TB2941HQ × 4ch Audio Power Amp IC Maximum Power 49 W BTL

TB2941HQ × 4ch Audio Power Amp IC Maximum Power 49 W BTL
TB2941HQ
Bi-CMOS Linear Integrated Circuit Silicon Monolithic
TB2941HQ
Maximum Power 49 W BTL × 4ch Audio Power Amp IC
1.
Description
The TB2941HQ is a power IC with built-in four-channel BTL
amplifier developed for car audio application. The maximum
output power POUT is 49 W using a pure complementary P-ch and
N-ch DMOS output stage.
In addition, a standby switch, a mute function, output offset
voltage detector, high-side switch and various protection features
are included.
2.
Weight: 7.7 g (typ.)
Applications
Power Amp IC developed for car audio applications.
3.
Features
• High output power, low distortion, and low noise property (for details, refer to the Table 1 Typical
Characteristics).
• Built-in high-side switches. (Pin25) (Note2)
• Built-in detecting output offset voltage. (Pin1,Pin25) (Note2)
• Built-in muting function. (Pin22)
• Built-in auto muting functions (for low Vcc and stand-by
sequence)
Table 1 Typical Characteristics
(Note1)
Test condition
• Built-in stand-by switch. (Pin4)
• Built-in various protection circuits (thermal shut down,
over-voltage, short to VCC, short to GND, and output to output
short)
Typ.
Unit
Output power (POUT)
VCC = 15.2 V, JEITA max
49
VCC = 13.7 V, JEITA max
40
THD = 10%
24
W
Output power (POUT) (RL = 2 Ω)
VCC = 13.7 V, JEITA max
73
THD = 10%
45
W
Total harmonic distortion (THD)
POUT = 4 W
0.006
%
Output noise voltage (VNO) (Rg = 0 Ω)
Filter : DIN AUDIO
65
µVrms
Operating Supply voltage range (VCC)
Note1:
RL = 4 Ω
6 to 18
RL = 2 Ω
6 to 16
V
Typical test conditions: VCC = 13.2 V, f = 1 kHz, RL = 4 Ω, Ta = 25°C; unless otherwise specified.
Rg: signal source resistance
Note2:
Pin25 functions are selected by mute terminal (pin 22) voltage.
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6
VCC2
20
VCC1
11
C1: 0.22 μF IN1
9
MPC
DFA
8
7
AC-GND
C1: 0.22 μF IN2
12
5
MPC
DFA
2
13 Pre-GND
3
AC-GND
C1: 0.22 μF IN3
15
17
C3: 0.1 μF
10
Ripple
C5:
3900 μF
C2: 10 μF
Block Diagram
+B
OUT1 (+)
PW-GND1
RL
OUT1 (−)
OUT2 (+)
PW-GND2
RL
OUT2 (−)
OUT3 (+)
PW-GND3
C6: 1 μF
MPC
DFA
19
C1: 0.22 μF IN4
14
Mute
DFA
24
4 Stby
22 Mute
OUT3 (−)
OUT4 (+)
MPC
R1: 47 kΩ
RL
21
5V
Play
18
16 AC-GND
AC-GND
C4: 1 μF
4.
23
AC-GND
H-SW / Offset Det
Offset Det
PW-GND4
RL
OUT4 (−)
25
1
Some of the functional blocks, circuits or constants labels in the block diagram may have been omitted or simplified
for clarity.
In the following explanation, a "channel" is a circuit which consists of INx, OUTx (+), OUTx (-), and PW-GNDx. (x:1
to 4)
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5.
