SANYO STK433-130N-E

Ordering number : ENA2102
STK433-130N-E
Thick-Film Hybrid IC
2channel class-AB Audio Power IC
150W+150W
Overview
The STK433-130N-E is a hybrid IC designed to be used in 150W × 2ch class AB audio power amplifiers.
Application
• Audio Power amplifiers
Features
• Pin-to-pin compatible outputs ranging from 40W to 150W.
• Miniature package.
• Output load impedance: RL = 6Ω recommended.
• Allowable load shorted time: 0.3 second
• Allows the use of predesigned applications for standby and mute circuit.
Series model
STK433-040N-E
STK433-060N-E
STK433-130N-E
STK433-330N-E
Output1 (10%/1kHz)
40W × 2ch
50W × 2ch
150W × 2ch
150W × 3ch
Output2 (0.4%/20Hz to 20kHz)
25W × 2ch
35W × 2ch
100W × 2ch
100W × 3ch
Max. rating VCC (quiescent)
±38V
±46V
±71.5V
±71.5V
Max. rating VCC (6Ω)
±36V
±40V
±63V
±63V
Recommended operating VCC (6Ω)
±24V
±27V
±44V
±44V
67.0mm×25.6mm×9.0mm
64.0mm×36.6mm×9.0mm
Dimensions (excluding pin height)
47.0mm×25.6mm×9.0mm
STK433-840N-E
STK433-870N-E
STK433-890N-E
Output1 (10%/1kHz)
40W × 4ch
60W × 4ch
80W × 4ch
Output2 (0.4%/20Hz to 20kHz)
25W × 4ch
40W × 4ch
50W × 4ch
Max. rating VCC (quiescent)
±38V
±50V
±54V
Max. rating VCC (6Ω)
±36V
±44V
±47V
Recommended operating VCC (6Ω)
±25V
±30V
±34V
Dimensions (excluding pin height)
64.0mm×31.1mm×9.0mm
78.0mm×44.1mm×9.0mm
Any and all SANYO Semiconductor Co.,Ltd. products described or contained herein are, with regard to
"standard application", intended for the use as general electronics equipment. The products mentioned herein
shall not be intended for use for any "special application" (medical equipment whose purpose is to sustain life,
aerospace instrument, nuclear control device, burning appliances, transportation machine, traffic signal system,
safety equipment etc.) that shall require extremely high level of reliability and can directly threaten human lives
in case of failure or malfunction of the product or may cause harm to human bodies, nor shall they grant any
guarantee thereof. If you should intend to use our products for new introduction or other application different
from current conditions on the usage of automotive device, communication device, office equipment, industrial
equipment etc. , please consult with us about usage condition (temperature, operation time etc.) prior to the
intended use. If there is no consultation or inquiry before the intended use, our customer shall be solely
responsible for the use.
Specifications of any and all SANYO Semiconductor Co.,Ltd. products described or contained herein stipulate
the performance, characteristics, and functions of the described products in the independent state, and are not
guarantees of the performance, characteristics, and functions of the described products as mounted in the
customer's products or equipment. To verify symptoms and states that cannot be evaluated in an independent
device, the customer should always evaluate and test devices mounted in the customer ' s products or
equipment.
