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TDA2050
32W Hi-Fi AUDIO POWER AMPLIFIER
HIGH OUTPUT POWER (50W MUSIC POWER IEC 268.3 RULES) HIGH OPERATING SUPPLY VOLTAGE (50V) SINGLE OR SPLIT SUPPLY OPERATIONS VERY LOW DISTORTION SHORT CIRCUIT PROTECTION (OUT TO GND) THERMAL SHUTDOWN DESCRIPTION The TDA 2050 is a monolithic integrated circuit in Pentawatt package, intended for use as an audio class AB audio amplifier. Thanks to its high power capability the TDA2050 is able to provide up to 35W true rms power into 4 ohm load @ THD = 10%, VS = ±18V, f = 1KHz and up to 32W into 8ohm load @ THD = 10%, VS = ±22V, f = 1KHz. Moreover, the TDA 2050 delivers typically 50W music power into 4 ohm load over 1 sec at VS= 22.5V, f = 1KHz. TEST AND APPLICATION CIRCUIT
Pentawatt ORDERING NUMBERS: TDA2050V TDA2050H
The high power and very low harmonic and crossover distortion (THD = 0.05% typ, @ VS = ±22V, PO = 0.1 to 15W, RL=8ohm, f = 100Hz to 15KHz) make the device most suitable for both HiFi and high class TV sets.
March 1995
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This is advanced information on a new product now in development or undergoing evaluation. Details are subject to change without notice.
TDA2050
ABSOLUTE MAXIMUM RATINGS
Symbol VS Vi Vi IO Ptot Tstg, Tj Supply Voltage Input Voltage Differential Input Voltage Output Peak Current (internally limited) Power Dissipation TCASE = 75°C Storage and Junction Temperature Parameter Value ±25 VS ±15 5 25 -40 to 150 V A W °C Unit V
PIN CONNECTION (Top view)
SCHEMATIC DIAGRAM
THERMAL DATA
Symbol Rth j-case 2/13 Thermal Resistance junction-case Description Max Value 3 Unit °C/W
TDA2050
ELECTRICAL CHARACTERISTICS (Refer to the Test Circuit, VS = ±18V, Tamb = 25°C, f = 1 kHz; unless otherwise specified)
Symbol VS Id Ib VOS IOS PO Parameter Supply Voltage Range Quiescent Drain Current Input Bias Current Input Offset Voltage Input Offset Current RMS Output Power VS = ±4.5V VS = ±25V VS = ±22V VS = ±22V VS = ±22V d = 0.5% R L = 4 R L = 8 VS = ±22V RL = 8 d = 10% R L = 4 R L = 8 VS = ±22V RL = 8 Music Power IEC268.3 RULES d Total Harmonic Distortion d = 10%; T = 1s VS = ±22.5V; RL = 4 R L = 4 f = 1kHz, PO = 0.1 to 24W f = 100Hz to 10kHz, PO = 0.1 to 18W VS = ±22V RL = 8 f = 1kHz, PO = 0.1 to 20W f = 100Hz to 10kHz, PO = 0.1 to 15W SR GV GV BW eN Ri SVR Slew Rate Open Loop Voltage Gain Closed Loop Voltage Gain Power Bandwidth (-3dB) Total Input Noise Input Resistance (pin 1) Supply Voltage Rejection Efficiency R s = 22k; f = 100Hz; Vripple = 0.5Vrms PO = 28W; RL = 4 PO = 25W; RL = 8; VS = ±22V Tsd- j Thermal Shut-down Junction Temperature R L = 4 Vi = 200mV curve A B = 22Hz to 22kHz 500 45 65 67 150 30 5 24 22 28 18 25 35 22 32 50 0.03 0.5 0.5 Test Condition Min. ±4.5 30 55 0.1 Typ. Max. ±25 50 90 0.5 ±15 ±200 Unit V mA mA µA mV nA W W W W W W W % % % % V/µs dB 31 dB Hz 10 µV µV k dB % % °C
0.02 0.5 8 80 30.5 20 to 80,000 4 5
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TDA2050
Figure 1: Split Supply Typical Application Circuit
Figure 2: P.C. Board and Components Layout of the Circuit of Fig. 1 (1:1)
TDA20 5 0
RL R4 R3 +Vs R2 C2 R1 C4 C1 Vi -Vs C6 C3 C7 C5
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TDA2050
SPLIT SUPPLY APPLICATION SUGGESTIONS The recommended values of the external components are those shown on the application circuit of fig. 2. Different values can be used. The following table can help the designer.