5.1
Pin Configuration and Function Descriptions
Pin Configuration (top view)
H-SW/OffsetDet
PW-GND4
OUT4(-)
MUTE
OUT4(+)
VCC1
OUT3(-)
PW-GND3
OUT3(+)
AC-GND
IN3
IN4
Pre-GND
IN2
IN1
Ripple
OUT1(+)
PW-GND1
OUT1(-)
VCC2
OUT2(+)
Stby
OUT2(-)
PW-GND2
Offset Det
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5.2
Pin Function Descriptions
Pin
Symbol
I/O (Note1)
Description
1
Offset Det
Vod-OUT
Output offset voltage detector output
2
PW-GND2
―
Ground for OUT2
3
OUT2(-)
OUT
OUT2(-) output
4
Stby
VST-IN
Stand-by voltage input
5
OUT2(+)
OUT
OUT2(+) output
6
VCC2
VCC-IN
Supply voltage 2
7
OUT1(-)
OUT
OUT1(-) output
8
PW-GND1
―
Ground for OUT1
9
OUT1(+)
OUT
OUT1(+) output
10
Ripple
―
Ripple voltage
11
IN1
IN
OUT1 input
12
IN2
IN
OUT2 input
13
Pre-GND
―
Signal ground
14
IN4
IN
OUT4 input
15
IN3
IN
OUT3 input
16
AC-GND
―
Common reference voltage for all input
17
OUT3(+)
OUT
OUT3(+) output
18
PW-GND3
―
Ground for OUT3
19
OUT3(-)
OUT
OUT3(-) output
20
VCC1
VCC-IN
Supply voltage 1
21
OUT4(+)
OUT
OUT4(+) output
22
MUTE
VmuteIN
Mute voltage input
23
OUT4(-)
OUT
OUT4(-) output
24
PW-GND4
―
Ground for OUT4
25
H-SW/OffsetDet
HSW/Vod-OUT
High-side switch / Offset detector output
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VCC2
20
VCC1
11
C1: 0.22 μF IN1
9
DFA
MPC
8
7
AC-GND
C1: 0.22 μF IN2
12
5
DFA
MPC
2
13 Pre-GND
3
AC-GND
C1: 0.22 μF IN3
15
17
+B
C3: 0.1 μF
10
Ripple
C5:
3900 μF
Functional Description
C2: 10 μF
6.
OUT1 (+)
PW-GND1
RL
OUT1 (−)
OUT2 (+)
PW-GND2
RL
OUT2 (−)
OUT3 (+)
PW-GND3
C6: 1 μF
DFA
MPC
16 AC-GND
19
AC-GND
C1: 0.22 μF IN4
14
24
4 Stby
C4: 1 μF
Mute
OUT3 (−)
OUT4 (+)
MPC
R1: 47 kΩ
RL
21
5V
Play
18
22 Mute
23
AC-GND
H-SW / Offset Det
Offset Det
PW-GND4
RL
OUT4 (−)
25
1
Effect (Note1)
Component
Recommended
Name
Value
C1
0.22 μF
INx
(x:1 to 4)
C2
10 μF
C3
Pin
Purpose
Lower than Recommended Value
Higher than Recommended Value
To eliminate DC
Cut-off frequency becomes higher
Cut-off frequency becomes lower
Ripple
To reduce ripple
Turn on/off time shorter
Turn on/off time longer
0.1 μF
VCC1,
VCC2
To provide sufficient
oscillation margin
Reduces noise and provides sufficient oscillation margin
C6
1 μF
AC-GND
Common reference
voltage for all input
Pop noise is suppressed when C1: C6 = 1:4. (Note2)
C5
3900 μF
VCC1,
VCC2
Ripple filter
Power supply ripple filtering
R1 / C4
47 kΩ / 1 μF
Mute
Mute ON/OFF
Smooth switching
Pop noise becomes larger
Switching time becomes longer
Note1: When the unrecommended value is used, please examine it enough by system evaluation.
Note2: Since “AC-GND” pin is a common reference voltage for all input, this product needs to set the ratio of an input
capacitance (C1) and the AC-GND capacitance (C6) to 1:4
Note3: Use the low leak current capacitor for C1 and C6.
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7.
Standby Function (Pin 4)
The power supply can be turned on or off via
pin 4 (Stby). The threshold voltage of pin 4 is
below table. The power supply current is about
0.01 μA (typ.) in the standby state.