80112HKPC 018-11-0062 No.A2102-1/11
STK433-130N-E
Specifications
Absolute Maximum Ratings at Ta = 25°C, Tc = 25°C unless otherwise specified
Parameter
Symbol
Maximum power supply voltage
Minimum operation supply voltage
#13 Operating voltage
Conditions
VCC max (0)
Non- signal
VCC max (1)
Signal, RL ≥ 6Ω
Ratings
VCC min
*5
VST OFF max
Unit
±71.5
V
±63
V
±10
V
-0.3 to +5.5
V
Thermal resistance
θj-c
Per one power transistor
1.6
°C/W
Junction temperature
Tj max
Should satisfy Tj max and Tc max
150
°C
Operating substrate temperature
Tc max
125
°C
Storage temperature
Tstg
-30 to +125
°C
Allowable time for load short-circuit
ts
VCC = ±44V, RL = 6Ω, f = 50Hz
PO = 100W, 1ch drive
*4
0.3
s
Operating Characteristics at Tc = 25°C, RL = 6Ω (Non-inductive Load), Rg = 600Ω, VG = 30dB
Conditions *2
Parameter
Output power
Total harmonic distortion
Frequency characteristics
Symbol
*1
*1
*1
Input impedance
Output noise voltage
PO 1
±44
20 to 20k
0.4
PO 2
±44
1k
10
THD 1
±44
20 to 20k
THD 2
±44
1k
±44
ri
±44
1k
PO
[W]
THD
min
[%]
96
5.0
VG=30dB
1.0
+0 -3dB
100
±53
Rg=2.2kΩ
±53
No load
Output neutral voltage
VN
±53
VST ON
±44
Stand-by
VST OFF
±44
Operation
Unit
W
0.4
20 to 50k
%
Hz
55
ICCO
#13 Stand-by OFF threshold *5
max
0.01
1.0
VNO
*5
typ
150
Quiescent current
#13 Stand-by ON threshold
*3
[Hz]
fL, fH
f
Ratings
VCC
[V]
kΩ
1.0
mVrms
40
80
100
mA
-70
0
+70
mV
0
0.6
V
3.0
5.5
V
2.5
Note
*1. 1channel operation.
*2. All tests are measured using a constant-voltage supply unless otherwise specified
*3. The output noise voltage is peak value of an average-reading meter with a rms value scale (VTVM).
A regulated AC supply (50Hz) should be used to eliminate the effects of AC primary line flicker noise
*4. Allowable time for load short-circuit and output noise voltage are measured using the specified transformer power
supply.
*5. The impression voltage of ‘#13 (Stand-By) pin’ must not exceed the maximum rating.
Power amplifier operate by impressing voltage +2.5 to +5.5v to ‘#13 (Stand-By) pin’.
* Please connect - PreVcc pin (#1 pin)with the stable minimum voltage.
and connect so that current does not flow in by reverse bias.
* In case of heat sink design, we request customer to design in the condition to have assumed market.
* The case of this Hybrid-IC is using thermosetting silicon adhesive (TSE322SX).
* Weight of HIC : (typ) 18.4g
Outer carton dimensions (W×L×H) : 429mm×245mm×275mm
Specified transformer power supply
(Equivalent to MG-250)
DBA40C
10000μF
+
+
10000μF
+VCC
500Ω
500Ω
-VCC
No.A2102-2/11
STK433-130N-E
Package Dimensions
unit : mm (typ)
67.0
60.0
2.0
(16.0)
20.8
15
0.4
4.0
1
25.6
16.0
5.0
3.6
9.0
(R1.8)
0.5
2.9
14 2.0=28.0
5.5
RoHS directive pass
Equivalent Circuit
3
8
Pre Driver
CH1
Pre Driver
CH2
11
15
12
14
Stand-by Circuit
1
2
SUB
9
5 4
6 7
10
13
No.A2102-3/11
STK433-130N-E
Application Circuit
STK433-130N-E
SUB
Ch1 Ch1 Ch2 Ch2
/AMP IC
Ch1
-PRE -VCC +VCC OUT OUT OUT OUT +PRE GND GND IN
1
2
3
4
5
R20
R23
6
7
8
9
10
11
Ch1
Ch2
NF ST-BY NF
Ch2
IN
12
15
13
14
R21
C19
R08
C20
R30
Stand-by
R09
C05
C10
C11
+
R11
C13
+
R12
C14
R06
+
R03
GND
C07
R05
+
C04
R02
L02
+VCC
C01
+
C23
+
R01
C03
+
Ch2
C08
R15
C17
R18
Ch1
Ch2
GND
GND
C02
+
-VCC
L01
R17
C16
GND
Ch1
R14
PCB Layout Example
Top view
No.A2102-4/11
STK433-130N-E
STK433-040N-E/060N-E/130N-E/330N-E PCB PARTS LIST
PCB Name : STK403-000Sr/100Sr/200Sr PCBA
Location No.
(*2) 2ch Amp doesn't mount
parts of (
RATING
Component
).
