Ground Referenced Stereo Headphone Amplifier V+ GENERAL ... · =10kΩ - 0.007 0.05 % Channel...
Transcript of Ground Referenced Stereo Headphone Amplifier V+ GENERAL ... · =10kΩ - 0.007 0.05 % Channel...
NJU72040
– 1 –
Ver. 1.3E
Ground Referenced Stereo Headphone Amplifier
GENERAL DESCRIPTION
The NJU72040 is an audio headphone amplifier .
Ground-referenced outputs eliminate output coupling
capacitor. The pop noise suppression circuit removes a pop
noise at the power-on and power-off.
It is suitable for audio headphone amplifer application
APPLICATIONS
Audio applications which have audio headphone interface
FEATURES
Operating Voltage +2.7 to +3.6V
Operating Current IDD=10.5mA typ.
at V+=3.3V, No load, No Signal
Output Coupling Capacitor-less
Pop Noise Suppression Circuit
Gain Select
C-MOS Technology
Package Outline SSOP14
BLOCK DIAGRAM
PACKAGE OUTLINE
NJU72040V
INL-
INL+
OUTL
V+
CP
CN
GND
REF
V-
MUTE
GAIN
INR-
INR+
OUTR
32Ω
Headphone
32Ω
Headphone
V+
inverted
phase
inverted
phase
V-Regulator
Bias
Gain Select
V+ V+
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegV+
NJU72040
– 2 –
PIN CONFIGURATION
No. Symbol Function No. Symbol Function
1 INL- Lch Inverted Input 8 REF Reference Voltage Input
2 INL+ Lch Noninverted Input 9 V- V- Power Supply
3 OUTL Lch Output 10 MUTE MUTE / Pop Noise Suppression
4 V+ V+ Power Supply 11 GND Ground
5 CP Flying Capacitor Positive Terminal 12 OUTR Rch Output
6 CN Flying Capacitor Negative Terminal 13 INR+ Rch Inverted Input
7 GAIN Gain Select 14 INR- Rch Noninverted Input
NJU72040
INL-
INL+ INR+
INR-
OUTL OUTR
V+ GND
MUTE CP
CN V-
REF GAIN
1
7 8
14
NJU72040
– 3 –
ABSOLUTE MAXIMUM RATING (Ta=25C)
PARAMETER SYMBOL RATING UNIT
Supply Voltage V+ +4 V
Power Dissipation PD SSOP14 : 550(Note1) mW
Maximum Input Voltage VIM V+
+0.3 V
Operating Temperature Range Topr -40 ~ +85 C
Storage Temperature Range Tstg -40 ~ +125 C
(Note1) EIA/JEDEC STANDARD Test board (76.2x114.3x1.6mm, 2layer, FR-4) mounting
RECOMMENDED OPERATING CONDITIONS (Ta=25C unless otherwise specified)
PARAMETER SYMBOL TEST CONDITION MIN. TYP. MAX. UNIT
Operating Voltage V+ 2.7 3.3 3.6 V
ELECTRICAL CHARACTERISTICS (Ta=25C, V
+=3.3V, f=1kHz, Vin=0.1Vrms[differential input], Gv=6.4dB, MUTE=OFF, RL=32Ω unless otherwise specified)
PARAMETER SYMBOL TEST CONDITION MIN. TYP. MAX. UNIT
Operating Current IDD No signal, No load - 10.5 15.5 mA
Input Resistance1 Rin1 INL-, INR- 49 61 73 kΩ
Input Resistance2 Rin2 INL+, INR+ 103 129 155 kΩ
Voltage Gain1 GV1 Gain Terminal=Low 5.4 6.4 7.4 dB
Voltage Gain2 GV2 Gain Terminal=High 11.4 12.4 13.4 dB
Voltage Gain3 GV3 Gain Terminal=Low, RL=10kΩ 6.6 7.1 7.6 dB
Voltage Gain4 GV4 Gain Terminal=High, RL=10kΩ 12.6 13.1 13.6 dB
