STMICROELECTRONICS TDA2052H

TDA2052
®
60W Hi-Fi AUDIO POWER AMPLIFIER
WITH MUTE / STAND-BY
SUPPLY VOLTAGE RANGE UP TO ±25V
SPLIT SUPPLY OPERATION
HIGH OUTPUT POWER
(UP TO 60W MUSIC POWER)
LOW DISTORTION
MUTE/STAND-BY FUNCTION
NO SWITCH ON/OFF NOISE
AC SHORT CIRCUIT PROTECTION
THERMAL SHUTDOWN
ESD PROTECTION
DESCRIPTION
The TDA2052 is a monolithic integrated circuit in
Heptawatt package, intended for use as audio
class AB amplifier in TV or Hi-Fi field application.
Thanks to the wide voltage range and to the high
out current capability it’s able to supply the high-
Heptawatt V
Heptawatt H
ORDERING NUMBERS:
TDA2052V
TDA2052H
est power into both 4Ω and 8Ω loads even in
presence of poor supply regulation.
The built in Muting/Stand-by function simplifies
the remote operations avoiding also switching onoff noises.
TEST AND APPLICATION CIRCUIT
January 2003
1/14
This is advanced information on a new product now in development or undergoing evaluation. Details are subject to change without notice.
TDA2052
ABSOLUTE MAXIMUM RATINGS
Symbol
Parameter
VS
IO
DC Supply Voltage
Ptot
Top
Power Dissipation Tcase = 70°C
Operating Temperature Range
Tstg, Tj
Value
Unit
±25
V
Output Peak Current (internally limited)
Storage and Junction Temperature
6
A
30
0 to +70
W
°C
-40 to +150
°C
PIN CONNECTION (Top view)
tab connected to pin 4
BLOCK DIAGRAM
2/14
7
NON INVERTING INPUT(PLAY)
6
INVERTING INPUT
5
NON INVERTING INPUT(MUTE)
4
-VS
3
STAND-BY/MUTE
2
+VS
1
OUTPUT
D95AU326
TDA2052
THERMAL DATA
Symbol
Rth j-case
Description
Thermal Resistance Junction-case
Max
Value
Unit
2.5
°C/W
ELECTRICAL CHARACTERISTICS (Refer to the test circuit, GV = 32dB; VS + 18V; f = 1KHz; Tamb =
25°C, unless otherwise specified.)
Symbol
VS
Parameter
Supply Range
Iq
Ib
Total Quiescent Current
Input Bias Current
VOS
Input Offset Voltage
IOS
PO
Input Offset Current
PO
d
Test Condition
VS = +22V
Music Output Power
IEC268-3 Rules (*)
VS = + 22.5, RL = 4Ω,
d = 10%, t = 1s
Output Power (continuous RMS)
d = 10%
RL = 4Ω
RL = 8Ω
VS = +22V, R L = 8Ω
Total Harmonic Distortion
Min.
+6
Typ.
Max.
+25
Unit
V
20
40
70
+0.5
mA
µA
+15
mV
+200
nA
50
60
W
35
40
22
33
W
W
W
d = 1%
RL = 4Ω
RL = 8Ω
VS = +22V, R L = 8Ω
32
17
28
W
W
W
RL = 4Ω
PO = 0.1 to 20W;
f = 100Hz to 15KHz
0.1
0.7
0.1
0.5
30
VS + 22V, RL = 8Ω
PO = 0.1 to 20W;
f = 100Hz to 15KHz
SR
GV
Slew Rate
Open Loop Voltage Gain
eN
Total Input Noise
Ri
SVR
TS
3
A Curve
f = 20Hz to 20KHz
Input Resistance
Supply Voltage Rejection
5
80
2
3
%
V/µs
dB
10
500
f = 100Hz, Vripple = 1VRMS
%
µV
µV
KΩ
40
50
145
dB
°C
1
1.8
V
Thermal Shutdown
MUTE/STAND-BY FUNCTION (Ref. –VS)
VTST-BY
Stand-by - Threshold
VTPLAY
Iq ST-BY
Play Threshold
Quiescent Current @ Stand-by
ATTST-BY
Ipin3
2.7
1
Vpin 3 = 0.5V
Stand-by Attenuation
Pin 3 Current @ Stand-by
70
4
3
90
–1
V
mA
dB
+10
µA
Note (*):
MUSIC POWER CONCEPT
MUSIC POWER is ( according to the IEC clauses n.268-3 of Jan 83) 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.