STK433-
Hybrid IC#1 Pin Position
-
040N-E
060N-E
R01
100Ω, 1W
○
R02, R03, (R04)
1kΩ, 1/6W
○
R05, R06, (R07), R08, R09, (R10)
56KΩ, 1/6W
○
R11, R12, (R13)
1.8KΩ, 1/6W
○
R14, R15, (R16)
4.7Ω, 1/4W
○
R17, R18, (R19)
4.7Ω, 1W
○
R20, R21, (R22)
0.22Ω, 5W
○
C01, C02, C03, C23 (*3)
100μF, 100V
○
C04, C05, (C06)
2.2μF, 50V
○ (*1)
C07, C08, (C09)
470pF, 50V
○
C10, C11, (C12)
3pF, 50V
○
C13, C14, (C15)
10μF, 10V
○ (*1)
C16, C17, (C18)
0.1μF, 50V
C19, C20, (C21)
***pF, 50V
R34, R35, (R36)
3kΩ, 1/6W
L01, L02, (L03)
3μH
○
Tr1
VCE ≥ 75V, IC ≥ 1mA
○
D1
Di
○
Stand-By
R30 (*4)
***kΩ, 1/6W
○ (*4)
Control
R31
33kΩ, 1/6W
○
Circuit
R32
1kΩ, 1/6W
○
R33
2kΩ, 1/6W
○
C32
33μF, 10V
○
J1, J2, J3, J4, J5, J6, J8, J9
J7, JS2, JS3, JS4, JS5, JS7
JS8, JS9
JS6, JS10
JS1 (R23)
130N-E/
330N-E
○
100pF
56pF
N.C.
Short
-
○
-
-
-
○
100Ω, 1W
(*1) Capacitor mark “A” side is “ – ” (negative).
(*2) STK433-040N-E/060N-E/130N-E (2ch Amp) doesn't mount parts of (
(*3) Add parts C23 to the other side of PCB.
(*4) Recommended standby circuit is used.
○
)
No.A2102-5/11
STK433-130N-E
Recommended external components
STK433-040N-E/060N-E/130N-E/330N-E
Parts
Recommended
Location
value
R01, R23
100Ω/1W
Above
Below
Recommended value
Recommended value
Resistance for Ripple filter. (Fuse resistance is recommended.
Short-through current
Short-through current
Ripple filter is constituted with C03, C23.)
may decrease at
may increase at high
high frequency.
frequency.
Circuit purpose
R02, R03, R04
1kΩ
Resistance for input filters.
R05, R06, R07
56kΩ
Input impedance is determined.
R08, R09, R10
56kΩ
Voltage Gain (VG) is determined with R11, R12, R13
R11, R12, R13
1.8kΩ
Voltage Gain (VG) is determined with R8, R9, R10
It may oscillate.
With especially no
(As for VG, it is desirable to set up by R11, R12, R13)
(Vg < 30dB)
problem
R14, R15, R16
4.7Ω
Resistance for oscillation prevention.
-
-
R17, R18, R19
4.7Ω/1W
Resistance for oscillation prevention.
-
-
R20, R21, R22
0.22Ω/2W
This resistance is used as detection resistance of the protection
Decrease of
circuit application.
Maximum output
-
-
Output neutral voltage(VN) shift.
(It is referred that R05=R08, R06=R09)
-
-
It may cause thermal
runaway
Power
R30
Note *5
Select Restriction resistance, for the impression voltage of ‘#17 (Stand-By) pin’ must not exceed the maximum
rating.
C01, C02
100μF/50V
Capacitor for oscillation prevention.
• Locate near the HIC as much as possible.
• Power supply impedance is lowered and stable operation of
-
-
the IC is carried out. (Electrolytic capacitor is recommended.)
C03, C23
100μF/50V
Decoupling capacitor
The change in the Ripple ingredient mixed in
• The Ripple ingredient mixed in an input side Is removed from a
an input side from a power supply line
power supply line. (Ripple filter is constituted with R01, R23.)
C04, C05, C06
2.2μF/50V
C07, C08, C09
470pF
Input coupling capacitor.(for DC current prevention.)
-
Input filter capacitor
• A high frequency noise is reduced with the filter constituted by
-
R02, R03, R04
C10, C11, C12
3pF
C13, C14, C15
10μF/10V
Capacitor for oscillation prevention.
It may oscillate.