Maximum Output Power1 POMAX1 THD=3%, RL=32Ω
Input=Lch or Rch - 80 - mW
Maximum Output Power2 POMAX2 THD=3%, RL =32Ω
Input=Lch and Rch - 55 - mW
Maximum Output Voltage Level VOMAX THD=1%, RL=10kΩ - 2.2 - Vrms
Mute Level VMUTE Rg=0Ω , Mute=ON - -90 -80 dB
Equivalent Input Noise Voltage VNI Rg=0Ω , BW:400Hz-22kHz - -100 -95 dBV
Total Harmonic Distortion1 THD1 BW:400Hz-22kHz, RL=32Ω - 0.08 0.3 %
Total Harmonic Distortion2 THD2 BW:400Hz-22kHz, RL=10kΩ - 0.007 0.05 %
Channel Separation1 CS1 Rg=600Ω , (*1) 65 75 - dB
Channel Separation2 CS2 Rg=600Ω , f=10kHz, (*1) 55 65 - dB
Output Offset Voltage VOS Rg=0Ω , Gv=12.4Db, No load - 1 5 mV
(*1)OUTL(measured terminal): 20log(OUTR/OUTL) , OUTR(measured terminal): 20log(OUTL/OUTR) CONTROL CHARACTERISTICS (Ta=25C, V
+=3.3V, Gv=6.4dB, MUTE=OFF, RL=32Ω unless otherwise specified)
PARAMETER SYMBOL TEST CONDITION MIN. TYP. MAX. UNIT
Mute terminal High MuteH Mute=OFF 0.8 V+ - V
+ V
Mute terminal Low MuteL Mute=ON 0 - 0.2 V+ V
Gain terminal High GainH Gv=12.4dB 0.8 V+ - V
+ V
Gain terminal Low GainL Gv=6.4dB 0 - 0.2 V+ V
NJU72040
– 4 –
TEST CIRCUIT (IDD)
(*2): Monolithic Ceramic Capacitors
TEST CIRCUIT (GV1, GV2, GV3, GV4, POMAX1, VOMAX) (*2): Monolithic Ceramic Capacitors
(*2)
(*2)
INL-
INL+
OUTL
V+
CP
CN
GND
MUTE
GAIN
INR-
INR+
OUTR
REF
V-
A
V+
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C4=1uF
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
INL-
INL+
OUTL
V+
CP
CN
GND
MUTE
GAIN
INR-
INR+
OUTRGv1,2,POMAX1
RL=32Ω
Gv3,4,VOMAX
RL=10kΩ
V+
inverted phase
REF
V-
V
Gv1,2,POMAX1
RL=32Ω
Gv3,4,VOMAX
RL=10kΩ
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C4=1uF
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
(*2)
(*2)
NJU72040
– 5 –
TEST CIRCUIT (POMAX2) (*2): Monolithic Ceramic Capacitors
TEST CIRCUIT (VMUTE) (*2): Monolithic Ceramic Capacitors
(*2)
(*2)
INL-
INL+
OUTL
V+
CP
CN
GND
MUTE
GAIN
INR-
INR+
OUTR
RL=32Ω
V+
inverted phase
REF
V-
V
inverted phase
RL=32Ω
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C4=1uF
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
INL-
INL+
OUTL
V+
CP
CN
GND
MUTE
GAIN
INR-
INR+
OUTR
inverted phase
REF
V-
VRL=32Ω RL=32Ω
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C4=1uF
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
(*2)
(*2)
NJU72040
– 6 –
TEST CIRCUIT (VNI) VNI=(measurement)-Gv1 (*2): Monolithic Ceramic Capacitors TEST CIRCUIT (THD1, THD2) (*2): Monolithic Ceramic Capacitors (*3): Connect a low-pass filter circuit with the corner frequency of more than 20kHz in front of an analyzer for rejecting the switching noise generated from NJU72040. Otherwise, the characteristic result may change because of the switching noise.