Power
ON
4
OFF
to Bias
Standby Control Voltage (VSB): Pin 4
Stby
Power
VSB (V)
ON
OFF
0 to 0.9
OFF
ON
2.2 to VCC
Figure 1 Internal circuit for standby
Benefits of the Standby Switch
(1)
(2)
VCC can be directly turned on or off by a microcontroller, eliminating the need for a switching relay.
Since the control current is minuscule, a low-current-rated switching relay can be used.
Relay
High-current-rated switch
Battery
VCC
Battery
From
microcontroller
VCC
– Conventional Method –
Low-current-rated switch
Battery
Stby
From microcontroller
Battery
VCC
Stby
VCC
– Using the Standby Switch –
Figure 2 Standby Switch
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Mute Function (pin 22)
The audio mute function is enabled by setting pin 22 Low. R1 and C4 determine the time constant of the
mute function. The time constant affects pop noise generated when power or the mute function is turned on
or off; thus, it must be determined on a per-application basis. (Refer to Figures 3 and 4.)
The value of the external pull-up resistor is determined, based on pop noise value.
For example:
when the control voltage is changed from 5 V to 3.3 V, the pull-up resistor should be: 3.3V/5V×47 kΩ=31 kΩ
when the control voltage is changed from 5 V to 8.5 V, the pull-up resistor should be: 8.5V/5V×47 kΩ=80 kΩ
ATT – VMUTE
Mute attenuation ATT (dB)
8.
5V
R1
22
C4
1 kΩ
Mute
ON/OFF
control
Pin 22 Control voltage: VMUTE (V)
Figure 3
Mute Function
Figure 4 Mute Attenuation
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9.
Auto Muting Functions
The TB2941HQ has two automatic mute function.
a) Low Vcc Mute
b) Stand-by Off Mute.
9.1
Low Vcc Mute
When the supply voltage became lower than 5.5V (Typ.), The TB2941HQ operates the mute circuit
automatically. This function prevents the large audible transient noise which is generated by low Vcc
9.2
Standby-Off Mute
The TB2941HQ operates the mute circuit during the standby-off transition. When the ripple voltage
reached Vcc/5, the standby-off mute is terminated. The external mute has to be ON till the internal
mute-OFF.
Ripple terminal voltage
Standby OFF
Ripple voltage
Vcc/5 →
t
Standby Off transition
(Mute-ON)
Tmute <500 ms Vcc = 13.2 V
Normal operation (mute-OFF)
Figure 5 standby-Off Mute
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10. High-side Switch (Pin 25)
The high-side switch can be used for many application circuits related to Power-ON.
This function is enabled by mute voltage (Pin 22) less than 6 V.
Vcc
Q1
25
RLsw
Figure 6 High-side Switch
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11. Output DC Offset Detection
This function detects the offset voltage between OUT(+) and OUT(-). The detection result is gotten by pin1
or pin25. When the offset voltage appeared by the external parts accident, for example the leak of coupling
capacitor, this function can contribute to a part of safety system to prevent the speaker damage.
The example flowchart: The safety system to prevent damaging to speakers by abnormal offset.
(a) Offset
detection
(b) Judgment
Normal / Abnormal
(c) To reduce the speaker stress
Standby-ON, Mute-ON etc.
The result of detection does not judge the abnormal offset or not. This function detects only the offset
voltage which is decided by specification.
11.1
Offset Circuit
a) Regarding offset detector of Pin25.
The result of output offset voltage detection of Pin25 is gotten by the internal high-side switch which
synchronizes with offset voltage. This function is enabled by mute terminal voltage more than 7V.
b) Regarding offset detector of Pin1
The result of output offset voltage detection of Pin1 is gotten by the internal open collector transistor
which synchronizes with offset voltage. This function is always available. If this pin does not be used,
connect to GND or open.
Figure 8 shows the detected result and audio output waveform.
Rs1 generates the positive offset voltage.
Rs2 generates the negative offset voltage.