Negative feedback capacitor.
The voltage gain (VG)
The voltage gain (VG)
The cutoff frequency of a low cycle changes.
of low frequency is
of low frequency
(fL = 1/(2π ⋅ C13 ⋅ R11))
extended. However,
decreases.
the pop noise at the
time of a power
supply injection also
becomes large.
C16, C17, C18
0.1μF
Capacitor for oscillation prevention.
It may oscillate.
C19, C20, C21
100pF (040N-E)
Capacitor for oscillation prevention.
It may oscillate.
56pF (060N-E)
N.C. (130N-E,
330N-E)
L01, L02, L03
3μH
Coil for oscillation prevention.
With especially
It may oscillate.
no problem
No.A2102-6/11
STK433-130N-E
Pin Layout
[STK433-000N/-100N/-300Nsr Pin Layout]
1
2
3
4
5
(Size) 47.0mm×25.6mm×9.0mm
6
7
8
9
10
11
12
13
14
15
I
N
S
N
I
N
F
T
F
N
2ch classAB/2.00mm
STK433-040N 40W/JEITA
-
-
+
O
O
O
O
+
STK433-060N 50W/JEITA
P
V
V
U
U
U
U
P
S
G
R
C
C
T
T
T
T
R
U
N
/
/
A
/
/
E
C
C
/
/
/
/
E
B
D
C
C
N
C
C
C
C
C
C
H
H
D
H
H
(Size) 67.0mm×25.6mm×9.0mm
H
H
H
H
1
1
⎪
2
2
STK433-130N 150W/JEITA
1
1
2
2
B
+
-
+
-
Y
4
5
6
7
13
14
15
1
2
3
(Size) 64.0mm×36.6mm×9.0mm
STK433-330N 150W/JEITA
8
9
10
11
12
16
17
18
19
3ch classAB/2.00mm
-
-
+
O
O
O
O
+
I
N
S
N
I
I
N
O
O
P
V
V
U
U
U
U
P
S
G
N
F
T
F
N
N
F
U
U
R
C
C
T
T
T
T
R
U
N
/
/
A
/
/
/
/
T
T
E
C
C
/
/
/
/
E
B
D
C
C
N
C
C
C
C
/
/
C
C
C
C
H
H
D
H
H
H
H
C
C
H
H
H
H
1
1
⎪
2
2
3
3
H
H
1
1
2
2
B
3
3
+
-
+
-
Y
+
-
5
6
7
18
19
20
21
22
23
[STK433-000N/-100N/-800Nsr Pin Layout]
1
2
3
4
(Size) 47.0mm×25.6mm×9.0mm
8
9
10
11
12
13
14
15
I
N
S
N
I
N
F
T
F
N
2ch classAB/2.00mm
STK433-040N 40W/JEITA
-
-
+
O
O
O
O
+
STK433-060N 50W/JEITA
P
V
V
U
U
U
U
P
S
G
R
C
C
T
T
T
T
R
U
N
/
/
A
/
/
E
C
C
/
/
/
/
E
B
D
C
C
N
C
C
C
C
C
C
H
H
D
H
H
(Size) 67.0mm×25.6mm×9.0mm
H
H
H
H
1
1
⎪
2
2
STK433-130N 150W/JEITA
1
1
2
2
B
+
-
+
-
Y
14
15
16
1
2
3
4
5
6
7
8
9
STK433-840N 40W/JEITA
-
-
+
O
O
O
O
+
I
N
S
N
I
N
I
I
N
O
O
O
O
STK433-870N 60W/JEITA
P
V
V
U
U
U
U
P
S
G
N
F
T
F
N
F
N
N
F
U
U
U
U
R
C
C
T
T
T
T
R
U
N
/
/
A
/
/
/
/
/
/
T
T
T
T
E
C
C
/
/
/
/
E
B
D
C
C
N
C
C
C
C
C
C
/
/
/
/
C
C
C
C
H
H
D
H
H
H
H
H
H
C
C
C
C
(Size) 78.0mm×44.1mm×9.0mm
H
H
H
H
1
1
⎪
2
2
3
3
4
4
H
H
H
H
STK433-890N 80W/JEITA
1
1
2
2
B
3
3
4
4
+
-
+
-
Y
-
+
-
+
(Size) 64.0mm×31.1mm×9.0mm
10
11
12
13
17
4ch classAB/2.00mm
No.A2102-7/11
STK433-130N-E
240
Output power, PO/ch -- W
220
200
180
160
f=20kHz
f=1kHz
2 3
5 7 1.0
2 3
5 7 10
2 3
5 7 100
Output power, PO/ch -- W
2 3
5 71000
Total power dissipation within the board, Pd -- W
10
7
5
3
2
1.0
7
5
3
2
0.1
7
5
3
2
0.01
7
5
3
2
0.001
0.1
260
THD – PO
VCC=±44V
RL=6Ω
2ch Drive
VG=30dB
Rg=600Ω
Tc=25°C
PO – VCC
f=1kHz
RL=6Ω
2ch Drive
VG=30dB
Rg=600Ω
Tc=25°C
260
240
220
200
180
160
140
120
100
80
60
40
20
0
0.1
2 3
5 7 1.0
2 3
5 7 10
2 3
5 7 100
100
80
60
VCC=±44V
RL=6Ω
2ch Drive
VG=30dB
Rg=600Ω
Tc=25°C
200
180