Component R1 R2 R3 R4 C1 C2 C3 C4 C5 C6 C7
Recommended Value 22k 680 22k 2.2 1µF 22µF 100nF 220µF 0.47µF
Purpose Input Impedance Feedback Resistor Frequency Stability Input Decoupling DC Inverting Input DC Decoupling Supply Voltage Bypass Supply Voltage Bypass Frequency Stability
Larger than Recommended Value Increase of Input Impedance Decrease of Gain (*) Increase of Gain Danger of Oscillations
Smaller than Recommended Value Decrease of Input Impedance Increase of Gain Decrease of Gain (*) Higher Low-frequency cut-off
Increase of Switch ON/OFF Noise
Higher Low-frequency cut-off Danger of Oscillations Danger of Oscillations Danger of Oscillations
(*) The gain must be higher than 24dB
PRINTED CIRCUIT BOARD The layout shown in fig. 2 should be adopted by the designers. If different layouts are used, the
ground points of input 1 and input 2 must be well decoupled from the ground return of the output in which a high current flows.
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TDA2050
Figure 3: Single Supply Typical Application Circuit
Figure 4: P.C. Board and Components Layout of the Circuit of Fig. 3 (1:1)
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TDA2050
SINGLE SUPPLY APPLICATION SUGGESTIONS The recommended values of the external components are those shown on the application circuit
Recommended Value 22k 22k 680 2.2 2.2µF 100µF 1000µF
of fig. 3. Different values can be used. The following table can help the designer.
Larger than Recommended Value Increase of Gain Decrease of Gain (*) Danger of Oscillations Higher Low-frequency cut-off Worse Turn-off Transient Worse Turn-on Delay Danger of Oscillations Worse of Turn-off Transient Increase of Switching ON/OFF Higher Low-frequency cut-off Danger of Oscillations Danger of Oscillations Higher Low-frequency cut-off Smaller than Recommended Value Decrease of Gain (*) Increase of Gain
Component R1, R2, R3 R4 R5 R6 C1 C2 C3
Purpose Biasing Resistor Feedback Resistors Frequency Stability Input Decoupling DC Supply Voltage Rejection Supply Voltage Bypass
C4 C5 C6 C7
22µF 100nF 0.47µF 1000µF
Inverting Input DC Decoupling Supply Voltage Bypass Frequency Stability Output DC Decoupling
(*) The gain must be higher than 24dB
NOTE If the supply voltage is lower than 40V and the load is 8ohm (or more) a lower value of C2 can
be used (i.e. 22µF). C7 can be larger than 1000uF only if the supply voltage does not exceed 40V.
TYPICAL CHARACTERISTICS (Split Supply Test Circuit unless otherwise specified) Figure 5: Output Power vs. Supply Voltage Figure 6: Distortion vs. Output Power
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TDA2050
Figure 7: Output Power vs. Supply Voltage Figure 8: Distortion vs. Output Power
Figure. 9: Distortion vs. Frequency
Figure 10: Distortion vs. Frequency
Figure 11: Quiescent Current vs. Supply Voltage
Figure 12: SupplyVoltage Rejection vs. Frequency
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TDA2050
Figure 13: Supply Voltage Rejection vs. Frequency (Single supply) for Different values of C2 (circuit of fig. 3) Figure 16: Total Power Dissipation and Efficiency vs. Output Power
Figure 14: Supply Voltage Rejection vs. Frequency (Single supply) for Different values of C2 (circuit of fig. 3) SHORT CIRCUIT PROTECTION The TDA 2050 has an original circuit which limits the current of the output transistors. The maximum output current is a function of the collector emitter voltage; hence the output transistors work within their safe operating area. This function can therefore be considered as being peak power limiting rather than simple current limiting. It reduces the possibility that the device gets damaged during an accidental short circuit from AC output to ground.