Vref
Power Amp IC
Leak or short
Vref
V1
1
Vin(dc)
The specification defines the Offset voltage as "OUT(+) - OUT(-)"
+
RS1
E. vol
Vos-det(on)
RS2
Vout(dc)
−
25
Vout(dc) > Vin(dc)
V25
Leak or short
Figure 7 Abnormal output offset voltage
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Abnormal offset voltage
+Vos-det(on)
Output waveform
OUT(+) to OUT(-)
t
0
-Vos-det(on)
V1/V25
Detection
result
0
Term of abnormal offset voltage
Figure 8
The detected result and audio output waveform
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12. Low voltage operation
The TB2941HQ's amplifier circuit is made in MPC/DFA technology. This technology prevents the audible
pop noise and sound cutting due to low Vcc voltage.
12.1
Description
When the headroom voltage is suppressed by the low Vcc, the TB2941HQ switches outputs voltage from
Vcc/2 to Vcc/4 and reduces the audible pop noise and the sound cutting.
The TB2941HQ can reduce the distortion which is generated by low Vcc, because this amplifier circuit
keeps the voltage gain of BLT outputs. In other words, if one side output of BTL has the voltage margin, its
output can make up for clipped waveform of other side output.
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13. Protection Functions
This product has internal protection circuits such as thermal shut down, over-voltage, out to VCC, out to
GND, and out to out short circuit protections.
(1)
Thermal shut down
It operates when junction temperature exceeds 150°C (typ.).
When it operates, it is protected in the following order.
1.
2.
3.
An Attenuation of an output starts first and the amount of attenuation also increases according
to a temperature rising,
All outputs become in a mute state, when temperature continues rising in spite of output
attenuation.
Shutdown function starts, when a temperature rise continues though all outputs are in a mute
state.
In any case if temperature falls, it will return automatically.
(2)
Over-voltage
It operates when voltage exceeding operating range is supplied to VCC pin. If voltage falls, it will
return automatically. When it operates, all outputs bias and high-side switch are turned off and all
outputs are intercepted. Threshold voltage is 23 V (Typ.)
(3)
Short to VCC, Short to GND, Output to output short
It operates when each output pin is in irregular connection and the load line goes over the SOA of
power transistor (DMOS). When it operates, all outputs bias circuits are turned off and all outputs are
intercepted. If irregular connection is canceled, it will return automatically.
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14. Absolute Maximum Ratings
(Ta = 25°C unless otherwise specified)
Characteristics
Condition
Symbol
Rating
Unit
Max 0.2 s
VCC (surge)
50
V
supply voltage (DC)
VCC (DC)
25
V
supply voltage (operation)
VCC (opr)
18
V
supply voltage (surge)
output current (peak)
IO (peak)
9
A
PD
125
W
Operating temperature range
Topr
-40 to 85
°C
Storage temperature
Tstg
-55 to 150
°C
power dissipation
(Note)
Note: Package thermal resistance Rth(j-t) = 1°C/W (typ.) (Ta = 25°C, with infinite heat sink)
The absolute maximum ratings of a semiconductor device are a set of specified parameter values, which must not
be exceeded during operation, even for an instant.
If any of these rating would be exceeded during operation, the device electrical characteristics may be irreparably
altered and the reliability and lifetime of the device can no longer be guaranteed. Moreover, these operations with
exceeded ratings may cause break down, damage, and/or degradation to any other equipment. Applications using
the device should be designed such that each maximum rating will never be exceeded in any operating conditions.
Before using, creating, and/or producing designs, refer to and comply with the precautions and conditions set forth
in this document.
14.1 Power Dissipation
PD (max) – Ta
120
(W)
(1) Infinite heat sink
Rth(j-t) = 1°C/W
Power Dissipation PD (max)
100
(2) Heat sink (Rth(HS) = 3.5°C/W)
Rth(j-t) + Rth(HS) = 4.5°C/W
(3) No heat sink
80
Rth(j-a) = 39°C/W
(1)
60
40
20
(2)
(3)
0
0
25
50
75
100
125
150
Ambient Temperature Ta (°C)
15. Operating Ranges
Characteristics
Supply voltage
Symbol
VCC
Condition
Min
Typ.
