, with the power darlingtons electrically the output pin (14) or between the boostrap pin
insulated from the heatsink. (6) and the bootstrap loader pin (12).
Since the total power dissipation is less than that
When the bootcap is connected between pin 6
of a usual class AB amplifier, additional cost sav- and 14, the maximum supply voltage in presence
ings can be obtained while optimizing the power of output signal is limited to 100V, due the boot-
supply, even with a high heatsink . strap capacitor overvoltage.
When the bootcap is connected between pins 6
BRIDGE APPLICATION and 12 the maximum supply voltage extend to the
full voltage that the technology can stand: 120V.
Another application suggestion is the BRIDGE
configuration, where two TDA7293 are used. This is accomplished by the clamp introduced at
In this application, the value of the load must not the bootstrap loader pin (12): this pin follows the
be lower than 8 Ohm for dissipation and current output voltage up to 100V and remains clamped
capability reasons. at 100V for higher output voltages. This feature
A suitable field of application includes HI-FI/TV lets the output voltage swing up to a gate-source
subwoofers realizations. voltage from the positive supply (VS -3 to 6V).

8/15
TDA7293

Figure 6: High Efficiency Application Circuit



+50V
T3
D6 BC394 R4 R5
T1
1N4001 BDX53A 270 270
D1 BYW98100 T4 T5
+25V BC393 BC393
R17 270

L1 1µH D3 1N4148 R6
20K
C12 330nF Z1 3.9V
7 13
R20 C1 C3 C5 C7 C9 IN 3 C11 22µF
20K 1000µF 100nF 1000µF 100nF 330nF R3 680
R12 2 R7 C16
63V 35V
R22 R1 13K 3.3K 1.8nF
R16 L3 5µH
10K 2 4 13K
TDA7293 OUT
PLAY C13 10µF 14
GND R18 270
9 6
ST-BY R13 20K C15 Pot
22µF R8 C17
R23 R2 R14 30K 1 3.3K 1.8nF
10K 2 D5 12
1N4148 R15 10K
R21 C2 C4 C6 C8 C10 10 8 15
20K 1000µF 100nF 1000µF 100nF 330nF Z2 3.9V
C14
63V 35V
10µF L2 1µH D4 1N4148
T7 T8
D2 BYW98100 BC394 BC394
R19 270
-25V
T2 R9 R10 R11
D7 BDX54A
1N4001 T6 270 270 20K
BC393
-50V
D97AU807C




Figure 6a: PCB and Component Layout of the fig. 6




9/15
TDA7293

Figure 6b: PCB - Solder Side of the fig. 6.




Figure 7: Modular Application Circuit

C7 100nF +Vs C6 1000µF

R3 22K
MASTER
BUFFER
+Vs DRIVER +PWVs
C2
R2 7 11 13
22µF
680 IN- 2
-
14 OUT
C1 470nF
IN+ 3 C10
+ 100nF
BOOT
R1 22K 12 LOADER R7
2
SGND 4
C5
47µF
VMUTE R5 10K MUTE 10 6
MUTE BOOTSTRAP
THERMAL S/C 5
VSTBY STBY 9 CLIP DET
STBY SHUTDOWN PROTECTION
R4 22K
1 8 15
STBY-GND -Vs -PWVs
C4 10µF
C9 100nF C8 1000µF
C3 10µF
-Vs
+Vs
C7 100nF C6 1000µF


BUFFER
+Vs DRIVER +PWVs
7 11 13
IN- 2
-
14 OUT
IN+ 3
+
BOOT
SLAVE 12 LOADER
SGND 4

MUTE 10 6
MUTE BOOTSTRAP
9 THERMAL S/C 5
STBY
STBY SHUTDOWN PROTECTION

1 8 15
STBY-GND -Vs -PWVs

C9 100nF C8 1000µF
D97AU808D
-Vs


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TDA7293

Figure 8a: Modular Application P.C. Board and Component Layout (scale 1:1) (Component SIDE)




Figure 8b: Modular Application P.C. Board and Component Layout (scale 1:1) (Solder SIDE)




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TDA7293

Figure 9: Distortion vs Output Power Figure 12: Modular Application Derating Rload
vs Vsupply (ref. fig. 7)
T.H.D (%)
10
6
5

2




Minimum Allovable Load (ohm)
5
1
0.5
4
0.2 Vs = +/-29V
f = 20 KHz
0.1 Rl = 4 Ohm
3
0.05

0.02 2
0.01
f = 1KHz Forbidden Area
0.005 1 Pd > 50W at Tcase=70°C
0.002
0.001 0
2 5 10 20 50 100 20 25 30 35 40 45 50
Pout (W)
Supply Voltage (+/-Vcc)

Figure 10: Distortion vs Output Power
Figure 13: Modular Application Pd vs Vsupply
T.H.D (%)
(ref. fig. 7)
10
60
5 Pd limit at Tcase=70°C
2 Dissipated Power for each
50
1 device of the modular
application
0.5 Vs = +/-40V 4ohm
Pdissipated (W)




Rl = 8 Ohm 40
0.2 f = 20 KHz
0.1
30
0.05 8ohm

0.02
20
0.01 f = 1KHz
0.005
10
0.002
0.001
2 5 10 20 50 100 0
Pout (W) 20 25 30 35 40 45 50
Supply Voltage (+/-Vcc)
Figure 11: Distortion vs Frequency
Figure 14: Output Power vs. Supply Voltage
T.H.D. (%)
10 Po (W)
120
110
100
Rl=8 Ohm
1 VS= +/- 35 V 90
f= 1 KHz
Rl= 8 Ohm 80 T.H.D.=10 %
70
0.1 60
50

Pout=100 mW 40
30 THD=0.5 %
0.01
20
Po=50 W 10

0.001