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TDA7296
70V - 60W DMOS AUDIO AMPLIFIER WITH MUTE/ST-BY
1

FEATURES
MULTIPOWER BCD TECHNOLOGY VERY HIGH OPERATING VOLTAGE RANGE (35V) DMOS POWER STAGE HIGH OUTPUT POWER (UP TO 60W MUSIC POWER) MUTING/STAND-BY FUNCTIONS NO SWITCH ON/OFF NOISE NO BOUCHEROT CELLS VERY LOW DISTORTION VERY LOW NOISE SHORT CIRCUIT PROTECTION THERMAL SHUTDOWN
Figure 1. Package

Multiwatt15V
Multiwatt15H (Short Leads)
Table 1. Order Codes
Part Number TDA7296 TDA7296HS Package Multiwatt15V Multiwatt15H (Short Leads)

2
DESCRIPTION
Thanks to the wide voltage range and to the high out current capability it is able to supply the highest power into both 4 and 8 loads even in presence of poor supply regulation, with high Supply Voltage Rejection. The built in muting function with turn on delay simplifies the remote operation avoiding switching onoff noises.
The TDA7296 is a monolithic integrated circuit in Multiwatt15 package, intended for use as audio class AB amplifier in Hi-Fi field applications (Home Stereo, self powered loudspeakers, Topclass TV). Figure 2. Typical Application and Test Circuit
C7 100nF R3 22K C2 22F
+Vs
C6 1000F
+Vs R2 680 C1 470nF IN2 7 -
+PWVs 13 14 OUT C5 22F 6 BOOTSTRAP R6 2.7 C10 100nF
IN+
3
+
R1 22K IN+MUTE R5 10K MUTE STBY R4 22K C3 10F C4 10F 4 10 9
VM VSTBY
MUTE STBY 1 STBY-GND 8
THERMAL SHUTDOWN
S/C PROTECTION 15 -PWVs C8 1000F
D93AU011
-Vs C9 100nF -Vs
Note: The Boucherot cell R6, C10, normally not necessary for a stable operation it could be needed in presence of particular load impedances at VS <25V.
February 2005
Rev. 10 1/15
TDA7296
Figure 3. Pin Connection
Table 2. Absolute Maximum Ratings
Symbol VS IO Ptot Top Tstg, Tj Supply Voltage (No Signal) Output Peak Current Power Dissipation Tcase = 70C Operating Ambient Temperature Range Storage and Junction Temperature Parameter Value 35 5 50 0 to 70 150 Unit V A W C C
Table 3. Thermal Data
Symbol Rth j-case Parameter Thermal Resistance Junction-case Typ. 1 Max 1.5 Unit C/W
Figure 4. Block Diagram
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TDA7296
Table 4. Electrical Characteristcs (Refer to the Test Circuit VS = 24V, RL = 8, GV = 30dB; Rg = 50; Tamb = 25C, f = 1 kHz; unless otherwise specified).
