HA13158A
34 W
4-Channel BTL Power IC
ADE-207-263A (Z)
2nd Edition
Jul. 1999
Description
The HA13158A is four-channel BTL amplifier IC designed for car audio, featuring high output and low
distortion, and applicable to digital audio equipment. It provides 34 W output per channel, with a 13.7 V
power supply and at Max distortion.
Functions
4 ch BTL power amplifiers
Built-in standby circuit
Built-in muting circuit
Built-in protection circuit (surge, T.S.D and ASO)
Features
Low power dissipation
Soft thermal limiter
Requires few external parts (C:3, R:1)
Popping noise minimized
Low output noise
Built-in high reliability protection circuit
Pin to pin with HA13153A/HA13154A/HA13155/HA13157/HA13158
HA13158A
Rev.2, Jul. 1999, page 2 of 15
Block Diagram
2
5 V
5 V
37.5 k
23.5 k
25 k
Q1 ON
BIAS ON
Q2 ON
MUTE ON
10
Notes:
Standby
Power is turned on when a signal of
3.5 V or 0.05 mA is impressed at pin 2.
When pin 2 is open or connected to
GND, standby is turned on (output off).
Muting
Muting is turned off (output on) when
a signal of 3.5 V or 0.2 mA is impressed
at pin 10.
When pin 10 is open or connected to
GND, muting is turned on (output off).
1.
2.
TAB (header of IC) connected to GND.
3.
STBY
2
IN-1
1
11
IN-2
IN-3
13
23
IN-4
MUTE
10
R1
7.5 k
12
22
TAB
C3
10
/10 V
14
18
6
IN V
CC
PV
CC
1
Buffer & Mute-1
Buffer & Mute-2
Buffer & Mute-3
Buffer & Mute-4
Protector
(ASO, Surge, TSD)
Amp-1
Amp-2
Amp-3
Amp-4
V
CC
13.2 V
C1
4400
/16 V
3
4
5
7
8
9
15
16
17
19
20
21
Unit
R:
C: F
C2
0.1
/16 V
PV
CC
2
HA13158A
Rev.2, Jul. 1999, page 3 of 15
Absolute Maximum Ratings
Item
Symbol
Rating
Unit
Operating supply voltage
V
CC
18
V
Supply voltage when no signal*
1
V
CC
(DC)
26
V
Peak supply voltage*
2
V
CC
(PEAK)
50
V
Output current*
3
I
O
(PEAK)
4
A
Power dissipation*
4
P
T
83
W
Junction temperature
Tj
150
C
Operating temperature
Topr
30 to +85
C
Storage temperature
Tstg
55 to +125
C
Note:
1. Tolerance within 30 seconds.
2. Tolerance in surge pulse waveform.
3. Value per 1 channel.
4. Value when attached on the infinite heat sink plate at Ta = 25 C.
The derating carve is as shown in the graph below.
100
50
0
25
50
85
100
150
Ambient temperature Ta (
C)
Power dissipation P
T
(W)
A: When heat sink is infinite (
j-a = 1.5
C/W)
B: When
f (thermal resistance of heat sink) = 3
C/W
(
j-a = 4.5
C/W)
B
83 W
28 W
A
HA13158A
Rev.2, Jul. 1999, page 4 of 15
Electrical Characteristics (V
CC
= 13.2 V, f = 1 kHz, R
L
= 4
, Rg = 600
, Ta = 25C)
Item
Symbol
Min
Typ
Max
Unit
Test Conditions
Quiescent current
I
Q1
--
220
--
mA
Vin = 0
Output offset voltage
V
Q
180
0
+180
mV
Gain
G
V
30.5
32
33.5
dB
Gain difference between
channels
G
V
1.0
0
+1.0
dB
Rated output power
P
O
--
20
--
W
V
CC
= 13.2 V,
THD = 10%, R
L
= 4
Max output power
P
OMAX
--
34
--
W
V
CC
= 13.7 V, R
L
= 4
Total harmonic distortion
T.H.D.
--
0.03
--
%
Po = 3 W
Output noise voltage
WBN
--
0.15
--
mVrms
Rg = 0
,
BW = 20 to 20 kHz
Ripple rejection
SVR
--
55
--
dB
f = 120 Hz
Channel cross talk
C.T.
--
70
--
dB
Vout = 0 dBm
Input impedance
Rin
--
25
--
k
Standby current
I
Q2
--
--
10
A
Standby control voltage (high)
V
STH
3.5
--
V
CC
V
Standby control voltage (low)
V
STL
0
--
1.5
V
Muting control voltage (high)
V
MH
3.5
--
V
CC
V
Muting control voltage (low)
V
ML
0
--
1.5
V
Muting attenuation
ATTM
--
70
--
dB
Vout = 0 dBm
HA13158A
Rev.2, Jul. 1999, page 5 of 15
Pin Explanation
Pin
No.