Max
Unit
RL = 4 Ω
6
---
18
V
RL = 2 Ω
6
---
16
V
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16. Electrical Characteristics
16.1 Amplifier, Common part
Characteristics
Quiescent supply current
Output power
(VCC = 13.2 V, f = 1 kHz, RL = 4 Ω, Ta = 25°C unless
Symbol
ICCQ
Channel-to-channel voltage
gain
Max
Unit
100
180
300
mA
―
49
―
POUT(max) (2)
VCC = 13.7 V, max POWER
―
40
―
THD = 10%
23
24
―
VCC = 13.7 V, max POWER
―
73
―
POUT (2)
THD = 10%
―
45
―
THD (1)
POUT = 4 W
―
0.006
0.07
THD (2)
POUT = 4 W, RL = 2 Ω
―
0.015
―
GV (1)
VOUT = 0.775 Vrms
25
26
27
dB
∆GV
VOUT = 0.775 Vrms
−1.0
0
1.0
dB
―
65
80
―
―
―
POUT(max) (3)
VNO (1)
Output noise voltage
Typ.
VCC = 15.2 V, max POWER
Total harmonic distortion
Voltage gain
VIN = 0 V
Min
POUT(max) (1)
POUT (1)
Output power(RL = 2 Ω)
Test Condition
otherwise specified)
Rg = 0 Ω, DIN AUDIO
―
―
W
W
%
µV
Ripple rejection ratio
R.R.
fRIP = 100 Hz, Rg = 620 Ω (Note 1)
VRIP = 1 Vrms
50
65
―
dB
Crosstalk
C.T.
Po = 4 W, Rg = 620 Ω,
―
80
―
dB
―
−90
0
90
mV
―
Output offset voltage
VOFFSET
―
90
―
kΩ
VSB = 0 V
―
0.01
1
µA
MUTE: ON
VOUT = 7.75 Vrms → Mute: OFF
85
100
―
dB
VSBH
POWER : ON
2.2
―
VCC
VSBL
POWER : OFF
0
―
0.9
VMH
MUTE : OFF
2.2
―
VCC
VML
MUTE : ON
0
―
0.9
Input resistance
RIN
Standby current
ISTBY
Mute attenuation
ATTMUTE
Standby control voltage
Mute control voltage
V
V
Note 1: fRIP : repple frequency
VRIP: Ripple signal voltage (AC fluctuations in the power supply)
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16.2 Pin 25 High-side switches, Output DC offset detector
(VCC = 13.2 V, f = 1 kHz, RL = 4 Ω, IO-HSW = 400 mA, Ta = 25°C unless
Characteristics
HSW maximum current
Symbol
IO-HSW (MAX)
Test Condition
VO-HSW = 12.6 V
―
∆VO
HSW I/O voltage ratio
otherwise specified)
Min
Typ.
Max
Unit
400
―
―
mA
―
0.2
0.6
V
Function switching control
voltage
VM (HSW)
enable HSW
2.2
―
6.0
VM (DET)
enable Vos Det
7.0
―
VCC
DC offset threshold voltage
VOS-DET(ON)
±2.5
±3
±3.5
VM = 8V, Vo(+) – Vo(-)
V
V
RLSW
High side switch test circuit 1
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16.3 Pin 1 Output DC offset detector
(VCC = 13.2 V, f = 1 kHz, RL = 4 Ω, Rpull-up = 10 kΩ, Vsb = Vref = 5 V Ta = 25°C unless
Test
Test Condition
Min
Characteristics
Symbol
circuit
DC offset threshold voltage
Vos1-det(on)
(5)
Vsb = 5 V, Vo(+) - Vo(-)
P1-sat
(5)
Rpull-up = 10 kΩ, Vref = 5.0 V
Active low
Pin 1 Saturation voltage
±2.5
―
otherwise specified)
Typ.