According to this definition our method of measurement comprises the following steps:
1) Set the voltage supply at the maximum operating value -10%
2) 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
3) The output voltage is measured 1 sec from the start of the pulse
4) Increase the input voltage until the output signal show a THD = 10%
5) The music power is then V2out/R1, where Vout is the output voltage measured in the condition of point 4) and R1 is the rated load impedance
The target of this method is to avoid excessive dissipation in the amplifier.
3/14
TDA2052
APPLICATIONS SUGGESTIONS (See Test and Application Circuit)
The recommended values of the external components are those shown on the application circuit. Different values can be used; the following table can help the designer.
Comp.
Value
R1
22KΩ (*)
Purpose
Larger Than
Smaller Than
Input Impedance
Increase of Input
Impedance
Decrease of Input
Impedance
Decrease of Gain
Increase of Gain
Increase of Gain
Decrease of Gain
Danger of oscillations
Danger of oscillations
Higher Low-frequency
cut-off
Higher Low-frequency
cut-off
R2
560Ω
R3
22KΩ (*)
Closed Loop Gain set to
32dB (**)
R4
R5
22KΩ (*)
22KΩ
Input Impedance @ Mute
Stand-by Time Constant
R6
C1
4.7Ω
1µF
Frequency Stability
Input DC Decoupling
C2
10µF
Feedback DC Decoupling
C3
10µF
Stand-by Time Constant
C4
0.100µF
Frequency Stability
C5, C6
1000µF
Supply Voltage Bypass
Danger of Oscillations
(*) R1 = R3 = R4 for POP optimization
(**) Closed Loop Gain has to be ≥ 30dB
TYPICAL CHARACTERISTICS
Figure 1: Output Power vs. Supply Voltage
4/14
Figure 2: Distortion vs. Output Power
TDA2052
Figure 3: Output Power vs. Supply Voltage.
Figure 4: Distortion vs. Output Power.
Figure 5: Distortion vs. Frequency.
Figure 6: Distortion vs. Frequency.
Figure 7: Quiescent Current vs. Supply Voltage
Figure 8: Supply Voltage Rejection vs. Frequency.
5/14
TDA2052
Figure 9: Bandwidth.
Figure 10: Output Attenuation & Quiescent Current vs. Vpin3.
Figure 11: Total Power Dissipation & Efficiency
vs. Output Power.
Figure 12: Total Power Dissipation & Efficiency
vs. Output Power.
6/14
TDA2052
Figure 13: P.C. Board and Components Layout of the Circuit of Fig. 14 (1:1 scale)
Figure 14: Demo Board Schematic.
7/14
TDA2052
MUTE/STAND-BY FUNCTION
The pin 3 (MUTE/STAND-BY) controls the amplifier status by three different thresholds, referred
to -VS.
When its voltage is lower than the first threshold
(1V, with a +70mV hysteresis), the amplifier is in
STAND-BY and all the final stage current generFigure 15.
8/14
ators are off. Only the input MUTE stage is on in
order to prevent pop-on problems.
At Vpin3=1.8V the final stage current generators
are switched on and the amplifier operates in
MUTE.
For Vpin3 =2.7V the amplifier is definitely on
(PLAY condition)
TDA2052
SHORT-CIRCUIT PROTECTION
The TDA 2052 has an original circuit which protects the device during accidental short-circuit between output and GND / -Vs / +Vs, taking it in
STAND-BY mode, so limiting also dangerous DC
current flowing throught the loudspeaker.