140
100
80
60
20
20
50
Supply voltage, VCC -- ±V
60
THD=0.4%
120
40
40
THD=10%
160
40
30
5 71000
PO – f
220
120
2 3
Output power, PO/ch -- W
240
140
0
20
Pd – PO
VCC=±44V
f=1kHz
RL=6Ω
2ch Drive
VG=30dB
Rg=600Ω
Tc=25°C
260
Output power, PO/ch -- W
100
7
5
3
2
T H TH
D=
D
=0
10
.4
%
%
Total harmonic distortion, THD -- %
Characteristic of Evaluation Board
0
10
2 3
5 7 100
2 3
5 7 1k
2 3
5 7 10k
Frequency, f -- Hz
2 3
5 7100k
No.A2102-8/11
STK433-130N-E
A Thermal Design Tip For STK433-130N-E Amplifier
[Thermal Design Conditions]
The thermal resistance (θc-a) of the heat-sink which manages the heat dissipation inside the Hybrid IC will be
determined as follow:
(Condition 1) The case temperature (Tc) of the Hybrid IC should not exceed 125°C
Pd × θc-a + Ta < 125°C ························································································(1)
Where Ta : the ambient temperature for the system
(Condition 2) The junction temperature of each power transistor should not exceed 150°C
Pd × θc-a + Pd/N × θj-c + Ta < 150°C··································································(2)
Where N : the number of transistors (two for 1 channel , ten for channel)
θj-c : the thermal resistance of each transistor (see specification)
Note that the power consumption of each power transistor is assumed to be equal to the total power dissipation (Pd)
divided by the number of transistors (N).
From the formula (1) and (2), we will obtain:
θc-a < (125 − Ta)/Pd·····························································································(1)’
θc-a < (150 − Ta)/Pd − θj-c/N···············································································(2)’
The value which satisfies above formula (1)’ and (2)’ will be the thermal resistance for a desired heat-sink.
Note that all of the component except power transistors employed in the Hybrid IC comply with above conditions.
[Example of Thermal Design]
Generally, the power consumption of actual music signals are being estimated by the continuous signal of
1/8 PO max. (Note that the value of 1/8 PO max may be varied from the country to country.)
(Sample of STK433-130N-E ; 100W×2ch)
If VCC is ±44V, and RL is 6Ω, then the total power dissipation (Pd) of inside Hybrid IC is as follow;
Pd = 91W (at 12.5W output power,1/8 of PO max)
There are four (4) transistors in Audio Section of this Hybrid IC, and thermal resistance (θj-c) of each transistor is
1.6°C/W. If the ambient temperature (Ta) is guaranteed for 50°C, then the thermal resistance (θc-a) of a desired heatsink should be;
From (1)’ θc-a < (125 − 50)/91
< 0.82
From (2)’ θc-a < (150 − 50)/91 − 1.6/4
< 0.70
Therefore, in order to satisfy both (1)’ and (2)’, the thermal resistance of a desired Heat-sink will be 0.70°C/W.