Symbol VS Iq
I
Parameter Supply Range Quiescent Current Input Bias Current Input Offset Voltage Input Offset Current RMS Continuous Output Power
Test Condition
Min. 10 20
Typ. 30
Max. 35 65 500
Unit V mA nA mV nA W W W W W W %
b
VOS IOS PO
-10 -100 d = 05% VS = 24V, RL = 8; VS = 21V, RL = 6; VS = 18V, RL = 4; d = 10% VS = 29V, RL = 8; VS = 24V, RL = 6; VS = 22V, RL = 4; PO = 5W; f = 1kHz PO = 0.1 to 20W; f = 20Hz to 20kHz VS = 18V, RL = 4; PO = 5W; f = 1kHz PO = 0.1 to 20W; f = 20Hz to 20kHz 27 27 27 30 30 30 60 60 60 0.005
10 100
Music Power (RMS) t = 1s (*)
d
Total Harmonic Distortion (**)
0.1 0.01 0.1 7 24 10 80 30 1 2 100 5 20Hz to 20kHz k 75 145 1.5 3.5 70 90 1 3 1.5 3.5 60 80 dB C V V dB mA V V dB 40 % % V/s dB dB V V
SR GV GV eN fL ,fH Ri SVR TS VST on VST off ATTst-by Iq st-by VMon VMoff ATTmute
Slew Rate Open Loop Voltage Gain Closed Loop Voltage Gain (1) Total Input Noise frequency response (-3dB) Input Resistance Supply Voltage Rejection Thermal Shutdown Stand-by on Threshold Stand-by off Threshold Stand-by Attenuation Quiescent Current @ Stand-by Mute on Threshold Mute off Threshold Mute AttenuatIon f = 100Hz; Vripple = 0.5Vrms A = curve f = 20Hz to 20kHz PO =1W
60
STAND-BY FUNCTION (Ref: -Vs or GND)
MUTE FUNCTION (Ref: -Vs ro GND)
Note (*): MUSIC POWER is the maximal power which the amplifier is capable of producing across the rated load resistance (regardless of non linearity) 1 sec after the application of a sinusoidal input signal of frequency 1KHz. Note (**): Tested with optimized Application Board (see fig.5)
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TDA7296
Figure 5. P.C.B. and Components Layout of the Circuit of figure 2.
Note: The Stand-by and Mute functions can be referred either to GND or -VS. On the P.C.B. is possible to set both the configuration through the jumper J1.
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TDA7296
3
APPLICATION SUGGESTIONS
(see Test and Application Circuits of the Fig. 2) The recommended values of the external components are those shown on the application circuit of Figure 2. Different values can be used; the following table can help the designer.
COMPONENTS R1 (*) R2 R3 (*) R4 R5 C1 C2 C3 C4 C5 C6, C8 C7, C9 SUGGESTED VALUE 22k 680 22k 22k 10k 0.47F 22F 10F 10F 22F 1000F 0.1F St-by Time Constant Mute Time Constant Input DC Decoupling Feedback DC Decoupling Mute Time Constant St-by Time Constant Bootstrapping Supply Voltage Bypass Supply Voltage Bypass Larger Mute ON/OFF Time Larger St-by ON/OFF Time PURPOSE Input Resistance Closed Loop Gain Set to 30db (**) LARGER THAN SUGGESTED Increase Input Impedance Decrease of Gain Increase of Gain Larger St-by ON/OFF Time Larger Mute ON/OFF Time SMALLER THAN SUGGESTED Decrease Input Impedance Increase of Gain Decrease of Gain Smaller St-by ON/OFF Time; Pop Noise Smaller Mute ON/OFF Time Higher Low Frequency Cutoff Higher Low Frequency Cutoff Smaller Mute ON/OFF Time Smaller St-by ON/OFF Time; Pop Noise Signal Degradation at Low Frequency Danger of Oscillation Danger of Oscillation
(*) R1 = R3 for pop optimization (**) Closed Loop Gain has to be 24dB
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TDA7296
4
TYPICAL CHARACTERISTICS
Figure 9. Distortion vs. Output Power
(Application Circuit of fig 2 unless otherwise specified) Figure 6. : Output Power vs. Supply Voltage.