If a short-circuit or an overload dangerous for the
final transistors are detected, the concerned SOA
circuit sends out a signal to the latching circuit
(with a 10µs delay time that prevents fast random
spikes from inadvertently shutting the amplifier
off) which makes Q1 and Q2 saturate (see Block
Diagram). Q1 immediately short-circuits to ground
the A point turning the final stage off while Q2
short-circuits to ground the external capacitor
driving the pin 3 (Mute/Stand-by) towards zero
potential.
Only when the pin 3 voltage becomes lower than
1V, the latching circuit is allowed to reset itself
and restart the amplifier, provided that the shortcircuit condition has been removed. In fact, a window comparator is present at the output and it is
aimed at preventing the amplifier from restarting if
the output voltage is lower than 0.35 Total Supply
Voltage or higher than 0.65 Total Supply Voltage.
If the output voltage lies between these two
thresholds, one may reasonably suppose the
short-circuit has been removed and the amplifier
may start operating again.
The PLAY/MUTE/STAND-BY function pin (pin 3)
is both ground- and positive supply-compatible
and can be interfaced by means of the R5, C3 net
either to a TTL or CMOS output (µ-Processor) or
to a specific application circuit.
The R5, C3 net is fundamental, because connecting this pin directly to a low output impedance
driver such as TTL gate would prevent the correct
operation during a short-circuit. Actually a final
stage overload turns on the protection latching
circuit that makes Q2 try to drive the pin 3 voltage
under 0.8 V. Since the maximum current this pin
can stand is 3 mA, one must make sure the following condition is met:
R5 ≥
THERMAL PROTECTION
The thermal protection operates on the 125µA
current generator, linearly decreasing its value
from 90°C on. By doing this, the A voltage slowly
decreases thus switching the amplifier first to
MUTE (at 145°C) and then to STAND-BY
(155°C).
Figure 16: Thermal Protection Block Diagram
The maximum allowable power dissipation depends on the size of the external heatsink (thermal resistance case-ambient); figure 17 shows
the dissipable power as a function of ambient
temperature for different thermal resistance.
Figure 17: Maximum Allowable Power Dissipation vs. Ambient Temperature.
(VA − 0.7V)
3mA
that yields: R5, min = 1.5 KΩ with VA=5V.
In order to prevent pop-on and -off transients, it is
advisable to calculate the C3, R5 net in such a
way that the STAND-BY/MUTE and MUTE/PLAY
threshold crossing slope (positive at the turn-on
and vice-versa) is less than 100 V/sec.
9/14
TDA2052
APPLICATION NOTES
90W MULTIWAY SPEAKER SYSTEM
The schematic diagram of figure 18, shows the
solution that we have closen as a suggestion for
Hi-Fi and especially TV applications.
The multiway system provides the separation of
the musical signal not only for the loudspeakers,
but also for the power amplifiers with the following
advantages:
Figure 18: Multiway Application Circuit
10/14
- reduced power level required of each individual amplifier
- complete separation of the ways (if an amplifier is affected by clipping distortion, the others are not)
- protection of tweeters (the high power harmonics generated by low frequency clipping
can not damage the delicate tweeters that are
driven by independent power amplifier)
- high power dedicated to low frequencies
TDA2052
As shown in Figure 19, the R-C passive network
for low-pass and High-pass give a cut with a
slope of 12dB/octave
A further advantage of this application is that connecting each speaker direcly to its amplifier, the
musical signal is not modified by the variations of
the impedance of the crossover over frequency.
The subwoofer is designed for obtaining high
sound pressure level with low distortion without
stereo effect.
In the application of figure 18, the subwoofer
plays the 20 to 300 Hz frequency range, while the
remaining 300 Hz to 20KHz are sent to two separate channels with stereo effect.
The multiway system makes use of three
TDA2052, one for driving the subwoofer with
POUT higher than 40W (THD = 10%), 28W undistorted (THD = 0.01%), while the others two
TDA2052 are used for driving the mid/high frequency speakers of L/R channels, delivering
POUT = 25W (THD = 10%) and 20W @ THD =
0.01%
Figure 19: Frequency Response
Figure 20: Distortion vs Output Power
(Subwoofer)
Figure 21:Distortion vs Output Power
(Midrange/Tweeter)
11/14
TDA2052
DIM.