[Note]
Above are reference only. The samples are operated with a constant power supply. Please verify the conditions when
your system is actually implemented.
No.A2102-9/11
STK433-130N-E
STK433-000N-E/100N-E series Stand-by Control & Mute Control & Load-Short
Protection Application
(*1) Please use restriction resistance as there is no Stand-by
terminal voltage (#13pin) beyond maximun rating (VSTmax).
STK433-000N-E/100N-E series
Ch1 Ch1 Ch2 Ch2 +PRE SUB GND Ch1
-PRE -VCC +VCC OUT
IN
OUT OUT OUT
4
5
7
56kΩ 6.8kΩ
56kΩ
56kΩ 6.8kΩ
6
8
9
10
Ch1 ST-BY Ch2
NF
NF
Ch2
IN
12
15
11
13
14
1kΩ
0.22kΩ/5w
3
Stand-by Control(ex)
33kΩ
(*1)
2.7kΩ
H : Operation Mode(+5V)
+ 33μF
L : Stand-by Mode(0V)
2kΩ
/10V
56kΩ
2
0.22kΩ/5w
1
Ch2 IN
+
Load Short Protection
Circuit
+
+
10kΩ
22kΩ
GND
10kΩ
56kΩ
Ch1 IN
+
10kΩ
1kΩ
0.1μF
+VCC
10kΩ
+
+
Latch Up
Circuit
R1
(*4)
+
V1
Mute Control
H : Single Mute
L : Normal
2.2kΩ
Ch2 OUT
GND
+5V
Stand-by Control
GND
+
GND
+5V
-VCC
Mute Control
Ch1 OUT
MUTE
(*4) R1 is changed depending on the power-supply voltage(-VCC).
Please set resistance(R1) to become [V1=0V] by the following calculation types.
ST-BY
PLAY
MUTE
ST-BY
[STK433-000N-E/100N-E series Stand-By Control Example]
[Feature]
• The pop noise which occurs to the time of power supply on/off can be improved substantially by recommendation
Stand-By Control Application.
• Stand-By Control can be done by additionally adjusting the limitation resistance to the voltage such as miccom, the
set design is easy.
(Reference circuit) STK433-000N-E/100N-E series test circuit To Stand-By Control added +5V.
1kΩ (*3)
#13pin Stand-By OFF threshold.
33kΩ
2.7kΩ (*1)
VST
ΔVBE
+ 33μF
(*2)
2kΩ
(*3)
Stand-by Control
H : Operation Mode(+5V)
L : Stand-by Mode(0V)
IST
1
2
3
4
5
6
7
8
9
10
11
SUB/AMP IC Ch1
Ch1 Ch2 Ch2
-PRE -VCC +VCC Ch1
GND IN
OUT OUT OUT OUT +PRE GND
STK433-000N-E/100N-E
series
12
13
Ch1 STNF BY
14
15
Ch2 Ch2
NF IN
ΔVBE
Stand-By Circuit
in PreDriver IC
4.7kΩ (*2)
Switching transistor
in the bias circuit
ex)Stand-By Control Voltage VST=+5V
VST is set by the limitation resistance(*1).
.IST=(VST-VBE*2)/((*1)+(*2))
=(5v-0.6v*2)/(4.7 k Ω+2.7kΩ)
=0.513(mA)
.VST=IST 4.7kΩ+VBE=0.513 4.7k+0.6=3.0v
[Operation explanation] #13pin Stand-By Control Voltage VST
(1) Operation Mode
The switching transistor in the bias circuit turns on and places the amplifier into the operating mode, when 13pin
(VST) voltage added above 2.5V (typ 3.0V).
(2) Stand-By Mode
When 13pin (VST) voltage is stopped (= 0V), the switching transistor in the bias circuit turn off. placing the
amplifier into the standby mode.
(*1) The current limiting resistor must be used to ensure that stand-by pin (13pin) voltage does not exceed its
maximum rated value VST max.
(*2) The pop noise level when the power is turned on can be reduced by setting the time constant with a capacitor
in operating mode.
(*3) Determines the time constant at which the capacitor (*2) is discharged in stand-by mode.
No.A2102-10/11
STK433-130N-E
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PS No.A2102-11/11