Figure 15: Total Power Dissipation and Efficiency vs. Output Power
THERMAL SHUTDOWN The presence of a thermal limiting circuit offers the following advantages: 1)An overload on the output (even if it is permanent), or an above limit ambient temperature can be easily tolerated since the Tj cannot be higher than 150°C. 2)The heatsink can have a smaller factor of safety compared with that of a conventional circuit. There is no possibility of device damage due to high junction temperature. If for any reason, the junction temperature increases up to 150°C, the thermal shutdown simply reduces the power dissipation and the current consumption. The maximum allowable power dissipation depends upon the thermal resistance junction-ambi9/13
TDA2050
ent. Fig. 17 shows this dissipable power as a function of ambient temperature for different thermal resistance. Figure 17: Maximum Allowable Power Dissipation vs. Ambient Temperature cient. Between the heatsink and the package is better to insert a layer of silicon grease, to optimize the thermal contact; no electrical isolation is needed between the two surfaces. Fig. 18 shows an example of heatsink. Dimension suggestion The following table shows the length that the heatsink in fig. 18 must have for several values of Ptot and Rth.
Ptot (W) Lenght of heatsink (mm) Rth of heatsink (°C/W) 12 60 4.2 8 40 6.2 6 30 8.3
Figure 18: Example of heat-sink
MOUNTING INSTRUCTIONS The power dissipated in the circuit must be removed by adding an external heatsink. Thanks to the PENTAWATT package, the heatsink mounting operation is very simple, a screw or a compression spring (clip) being suffi-
APPENDIX A
A.1 - MUSIC POWER CONCEPT MUSIC POWER is (according to the IEC clauses n.268-3 of Jan 83) the maximum 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 1 KHz. According to this definition our method of measurement comprises the following steps: - Set the voltage supply at the maximum operating value; - Apply a input signal in the form of a 1KHz tone burst of 1 sec duration: the repetition period of the signal pulses is 60 sec; - The output voltage is measured 1 sec from the start of the pulse; - Increase the input voltage until the output signal shows a THD=10%; - The music power is then V2out /RL, where Vout is the output voltage measured in the condition of point 4 and RL is the rated load impedance;
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The target of this method is to avoid excessive dissipation in the amplifier. A.2 - INSTANTANEOUS POWER Another power measurement (MAXIMUM INSTANTANEOUS OUTPUT POWER) was proposed by IEC in 1988 (IEC publication 268-3 subclause 19.A). We give here only a brief extract of the concept, and a circuit useful for the measurement. The supply voltage is set at the maximum operating value. The test signal consists of a sinusoidal signal whose frequency is 20 Hz, to which are added alternate positive and negative pulses of 50 µs duration and 500 Hz repetition rate. The amplitude of the 20 Hz signal is chosen to drive the amplifier to its voltage clipping limits, while the amplitude of the pulses takes the amplifier alternately into its current-overload limits.
TDA2050
A circuit for generating the test signal is given in fig. 19. The load network consists of a 40 µF capacitor, in series with a 1 ohm resistor. The capacitor limits the current due to the 20 Hz signal to a low value, whereas for he short pulses the effective load impedance is of the order of 1 ohm, and a high output current is produced. Using this signal and load network the measurement may be made without causing excessive dissipation in the amplifier. The dissipation in the 1 ohm resistor is much lower than a rated output Figure 19: Test circuit for peak power measurement power of the amplifier, because the duty-cycle of the high output current is low. By feeding the amplifier output voltage to the Xplates of an oscilloscope, and the voltage across the 1 ohm resistor (representing the output current) to the Y=plates, it is possible to read on the display the value of the maximum instantaneous output power. The result of this test applied at the TDA 2050 is: PEAK POWER = 100W typ
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TDA2050
PENTAWATT PACKAGE MECHANICAL DATA
DIM. A C D D1 E F F1 G G1 H2 H3 L L1 L2 L3 L5 L6 L7 M M1 Dia MIN. mm TYP. MAX. 4.8 1.37 2.8 1.35 0.55 1.05 1.4 MIN. inch TYP. MAX. 0.189 0.054 0.110 0.053 0.022 0.041 0.055 0.142 0.276 0.409 0.409
2.4 1.2 0.35 0.8 1 3.4 6.8 10.05 17.85 15.75 21.4 22.5 2.6 15.1 6 4.5 4 3.65
0.094 0.047 0.014 0.031 0.039 0.126 0.260 0.396
0.134 0.268
10.4 10.4
0.703 0.620 0.843 0.886 3 15.8 6.6 0.102 0.594 0.236 0.177 0.157 3.85 0.144 0.152 0.118 0.622 0.260
L E L1
A
C
D1
L2 L5 L3
D
Dia. F
L6
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H2
L7
F1
G
G1
H3
M
M1
TDA2050
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. © 1994 SGS-THOMSON Microelectronics - All Rights Reserved PENTAWATT® is a Registered Trademark of SGS-THOMSON Microelectronics 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.
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