INL-
INL+
OUTL
V+
CP
CN
GND
MUTE
GAIN
INR-
INR+
OUTR
RL=32Ω
V+
REF
V-
V VRL=32Ω
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C4=1uF
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
(*2)
(*2)
INL-
INL+
OUTL
V+
CP
CN
GND
MUTE
GAIN
INR-
INR+
OUTR
THD1
RL=32Ω
THD2
RL=10kΩV+
inverted phase
REF
V-
V
Filter
Ex)
AudioPrecision
aux-0025
THD1
RL=32Ω
THD2
RL=10kΩ
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C4=1uF
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
(*2)
(*2)
NJU72040
– 7 –
TEST CIRCUIT (CS1, CS2) OUTL (measured terminal) : CS1=CS2=20log(OUTR/OUTL) OUTR (measured terminal) : CS1=CS2=20log(OUTL/OUTR) (*2): Monolithic Ceramic Capacitors
TEST CIRCUIT (VOS) (*2): Monolithic Ceramic Capacitors
INL-
INL+
OUTL
V+
CP
CN
GND
MUTE
GAIN
INR-
INR+
OUTR
RL=32Ω
V+
REF
V-
VRL=32Ω
inverted phase
Rg=600Ω
Rg=600Ω
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C4=1uF
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
INL-
INL+
OUTL
V+
CP
CN
GND
MUTE
GAIN
INR-
INR+
OUTR
V+
REF
V-
V V
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C4=1uF
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
NJU72040
– 8 –
APPLICATION CIRCUIT (Single-end input) (Differential input) (*2): Monolithic Ceramic Capacitors (*3): V- terminal (8pin) shouldn’t be tied to V+ terminal (4pin)
INL-
INL+
OUTL
V+
CP
CN
GND
REF
V-
MUTE
GAIN
INR-
INR+
OUTR
32Ω
Headphone
32Ω
Headphone
V+
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C7=1uF
R2=100kΩ
V+
C4=1uF
V+
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
INL-
INL+
OUTL
V+
CP
CN
GND
REF
V-
MUTE
GAIN
INR-
INR+
OUTR
32Ω
Headphone
32Ω
Headphone
V+
C10=1uF
C8=1uFC2=1uF
C1=1uF
C6=10uF
C7=1uF
R2=100kΩ
V+
C4=1uF
inverted phase inverted phase
V+
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
NJU72040
– 9 –
APPLICATION NOTE The NJU72040 is an audio headphone amplifier that eliminates the need for external dc-blocking output capacitors. The NJU72040 has built-in pop suppression circuitry to eliminate disturbing pop noise during power-on, power-off and mute-control.
1. Operating Principle
The NJU72040 has the built-in differential input operational amplifiers, voltage inverter, pop noise suppression circuitry, gain selectable circuitry and thermal-overload protection circuitry (Fig.1). For single-ended input signals, connect inverted terminal (INL-, INR-) or non-inverted terminal (INL+, INR+) to ground through the capacitor. The voltage gain is selectable. In the differential circuitry, the setting gain is
+6.4dB or +12.4dB for the RL=32. In the single-end input circuitry, the setting gain is +0.4dB or +6.4dB for
the RL=32. The voltage inverter for NJU72040 eliminates the need for external dc-blocking output capacitors. The pop suppression circuitry for NJU72040 eliminates the pop noise during power-on, power-off and mute-control.
Fig.1 The NJU72040 functional block diagram
1.1 External parts
1.1.1 Input coupling capacitors Ci (C1, C2, C8, C10)
The input coupling capacitor (Ci) and the input resistance (Rin=61k typ.) for the inverted terminal
form a high-pass filter with the corner frequency determined in [fc=1/(2x 61k x Ci)]. It is necessary to adjust 1uF or more.
INL-
INL+
OUTL
V+
CP
CN
GND
REF
MUTE
GAIN
INR-
INR+
OUTR
32Ω
Headphone
32Ω
Headphone
V+
inverted phase inverted phase
C1
C2
C4
C6
C7
R2
C8
C10
V+
V+
V-V-
Negative
Voltage
Regulator
Bias
Gain Select
Pop Noise
Suppression
Pop Noise
Suppression
3MΩ
100kΩ
RegulatorV+
NJU72040
– 10 –
1.1.2 Flying capacitor (C4) Use capacitors with a low-ESR (ex. ceramic capacitors) for optimum performance. Design to provide
low impedance for the wiring between CP terminal (5pin), CN terminal (6pin), and the flying capacitor (C4).
Fig.2 The NJU72040 block diagram (5pin, 6pin)
1.1.3 Hold capacitor (C6) Use capacitors with a low-ESR (ex. ceramic capacitors) for optimum performance. Design to provide
low impedance for the wiring between the hold capacitor (C6), V- terminal (9pin) and the GND on the PCB.