Max
Unit
±3.0
±3.5
V
100
500
mV
Test circuit (5)
Vref = 5 V
Rpull-up = 10 kΩ
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6
VCC2
20
VCC1
11
C1: 0.22 μF IN1
9
MPC
DFA
8
7
AC-GND
C1: 0.22 μF IN2
12
5
MPC
DFA
2
13 Pre-GND
3
AC-GND
C1: 0.22 μF IN3
15
17
C3: 0.1 μF
10
Ripple
C5:
3900 μF
C2: 10 μF
17. Test Circuit
+B
OUT1 (+)
PW-GND1
RL: 4 Ω
OUT1 (−)
OUT2 (+)
PW-GND2
RL: 4 Ω
OUT2 (−)
OUT3 (+)
PW-GND3
C6: 1 μF
MPC
DFA
16 AC-GND
19
AC-GND
C1: 0.22 μF IN4
14
OUT4 (+)
MPC
DFA
24
4 Stby
R1: 47 kΩ
C4: 1 μF
Mute
22 Mute
OUT3 (−)
21
5V
Play
RL: 4 Ω
18
23
AC-GND
H-SW / Offset Det
25
Offset Det
1
PW-GND4
RL: 4 Ω
OUT4 (−)
Components in the test circuit are only used to determine the device characteristics.
It is not guaranteed that the system will work properly with these components.
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18. Characteristics Curve data
THD – POUT
Total harmonic distortion THD (%)
Total harmonic distortion THD (%)
THD – POUT
Output power POUT
Output power POUT
(W)
THD – f
(W)
Voltage gain GV (dB)
Total harmonic distortion THD (%)
GV – f
Frequency f
(kHz)
Frequency f
19
(kHz)
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ATTMUTE – f
Mute attenuation ATTMUTE
Ripple rejection rate R.R.
(dB)
(dB)
R.R. – f
Frequency f
(kHz)
Frequency f
C.T. – f (OUT2)
Cross talk
Cross talk
C.T. (dB)
C.T. (dB)
C.T. – f (OUT1)
(kHz)
Frequency f
(kHz)
Frequency f
C.T. – f (OUT4)
Cross talk
Cross talk
C.T. (dB)
C.T. (dB)
C.T. – f (OUT3)
(kHz)
Frequency f
(kHz)
Frequency f
20
(kHz)
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ICCQ –VCC
Quiescent Current ICCQ
Output noise voltage VNO (μV)
(mA)
VNO – Rg
Input signal resistor Rg (kΩ)
Supply voltage VCC
(V)
PD – POUT
Output power POUT
Power dissipation PD
(W)
(W)
POUT – VIN
Input voltage VIN(rms)
(V)
Output power POUT
(W)
HSW output voltage
VO-HSW (V)
VO-HSW – IO-HSW
HSW output current
IO-HSW (A)
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19. Package Dimensions
* From center to parting line.
Weight: 7.7 g (typ.)
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20. Attention in Use
• Use an appropriate power supply fuse to ensure that a large current does not continuously flow in case of
over current and/or IC failure. The IC will fully break down when used under conditions that exceed its
absolute maximum ratings, when the wiring is routed improperly or when an abnormal pulse noise occurs
from the wiring or load, causing a large current to continuously flow and the breakdown can lead smoke or
ignition. To minimize the effects of the flow of a large current in case of breakdown, appropriate settings,
such as fuse capacity, fusing time and insertion circuit location, are required.
• If your design includes an inductive load such as a motor coil, incorporate a protection circuit into the design
to prevent device malfunction or breakdown caused by the current resulting from the inrush current at
power ON or the negative current resulting from the back electromotive force at power OFF. For details on
how to connect a protection circuit such as a current limiting resistor or back electromotive force adsorption
diode, refer to individual IC datasheets or the IC databook. IC breakdown may cause injury, smoke or
ignition.