A
C
D
D1
E
E1
F
G
G1
G2
H2
H3
L
L1
L2
L3
L4
L5
L6
L7
L9
L10
L11
M
M1
V4
Dia
MIN.
2.4
1.2
0.35
0.7
0.6
2.34
4.88
7.42
10.05
16.7
21.24
22.27
2.6
15.1
6
2.1
4.3
2.55
4.83
mm
TYP.
2.54
5.08
7.62
16.9
14.92
21.54
22.52
2.8
15.5
6.35
0.2
MAX.
4.8
1.37
2.8
1.35
0.55
0.97
0.8
2.74
5.28
7.82
10.4
10.4
17.1
21.84
22.77
1.29
3
15.8
6.6
MIN.
0.094
0.047
0.014
0.028
0.024
0.095
0.193
0.295
0.396
0.657
0.386
0.877
0.102
0.594
0.236
2.7
0.082
4.8
0.169
3.05 0.100
5.33 0.190
40 (typ.)
3.85 0.144
2.8
5.08
3.65
inch
TYP.
0.100
0.200
0.300
0.668
0.587
0.848
0.891
0.110
0.610
0.250
0.008
0.110
0.200
MAX.
0.189
0.054
0.110
0.053
0.022
0.038
0.031
0.105
0.205
0.307
0.409
0.409
0.673
OUTLINE AND
MECHANICAL DATA
Weight: 1.90gr
0.860
0.896
0.051
0.118
0.622
0.260
0.106
0.190
0.120
0.210
Heptawatt V
0.152
L
E
L1
M1
A
M
D
C
D1
H2
L2
L5
L3
F
E
E1
V4
L9
H3
G
G1
G2
Dia.
F
L10
L4
H2
L11
L7
L6
12/14
HEPTAMEC
0016069
TDA2052
mm
DIM.
MIN.
TYP.
A
inch
MAX.
MIN.
TYP.
MAX.
4.80
C
1.37
0.054
D
2.40
2.80
0.094
0.11
D1
1.20
1.35
0.047
0.053
E
0.35
0.55
0.014
0.022
E1
0.70
0.97
0.03
0.036
F
0.60
0.80
0.024
G
2.34
2.54
2.74
0.092
0.1
0.108
G1
4.88
5.08
5.28
0.192
0.2
0.208
G2
7.42
7.62
7.8
0.292
0.3
0.307
H2
0.031
10.40
H3
10.05
0.41
10.40
0.395
0.409
L1
3.90
4.20
4.50
0.153
0.165
L2
18.10
18.40
18.70
0.712
0.724
0.736
L3
4.88
5.08
5.28
0.192
0.2
0.208
L4
0.177
1.29
0.05
L5
2.60
3.00
0.102
0.118
L6
15.10
15.80
0.594
0.622
L7
6.00
6.60
0.236
L9
3.9
4.5
0.153
L10
2.10
2.70
0.083
0.106
L13
4.30
4.80
0.169
0.189
V5
4.2
OUTLINE AND
MECHANICAL DATA
0.188
0.260
0.165
0.177
Heptawatt H
89˚ (Min.), 90˚ (Typ.), 91˚ (Max.)
DIA
3.65
3.85
0.143
0.151
C
A
V5
D
L1
L9
D1
E
L3
L2
F
G
L7
H2
L4
L5
G1
G2
H2
H3
F
F
Dia.
Resin between
leads
E
E1
L10
L6
L11
HEPTHMEC.EPS
0080180
13/14
TDA2052
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. Specification 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
© 2003 STMicroelectronics – Printed in Italy – All Rights Reserved
STMicroelectronics GROUP OF COMPANIES
Australia - Brazil - Canada - China - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan - Malaysia - Malta - Morocco Singapore - Spain - Sweden - Switzerland - United Kingdom - United States.
http://www.st.com
14/14