Separate the GND pattern connecting to the hold capacitor (C6) from that connecting to the REF terminal (8pin), thus suppressing the influence of switching noise by removing the common impedance of the GND wiring.
Design no short-circuits of V- terminal (9pin) and V+ terminal (4pin) on the PCB pattern.
Fig.3 The NJU72040 block diagram (8pin, 9pin)
1.1.4 Mute terminal pop noise countermeasures (C7, R2)
Mute terminal needs time constant more than R2 x C7=0.1. It is necessary to adjust R2 to 100k or less. Please pay attention to meet the threshold voltage because the Mute terminal’s applied voltage is dropped in case of setting R2 to high.
Fig.4 The NJU72040 block diagram (10pin)
CP(5pin)
CN(6pin)
C4=1uF
C6V-(9pin)
REF(8pin)
3MΩ
MUTE(10pin)R2=100kΩ
C7=1uF
Vcnt
NJU72040
– 11 –
1.2 Control of V+ terminal and Mute terminal 1.2.2 Power-on procedure
1. Turn on the V+. 2. After 5msec from power on, change the control voltage of MUTE terminal (Vcnt) from "Low" to "High". * It is necessary to stabilize an IC for 5msec. By releasing the MUTE function, the output terminal output the signal.
1.2.3 Power-off procedure
1. Change the control voltage of MUTE terminal (Vcnt) from "High" to "Low". By the MUTE function, the output signals are stopped from output terminal. 2. Turn off the V+ after “2RC” sec from MUTE. * It is necessary to stabilize a MUTE condition for “2RC” sec. Ex.) R2=100kΩ, C7=1uF -> 2R2 x C7=200msec
Fig.5 Turn-on / Turn-off timing chart
5msec 2RC=200msec
t
t
t
V+
(4pin)
Vcnt
MUTE
(10pin)
MUTE ON MUTE OFF MUTE ON
NJU72040
– 12 –
40k
V+ V+ V+
V- V-
TERMINAL DESCRIPTION
Terminal SYMBOL FUNCTION EQUIVALENT CIRCUIT VOLTAGE
1 2
13 14
INL- INL+ INR- INR+
AC Input
0V
3 12
OUTL OUTR
AC Output
0V
7 GAIN Gain Select
0V
10 MUTE MUTE/Pop Noise
Suppression
0V
V-
V+
FB
V-
10 5.5k 20k
REF
2k
V+ V+
V-
V+
20k
100k
1k
V+
V-
V+
20k
3M
NJU72040
– 13 –
TERMINAL DESCRIPTION
Terminal SYMBOL FUNCTION EQUIVALENT CIRCUIT VOLTAGE
5 CP Flying Capacitor Positive Terminal
-
6 CN Flying Capacitor Positive Terminal
-
8 REF Reference Voltage
Input
-
V+
V-
V- V-
INL+
INR+
V+
V-
OUTL
OUTR5.5k 10
V-
69k
40k
NJU72040
– 14 –
TYPICAL CHARACTERISTICS
Supply Current vs Temperature
V+=3.3V, RL=NoLoad, MUTE=L
0
5
10
15
20
25
-50 -25 0 25 50 75 100 125
Temperature[oC]
Supply
Curr
ent[m
A]
GAIN=L,H
Supply Current vs Supply Voltage
RL=NoLoad, MUTE=L, GAIN=L
0
5
10
15
20
25
0 0.5 1 1.5 2 2.5 3 3.5 4
Supply Voltage[V]
Supply
Curr
ent[m