• Use a stable power supply with ICs with built-in protection functions. If the power supply is unstable, the
protection function may not operate, causing IC breakdown. IC breakdown may cause injury, smoke or
ignition.
• Carefully select external components (such as inputs and negative feedback capacitors) and load
components (such as speakers), for example, power amp and regulator. If there is a large amount of
leakage current such as input or negative feedback condenser, the IC output DC voltage will increase. If
this output voltage is connected to a speaker with low input withstand voltage, overcurrent or IC failure can
cause smoke or ignition. (The over current can cause smoke or ignition from the IC itself.) In particular,
please pay attention when using a Bridge Tied Load (BTL) connection type IC that inputs output DC voltage
to a speaker directly.
• Over current Protection Circuit
Over current protection circuits (referred to as current limiter circuits) do not necessarily protect ICs under
all circumstances. If the Over current protection circuits operate against the over current, clear the over
current status immediately. Depending on the method of use and usage conditions, such as exceeding
absolute maximum ratings can cause the over current protection circuit to not operate properly or IC
breakdown before operation. In addition, depending on the method of use and usage conditions, if over
current continues to flow for a long time after operation, the IC may generate heat resulting in breakdown.
• Thermal Shutdown Circuit
Thermal shutdown circuits do not necessarily protect ICs under all circumstances. If the Thermal shutdown
circuits operate against the over temperature, clear the heat generation status immediately. Depending on
the method of use and usage conditions, such as exceeding absolute maximum ratings can cause the
thermal shutdown circuit to not operate properly or IC breakdown before operation.
• Heat Radiation Design
When using an IC with large current flow such as power amp, regulator or driver, please design the device
so that heat is appropriately radiated, not to exceed the specified junction temperature (Tj) at any time and
condition. These ICs generate heat even during normal use. An inadequate IC heat radiation design can
lead to decrease in IC life, deterioration of IC characteristics or IC breakdown. In addition, please design the
device taking into considerate the effect of IC heat radiation with peripheral components.
• Installation to Heat Sink
Please install the power IC to the heat sink not to apply excessive mechanical stress to the IC. Excessive
mechanical stress can lead to package cracks, resulting in a reduction in reliability or breakdown of internal
IC chip. In addition, depending on the IC, the use of silicon rubber may be prohibited. Check whether the
use of silicon rubber is prohibited for the IC you intend to use, or not. For details of power IC heat radiation
design and heat sink installation, refer to individual technical datasheets or IC databooks.
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TB2941HQ
RESTRICTIONS ON PRODUCT USE
• Toshiba Corporation, and its subsidiaries and affiliates (collectively "TOSHIBA"), reserve the right to make changes to the information
in this document, and related hardware, software and systems (collectively "Product") without notice.
• This document and any information herein may not be reproduced without prior written permission from TOSHIBA. Even with
TOSHIBA's written permission, reproduction is permissible only if reproduction is without alteration/omission.
• Though TOSHIBA works continually to improve Product's quality and reliability, Product can malfunction or fail. Customers are
responsible for complying with safety standards and for providing adequate designs and safeguards for their hardware, software and
systems which minimize risk and avoid situations in which a malfunction or failure of Product could cause loss of human life, bodily
injury or damage to property, including data loss or corruption. Before customers use the Product, create designs including the Product,
or incorporate the Product into their own applications, customers must also refer to and comply with (a) the latest versions of all
relevant TOSHIBA information, including without limitation, this document, the specifications, the data sheets and application notes for
Product and the precautions and conditions set forth in the "TOSHIBA Semiconductor Reliability Handbook" and (b) the instructions for
the application with which the Product will be used with or for. Customers are solely responsible for all aspects of their own product
design or applications, including but not limited to (a) determining the appropriateness of the use of this Product in such design or
applications; (b) evaluating and determining the applicability of any information contained in this document, or in charts, diagrams,
programs, algorithms, sample application circuits, or any other referenced documents; and (c) validating all operating parameters for
such designs and applications. TOSHIBA ASSUMES NO LIABILITY FOR CUSTOMERS' PRODUCT DESIGN OR APPLICATIONS.