Figure 7. Distortion vs. Output Power
Figure 10. Distortion vs. Frequency
Figure 8. Output Power vs. Supply Voltage
Figure 11. Distortion vs. Frequency
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TDA7296
Figure 12. Quiescent Current vs. Supply Voltage Figure 15. St-by Attenuation vs. Vpin9
Figure 13. Supply Voltage Rejection vs. Frequency
Figure 16. Power Dissipation vs. Output Power
Figure 14. Mute Attenuation vs. Vpin10
Figure 17. Power Dissipation vs. Output Power
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TDA7296
5
INTRODUCTION
In consumer electronics, an increasing demand has arisen for very high power monolithic audio amplifiers able to match, with a low cost the performance obtained from the best discrete designs. The task of realizing this linear integrated circuit in conventional bipolar technology is made extremely difficult by the occurence of 2nd breakdown phenomenon. It limits the safe operating area (SOA) of the power devices, and as a consequence, the maximum attainable output power, especially in presence of highly reactive loads. Moreover, full exploitation of the SOA translates into a substantial increase in circuit and layout complexity due to the need for sophisticated protection circuits. To overcome these substantial drawbacks, the use of power MOS devices, which are immune from secondary breakdown is highly desirable. The device described has therefore been developed in a mixed bipolar-MOS high voltage technology called BCD 80. 5.1 Output Stage The main design task one is confronted with while developing an integrated circuit as a power operational amplifier, independently of the technology used, is that of realising the output stage. The solution shown as a principle schematic by Fig 18 represents the DMOS unity-gain output buffer of the TDA7296. This large-signal, high-power buffer must be capable of handling extremely high current and voltage levels while maintaining acceptably low harmonic distortion and good behaviour over frequency response; moreover, an accurate control of quiescent current is required. A local linearizing feedback, provided by differential amplifier A, is used to fullfil the above requirements, allowing a simple and effective quiescent current setting. Proper biasing of the power output transistors alone is however not enough to guarantee the absence of crossover distortion. While a linearization of the DC transfer characteristic of the stage is obtained, the dynamic behaviour of the system must be taken into account. A significant aid in keeping the distortion contributed by the final stage as low as possible is provided by the compensation scheme, which exploits the direct connection of the Miller capacitor at the amplifier's output to introduce a local AC feedback path enclosing the output stage itself. 5.2 Protections In designing a power IC, particular attention must be reserved to the circuits devoted to protection of the device from short circuit or overload conditions. Due to the absence of the 2nd breakdown phenomenon, the SOA of the power DMOS transistors is delimited only by a maximum dissipation curve dependent on the duration of the applied stimulus. In order to fully exploit the capabilities of the power transistors, the protection scheme implemented in this device combines a conventional SOA protection circuit with a novel local temperature sensing technique which " dynamically" controls the maximum dissipation. Figure 18. Principle Schematic of a DMOS Unity-gain Buffer.
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TDA7296
Figure 19. Turn ON/OFF Suggested Sequence
+Vs (V) +35
-35
-Vs VIN (mV)
VST-BY PIN #9 (V)
5V
VMUTE PIN #10 (V)
5V
IP (mA)
VOUT (V) OFF ST-BY PLAY MUTE MUTE
D93AU013
ST-BY
OFF
In addition to the overload protection described above, the device features a thermal shutdown circuit which initially puts the device into a muting state (@ Tj = 145C) and then into stand-by (@ Tj = 150C). Full protection against electrostatic discharges on every pin is included. 5.3 Other Features The device is provided with both stand-by and mute functions, independently driven by two CMOS logic compatible input pins. The circuits dedicated to the switching on and off of the amplifier have been carefully optimized to avoid any kind of uncontrolled audible transient at the output. The sequence that we recommend during the ON/OFF transients is shown by Figure 19. The application of figure 20 shows the possibility of using only one command for both st-by and mute functions. On both the pins, the maximum applicable range corresponds to the operating supply voltage.