Symbol
Functions
Input
Impedance
DC
Voltage
Equivalence Circuit
1
IN1
CH1 INPUT
25 k
(Typ)
0 V
1
25 k
11
IN2
CH2 INPUT
13
IN3
CH3 INPUT
23
IN4
CH4 INPUT
2
STBY
Standby control
90 k
(at Trs. cutoff)
--
2
23.5 k
37.5 k
3
OUT1 (+)
CH1 OUTPUT
--
V
CC
/2
3
5
OUT1 ()
7
OUT2 (+)
CH2 OUTPUT
9
OUT2 ()
15
OUT3 (+)
CH3 OUTPUT
17
OUT3 ()
19
OUT4 (+)
CH4 OUTPUT
21
OUT4 ()
10
MUTE
Muting control
25 k
(Typ)
--
10
25 k
22
RIPPLE
Bias stability
--
V
CC
/2
22
HA13158A
Rev.2, Jul. 1999, page 6 of 15
Pin Explanation (cont)
Pin
No.
Symbol
Functions
Input
Impedance
DC
Voltage
Equivalence Circuit
6
PV
CC
1
Power of
output stage
--
V
CC
--
18
PV
CC
2
14
INV
CC
Power of
input stage
--
V
CC
--
4
CH1 GND
CH1 power GND
--
--
--
8
CH2 GND
CH2 power GND
16
CH3 GND
CH3 power GND
20
CH4 GND
CH4 power GND
12
IN GND
Input signal GND
--
--
--
HA13158A
Rev.2, Jul. 1999, page 7 of 15
Point of Application Board Design
1. Notes on Application Board's Pattern Design
For increasing stability, the connected line of V
CC
and OUTGND is better to be made wider and lower
impedance.
For increasing stability, it is better to place the capacitor between V
CC
and GND (0.1
F) close to IC.
It is better to place the grounding of resistor (Rg), between input line and ground, close to INGND (Pin
12) because if OUTGND is connected to the line between Rg and INGND, THD will become worse due
to current from OUTGND.
Rg
0.1
F
V
CC
1
12
6
5
4
3
Figure 1 Notes on Application Board's Pattern Design
2. How to Reduce the Popping Noise by Muting Circuit
At normal operating circuit, Muting circuit operates at high speed under 1
s.
In case popping noise becomes a problem, it is possible to reduce the popping noise by connecting
capacitor, which determines the switching time constant, between pin 10 and GND. (Following figure
2)
We recommend value of capacitor greater then 1
F.
Also transitional popping noise can be reduced sharply by muting before V
CC
and Standby are ON/OFF.
0 V
5 V
7.5 k
4.7
F
10
Muting
control
Figure 2 How to use Muting Circuit
Table 1
Muting ON/OFF Time
C (
F)
ON Time
OFF Time
nothing
under 1
s
under 1
s
0.47
2 ms
2 ms
4.7
19 ms
19 ms
HA13158A
Rev.2, Jul. 1999, page 8 of 15
Characteristic Curves
50
20
Supply Voltage V
CC
(V)
Output Power Po, Pomax (W)
0
Output Power vs. Supply Voltage
60
40
30
10
8
10
12
14
16
18
20
Supply Voltage V
CC
(V)
0
Quiescent current vs. Supply Voltage
400
300
200
100
Quiescent current I
Q
(mA)
0
8
10
12
14
16
18
20
0
R
L
= 4
, f = 1 kHz, 4ch operation
R
L
=
Pomax (Vin = 4 Vrms)
Po (THD = 10 %)
HA13158A
Rev.2, Jul. 1999, page 9 of 15
Frequency f (Hz)
Total Harmonic Distortion THD (%)
Total Harmonic Distortion vs. Frequency
20
50
100 200
500
1k
2k
5k
5
10k 20k
2
0.5
1
0.2
0.1
0.01
0.02
0.05
V
CC
= 13.2 V, R
L
= 4
, 80 kHz L.P.F ON
Po = 1.5 W
Po = 8 W
Output Power Po (W)
Total Harmonic Distortion THD (%)
Total Harmonic Distortion vs. Output Power
0.02
0.05 0.1
0.2
0.5
1
2
5
5
10
10
20 30
2
0.5
1
0.2
0.1
0.01
0.02
0.05
0.01
f = 100 Hz
f = 1 kHz
f = 10 kHz
V
CC
= 13.2 V, R
L
= 4