A]
Ta=85oC
Ta=-40oC
Ta=25oC
Supply Current vs Supply Voltage
RL=NoLoad, MUTE=H, GAIN=L
0
5
10
15
20
25
0 0.5 1 1.5 2 2.5 3 3.5 4
Supply Voltage[V]
Supply
Curr
ent[m
A]
Ta=85oC
Ta=25oC
Ta=-40oC
Supply Current vs Temperature
V+=3.3V, RL=NoLoad, MUTE=H
0
5
10
15
20
25
-50 -25 0 25 50 75 100 125
Temperature[oC]
Supply
Curr
ent[m
A]
GAIN=L,H
Supply Current vs Supply Voltage
RL=NoLoad, MUTE=L, GAIN=H
0
5
10
15
20
25
0 0.5 1 1.5 2 2.5 3 3.5 4
Supply Voltage[V]
Supply
Curr
ent[m
A]
Ta=85oC
Ta=-40oC
Ta=25oC
Supply Current vs Supply Voltage
RL=NoLoad, MUTE=H, GAIN=H
0
5
10
15
20
25
0 0.5 1 1.5 2 2.5 3 3.5 4
Supply Voltage[V]
Supply
Curr
ent[m
A]
Ta=85oC
Ta=25oC
Ta=-40oC
NJU72040
– 15 –
Equivalent Input Noise vs Temperature
V+=3.3V, RL=32Ω, Rg=0Ω, MUTE=H, GAIN=L, INL+=0Vrms ,
INL-=0Vrms, Measure:OUTL, BW=400Hz - 22kHz
-120
-100
-80
-60
-40
-20
0
-50 -25 0 25 50 75 100 125
Temperature[oC]
Equiv
ale
nt In
put N
ois
e[d
BV
]
VoltageGain vs Frequency
V+=3.3V, RL=32Ω, MUTE=H, INL+=0.1Vrms
INL-=0.1Vrms(inverted), Measure=OUTL
0
5
10
15
20
10 100 1000 10000 100000
Frequency[Hz]
Volta
geG
ain
[dB
]
GAIN=H
Ta=-40,25,85oC
GAIN=L
Ta=-40,25,85oC
MuteLevel vs Frequency
V+=3.3V, RL=10kΩ, MUTE=H, GAIN=L, INL+=0.1Vrms
INL-=0.1Vrms(inverted), Measure=OUTL, Filter=Bandpass
-120
-100
-80
-60
-40
-20
0
10 100 1000 10000 100000
Freauency[Hz]
Mute
Level[d
B]
Ta=-40,25,85oC
VoltageGain vs Frequency
V+=3.3V, RL=10kΩ, MUTE=H, INL+=0.1Vrms
INL-=0.1Vrms(inverted), Measure=OUTL
0
5
10
15
20
10 100 1000 10000 100000
Frequency[Hz]
Volta
geG
ain
[dB
]
GAIN=H
Ta=-40,25,85oC
GAIN=L
Ta=-40,25,85oC
Equivalent Input Noise vs Temperature
V+=3.3V, RL=10kΩ, Rg=0Ω, MUTE=H, GAIN=L, INL+=0Vrms
INL-=0Vrms, Measure:OUTL, BW=400Hz - 22kHz
-120
-100
-80
-60
-40
-20
0
-50 -25 0 25 50 75 100 125
Temperature[oC]E
quiv
ale
nt In
put N
ois
e[d
BV
]
MuteLevel vs Frequency
V+=3.3V, RL=32Ω, MUTE=H, GAIN=L, INL+=0.1Vrms
INL-=0.1Vrms(inverted), Measure=OUTL, Filter=Bandpass
-120
-100
-80
-60
-40
-20
0
10 100 1000 10000 100000
Freauency[Hz]
Mute
Level[d
B]
Ta=-40,25,85oC
NJU72040
– 16 –
PSRR vs Frequency
V+=3.3V, RL=32Ω, MUTE=H, GAIN=L, Vripple=0.1Vrms
INL+=INR+=0Vrms, INL-=INR-=0Vrms, Measure=OUTL,OUTR
Filter=Bandpass
0
20
40
60
80
100
10 100 1000 10000 100000
Freauency[Hz]
PS
RR
[dB
]
Ta=-40oC
Ta=85oC
Ta=25oC
ChannelSeparation vs Frequency
V+=3.3V, RL=32Ω, Rg=600Ω, MUTE=H, GAIN=L
INR+=0.1Vrms, INR-=0.1Vrms(inverted), Measure=OUTL
Filter=Bandpass
0
20