• PRODUCT IS NEITHER INTENDED NOR WARRANTED FOR USE IN EQUIPMENTS OR SYSTEMS THAT REQUIRE
EXTRAORDINARILY HIGH LEVELS OF QUALITY AND/OR RELIABILITY, AND/OR A MALFUNCTION OR FAILURE OF WHICH
MAY CAUSE LOSS OF HUMAN LIFE, BODILY INJURY, SERIOUS PROPERTY DAMAGE AND/OR SERIOUS PUBLIC IMPACT
("UNINTENDED USE"). Except for specific applications as expressly stated in this document, Unintended Use includes, without
limitation, equipment used in nuclear facilities, equipment used in the aerospace industry, medical equipment, equipment used for
automobiles, trains, ships and other transportation, traffic signaling equipment, equipment used to control combustions or explosions,
safety devices, elevators and escalators, devices related to electric power, and equipment used in finance-related fields. IF YOU USE
PRODUCT FOR UNINTENDED USE, TOSHIBA ASSUMES NO LIABILITY FOR PRODUCT. For details, please contact your
TOSHIBA sales representative.
• Do not disassemble, analyze, reverse-engineer, alter, modify, translate or copy Product, whether in whole or in part.
• Product shall not be used for or incorporated into any products or systems whose manufacture, use, or sale is prohibited under any
applicable laws or regulations.
• The information contained herein is presented only as guidance for Product use. No responsibility is assumed by TOSHIBA for any
infringement of patents or any other intellectual property rights of third parties that may result from the use of Product. No license to
any intellectual property right is granted by this document, whether express or implied, by estoppel or otherwise.
• ABSENT A WRITTEN SIGNED AGREEMENT, EXCEPT AS PROVIDED IN THE RELEVANT TERMS AND CONDITIONS OF SALE
FOR PRODUCT, AND TO THE MAXIMUM EXTENT ALLOWABLE BY LAW, TOSHIBA (1) ASSUMES NO LIABILITY
WHATSOEVER, INCLUDING WITHOUT LIMITATION, INDIRECT, CONSEQUENTIAL, SPECIAL, OR INCIDENTAL DAMAGES OR
LOSS, INCLUDING WITHOUT LIMITATION, LOSS OF PROFITS, LOSS OF OPPORTUNITIES, BUSINESS INTERRUPTION AND
LOSS OF DATA, AND (2) DISCLAIMS ANY AND ALL EXPRESS OR IMPLIED WARRANTIES AND CONDITIONS RELATED TO
SALE, USE OF PRODUCT, OR INFORMATION, INCLUDING WARRANTIES OR CONDITIONS OF MERCHANTABILITY, FITNESS
FOR A PARTICULAR PURPOSE, ACCURACY OF INFORMATION, OR NONINFRINGEMENT.
• Do not use or otherwise make available Product or related software or technology for any military purposes, including without limitation,
for the design, development, use, stockpiling or manufacturing of nuclear, chemical, or biological weapons or missile technology
products (mass destruction weapons). Product and related software and technology may be controlled under the applicable export
laws and regulations including, without limitation, the Japanese Foreign Exchange and Foreign Trade Law and the U.S. Export
Administration Regulations. Export and re-export of Product or related software or technology are strictly prohibited except in
compliance with all applicable export laws and regulations.
• Please contact your TOSHIBA sales representative for details as to environmental matters such as the RoHS compatibility of Product.
Please use Product in compliance with all applicable laws and regulations that regulate the inclusion or use of controlled substances,
including without limitation, the EU RoHS Directive. TOSHIBA ASSUMES NO LIABILITY FOR DAMAGES OR LOSSES
OCCURRING AS A RESULT OF NONCOMPLIANCE WITH APPLICABLE LAWS AND REGULATIONS.
24
2015-07-22
Mouser Electronics
Authorized Distributor
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