, 80 kHz L.P.F ON
HA13158A
Rev.2, Jul. 1999, page 10 of 15
Frequency f (Hz)
Crosstalk C
T
(dB)
Crosstalk vs. Frequency (1)
20
50
100 200
500
1k
2k
5k
80
10k 20k
70
50
60
40
30
0
10
20
V
CC
= 13.2 V, Vout = 0 dBm,
80 kHz L.P.F, Input Ch1
Ch2
Ch3
Ch4
Frequency f (Hz)
Crosstalk C
T
(dB)
Crosstalk vs. Frequency (2)
20
50
100 200
500
1k
2k
5k
80
10k 20k
70
50
60
40
30
0
10
20
V
CC
= 13.2 V, Vout = 0 dBm,
80 kHz L.P.F, Input Ch2
Ch1
Ch3
Ch4
HA13158A
Rev.2, Jul. 1999, page 11 of 15
Frequency f (Hz)
Crosstalk C
T
(dB)
Crosstalk vs. Frequency (3)
20
50
100 200
500
1k
2k
5k
80
10k 20k
70
50
60
40
30
0
10
20
V
CC
= 13.2 V, Vout = 0 dBm,
80 kHz L.P.F, Input Ch3
Ch1
Ch2
Ch4
Frequency f (Hz)
Crosstalk C
T
(dB)
Crosstalk vs. Frequency (4)
20
50
100 200
500
1k
2k
5k
80
10k 20k
70
50
60
40
30
0
10
20
Ch1
Ch2
Ch3
V
CC
= 13.2 V, Vout = 0 dBm,
80 kHz L.P.F, Input Ch4
HA13158A
Rev.2, Jul. 1999, page 12 of 15
Supply Voltage Rejection Ratio SVR (dB)
Supply Voltage Rejection Ratio vs. Frequency
Wide Band Noise WBN (mV)
Wide Band Noise vs. Signal Source Resistance
Signal Source Resistance Rg (
)
20
50
100 200
500
1k
2k
5k
5
10k 20k
2
0.5
1
0.2
0.1
0.01
0.02
0.05
50k
V
CC
= 13.2 V, R
L
= 4
,
Vin = 0
Mute ON (Ch1Ch4)
Mute OFF (Ch1Ch4)
Frequency f (Hz)
20
50
100 200
500
1k
2k
5k
80
10k 20k
70
50
60
40
30
0
10
20
V
CC
= 13.2 V, R
L
= 4
,
Vripple = 0 dBm, 80 kHz L.P.F ON
Ch1
Ch2
Ch3
Ch4
HA13158A
Rev.2, Jul. 1999, page 13 of 15
Frequency f (Hz)
Power Dissipation P
T
(W)
Power Dissipation vs. Frequency
20
50
100 200
500
1k
2k
5k
15
10k 20k
10
5
0
V
CC
= 13.2 V, R
L
= 4
, Po = 10 W, 1ch operation
Power Dissipation P
T
(W)
Power Dissipation vs. Output Power
Output Power Po (W)
0.02
0.05 0.1
0.2
0.5
1
2
5
10
20 30
50
100
20
10
1
2
5
R
L
= 4
, f = 1 kHz, 1ch operation
V
CC
= 13.2 V
V
CC
= 14.4 V
V
CC
= 16 V
HA13158A
Rev.2, Jul. 1999, page 14 of 15
Package Dimensions
Hitachi Code
JEDEC
EIAJ
Weight (reference value)
SP-23TE
Conforms
--
8.5 g
Unit: mm
2 R1.84 0.19
4.32 0.05
19.81
30.18 0.25
2.79
10.70 0.12
3.80 0.05
+ 0.05
0.1
1.55
4.50 0.12
17.78 0.25
4.14 0.33
23
1
4.29
5.08
+ 0.06
0.04
0.40
3.80 0.05
17.50 0.13
0.70
+0.09
0.1
1.27
27.94
0.25 M
1.12
HA13158A
Rev.2, Jul. 1999, page 15 of 15
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received the latest product standards or specifications before final design, purchase or use.
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contact Hitachi's sales office before using the product in an application that demands especially high
quality and reliability or where its failure or malfunction may directly threaten human life or cause risk
of bodily injury, such as aerospace, aeronautics, nuclear power, combustion control, transportation,
traffic, safety equipment or medical equipment for life support.
4. Design your application so that the product is used within the ranges guaranteed by Hitachi particularly
for maximum rating, operating supply voltage range, heat radiation characteristics, installation
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