40
60
80
100
10 100 1000 10000 100000
Freauency[Hz]
ChannelS
epara
tion[d
B]
Ta=-40oC
Ta=85oC
Ta=25oC
ChannelSeparation vs Frequency
V+=3.3V, RL=32Ω, Rg=600Ω , MUTE=H, GAIN=L,
INL+=0.1Vrms, INL-=0.1Vrms(inverted), Measure=OUTR
Filter=Bandpass
0
20
40
60
80
100
10 100 1000 10000 100000
Freauency[Hz]
ChannelS
epara
tion[d
B]
Ta=-40oC
Ta=85oC
Ta=25oC
ChannelSeparation vs Frequency
V+=3.3V, RL=10kΩ, Rg=600Ω, MUTE=H, GAIN=L,
INL+=0.1Vrms, INL-=0.1Vrms(inverted), Measure=OUTR
Filter=Bandpass
0
20
40
60
80
100
10 100 1000 10000 100000
Freauency[Hz]C
hannelS
epara
tion[d
B]
Ta=-40oCTa=85oC
Ta=25oC
ChannelSeparation vs Frequency
V+=3.3V, RL=10kΩ, Rg=600Ω, MUTE=H, GAIN=L
INR+=0.1Vrms, INR-=0.1Vrms(inverted), Measure=OUTL
Filter=Bandpass
0
20
40
60
80
100
10 100 1000 10000 100000
Freauency[Hz]
ChannelS
epara
tion[d
B]
Ta=-40oC
Ta=85oC
Ta=25oC
PSRR vs Frequency
V+=3.3V, RL=10kΩ, MUTE=H, GAIN=L, Vripple=0.1Vrms
INL+=INR+=0Vrms, INL-=INR-=0Vrms, Measure=OUTL,OUTR
Filter=Bandpass
0
20
40
60
80
100
10 100 1000 10000 100000
Freauency[Hz]
PS
RR
[dB
]
Ta=-40oC
Ta=85oC
Ta=25oC
NJU72040
– 17 –
CMRR vs Frequency
V+=3.3V, RL=32Ω, MUTE=H, GAIN=L, INL+(INR+)=0.1Vrms
INL-(INR-)=0.1Vrms, Measure=OUTL(OUTR), BW=Bandpass
0
20
40
60
80
100
10 100 1000 10000 100000
Freauency[Hz]
CM
RR
[dB
]
OUTL
Ta=-40,25,85oC
OUTR
Ta=-40,25,85oC
Thermal Shut Down(SupplyCurrent)
V+=3.3V , RL=32Ω , MUTE=H , GAIN=L
0
2
4
6
8
10
12
14
120 130 140 150 160
Temperature[oC]
Supply
Curr
ent [m
A]
120oC
->160oC160oC
->120oC
Power Dissipation vs Output Power
V+=3.3V, RL=32Ω, MUTE=H, GAIN=L, Ta=25oC
f=1kHz, Measure=OUTL, BW=400Hz to 22kHz
0
50
100
150
200
250
300
0 20 40 60 80 100
Output Pow er [mW/ch]
Pow
er
Dis
sip
atio
n [m
W]
Input=Lch
Input=Lch,Rch
THD+N=3%
CMRR vs Frequency
V+=3.3V, RL=10kΩ , MUTE=H , GAIN=L,INL+(INR+)=0.1Vrms
INL-(INR-)=0.1Vrms, Measure=OUTL(OUTR), BW=Bandpass
0
20
40
60
80
100
10 100 1000 10000 100000
Freauency[Hz]C
MR
R[d
B]
OUTL
Ta=-40,25,85oC
OUTR
Ta=-40,25,85oC
Power Dissipation vs Output Power
V+=3.3V, RL=16Ω, MUTE=H, GAIN=L, Ta=25oC
f=1kHz, Measure=OUTL, BW=400Hz to 22kHz
0
50
100
150
200
250
300
0 20 40 60 80 100
Output Pow er [mW/ch]
Pow
er
Dis
sip
atio
n [m
W]
Input=Lch
Input=Lch,Rch
THD+N=3%
NJU72040
– 18 –
THD+N vs Output Power
V+=3.3V, RL=16Ω, MUTE=H , GAIN=L
Input=INL+,INL-(inverted), AC_GND=INR+,INR-, f=1kHz
Measure=OUTL, BW=400Hz to 22kHz
0.01
0.1
1
10
0.001 0.01 0.1 1 10 100 1000
Output Pow er[mW]
TH
D+N