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TDA7296
Figure 20. Single Signal ST-BY/MUTE Control Circuit
MUTE MUTE/ ST-BY
10K 20K 30K
STBY
1N4148
10F
10F
D93AU014
6
BRIDGE APPLICATION
Another application suggestion is the BRIDGE configuration, where two TDA7296 are used, as shown by the schematic diagram. In this application, the value of the load must not be lower than 8 Ohm for dissipation and current capability reasons. A suitable field of application includes HI-FI/TV subwoofers realizations. The main advantages offered by this solution are: - High power performances with limited supply voltage level. - Considerably high output power even with high load values (i.e. 16 Ohm). The characteristics shown by figures 23 and 24, measured with loads respectively 8 Ohm and 16 Ohm. With Rl= 8 Ohm, Vs = 18V the maximum output power obtainable is 60W, while with Rl=16 Ohm, Vs = 24V the maximum Pout is 60W. Figure 21. Bridge Application Circuit
+Vs 0.22F 2200F 7 Vi 0.56F 22K 1 4 ST-BY/MUTE 20K 22F 1N4148 10 10K 30K 22F 3 0.56F 22K 1 4 7 13 6 + 2 14 22F 22K 9 15 8 2200F 22K -Vs 0.22F 10 680 9 15 8 3 + 2 13 6 14 22F 22K
680
D93AU015A
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TDA7296
Figure 22. Frequency Response of the Bridge Application Figure 24. Distortion vs. Output Power
Figure 23. Distortion vs. Output Power
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TDA7296
Figure 25. Multiwatt15V Mechanical Data & Package Dimensions
DIM. A5 B C D E F G G1 H1 H2 L L1 L2 L3 L4 L7 M M1 S S1 Dia1 21.9 21.7 17.65 17.25 10.3 2.65 4.25 4.73 1.9 1.9 3.65 4.55 5.08 17.5 10.7 22.2 22.1 0.49 0.66 1.02 17.53 19.6 20.2 22.5 22.5 18.1 17.75 10.9 2.9 4.85 5.43 2.6 2.6 3.85 0.862 0.854 0.695 0.679 0.406 0.104 0.167 0.186 0.075 0.075 0.144 0.179 0.200 0.689 0.421 0.874 0.87 1.27 17.78 1 0.55 0.75 1.52 18.03 0.019 0.026 0.040 0.690 0.772 0.795 0.886 0.886 0.713 0.699 0.429 0.114 0.191 0.214 0.102 0.102 0.152 0.050 0.700 2.65 1.6 0.039 0.022 0.030 0.060 0.710 mm MIN. TYP. MAX. MIN. inch TYP. MAX. 0.197 0.104 0.063
OUTLINE AND MECHANICAL DATA
Multiwatt15 (Vertical)
0016036 J
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TDA7296
Figure 26. Multiwatt15 Horizontal (Short leads) Mechanical Data & Package Dimensions
mm DIM. MIN. A B C E F G G1 H1 H2 L1 L2 L3 L4 L5 L7 R S S1 Dia1 1.9 1.9 3.65 17.25 10.3 2.70 2.65 1.5 2.6 2.6 3.85 0.075 0.075 0.144 0.49 0.66 1.02 17.53 19.6 19.6 17.80 18.00 2.54 17.5 10.7 3.00 17.75 10.9 3.30 2.9 0.679 0.406 0.106 0.104 0.059 0.102 0.102 0.152 1.27 17.78 TYP. MAX. 5 2.65 1.6 0.55 0.75 1.52 18.03 20.2 20.2 18.20 0.019 0.026 0.040 0.690 0.772 0.772 0.701 0.709 0.100 0.689 0.421 0.118 0.699 0.429 0.130 0.114 0.050 0.700 MIN. TYP. MAX. 0.197 0.104 0.063 0.022 0.030 0.060 0.709 0.795 0.795 0.717 inch
OUTLINE AND MECHANICAL DATA
Multiwatt15 H (Short leads)
V R R B L5 L2 V E
V
V
V
A C
L1 L3 L4 N L7 H2
F
H2
G1 Diam 1 G S
H1
MW15HME
R1
P S1
0067558 E
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TDA7296
Table 5. Revision History
Date January 2004 September 2004 February 2005 Revision 8 9 10 Description of Changes First Issue in EDOCS DMS Added Package Multiwatt15 Horizontal (Short leads) Corrected mistyping error in Table 2.
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TDA7296
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) 2005 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 of America www.st.com
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