[%]
Ta=25,85oC
Ta=-40oC
THD+N vs Output Power
V+=3.3V, RL=16Ω, MUTE=H, GAIN=L, Ta=25oC
Input=INL+,INL-(inverted), AC_GND=INR+,INR-, f=1kHz
Measure=OUTL, BW=22Hz to 22kHz
0.01
0.1
1
10
0.001 0.01 0.1 1 10 100 1000
Output Pow er[mW]
TH
D+N
[%]
f=10kHz
f=100Hz,1kHz
THD+N vs Output Power
V+=3.3V, RL=32Ω, MUTE=H, GAIN=L
Input=INL+,INL-(inverted), AC_GND=INR+,INR-, f=1kHz
Measure=OUTL, BW=400Hz to 22kHz
0.01
0.1
1
10
0.001 0.01 0.1 1 10 100 1000
Output Pow er[mW]T
HD
+N
[%]
Ta=-40,25,85oC
THD+N vs Output Power
V+=3.3V, RL=32Ω, MUTE=H, GAIN=L, Ta=25oC
Input=INL+,INL-(inverted), AC_GND=INR+,INR-, f=1kHz
Measure=OUTL, BW=22Hz to 22kHz
0.01
0.1
1
10
0.001 0.01 0.1 1 10 100 1000
Output Pow er[mW]
TH
D+N
[%]
f=10kHz
f=100Hz,1kHz
THD+N vs Output Power
V+=3.3V, RL=16Ω, MUTE=H , GAIN=L
Input=INL+/R+,INL-/R-(inverted), f=1kHz, Measure=OUTL,
BW=400Hz to 22kHz
0.01
0.1
1
10
0.001 0.01 0.1 1 10 100 1000
Output Pow er[mW]
TH
D+N
[%]
Input=Lch
Input=Lch , Rch
THD+N vs Output Power
V+=3.3V, RL=32Ω, MUTE=H, GAIN=L
Input=INL+/R+,INL-/R-(inverted), f=1kHz, Measure=OUTL
BW=400Hz to 22kHz
0.01
0.1
1
10
0.001 0.01 0.1 1 10 100 1000
Output Pow er[mW]
TH
D+N
[%]
Input=Lch
Input=Lch , Rch
NJU72040
– 19 –
[CAUTION] The specifications on this databook are only
given for information , without any guarantee as regards either mistakes or omissions. The application circuits in this databook are described only to show representative usages of the product and not intended for the guarantee or permission of any right including the industrial rights.
THD+N vs Output Voltage
V+=3.3V, RL=10kΩ, MUTE=H , GAIN=L
Input=INL+,INL-(inverted), AC_GND=INR+,INR-, f=1kHz
Measure=OUTL, BW=400Hz to 22kHz
0.001
0.01
0.1
1
10
0.01 0.1 1 10
Output Voltage[Vrms]
TH
D+N
[%]
Ta=-40,25,85oC
THD+N vs Output Voltage
V+=3.3V, RL=10kΩ, MUTE=H, GAIN=L, Ta=25oC
Input=INL+,INL-(inverted), AC_GND=INR+,INR-, f=1kHz
Measure=OUTL, BW=22Hz to 22kHz
0.001
0.01
0.1
1
10
0.01 0.1 1 10
Output Voltage[Vrms]
TH
D+N
[%]
f=100,1k,10kHz
THD+N vs Output Voltage
V+=3.3V, MUTE=H, GAIN=L, Ta=25oC
Input=INL+,INL-(inverted), f=1kHz, Measure=OUTL ,
BW=400Hz to 22kHz
0.001
0.01
0.1
1
10
0.01 0.1 1 10Output Voltage[Vrms]
TH
D+N
[%]
RL=16
RL=32
RL=1k
RL=10k
RL=64
THD+N vs Output Voltage
V+=3.3V, RL=10kΩ, MUTE=H, GAIN=L
Input=INL+/R+,INL-/R-(inverted), f=1kHz, Measure=OUTL
BW=400Hz to 22kHz
0.001
0.01
0.1
1
10
0.01 0.1 1 10
Output Voltage[Vrms]
TH
D+N
[%]
Input=Lch , Rch
Input=Lch