Anpec APA2071 Stereo 3.1w non-inverting audio power amplifier(with dc volume control) Datasheet

APA2071
Stereo 3.1W Non-inverting Audio Power Amplifier(with DC Volume Control)
General Description
Features
•
•
•
Non-Inverting Audio Power Amplifier
The APA2071 is a monolithic integrated circuit, which
Low Operating Current about 9mA (Typical)
provides precise DC volume control, and a stereo
bridged audio power amplifiers capable of producing
Improved Depop Circuitry to Eliminate Turn-On
2.6W (2W) into 4Ω with less than 10% (1.0%) THD+N.
The attenuator range of the volume control in APA2071 is
and Turn-Off Transients in Outputs
•
32-Step Volume Adjustable by DC Voltage
from 18dB (VVOLUME=0V) to -80dB (VVOLUME=3.54V) with 32
steps. The advantage of internal gain setting can be less
with Hysteresis
•
Output Power
components and PCB area. Both the depop circuitry and
the thermal shutdown protection circuitry are integrated
at 1% THD+N
- 2.4W, at VDD=5V, BTL Mode, RL=3Ω
in the APA2071, that reduce pops and clicks noise during power up or shutdown mode operation. It also im-
- 2W, at VDD=5V, BTL Mode, RL=4Ω
proves the power off pop noise and protects the chip being destroyed by over temperature and short current
at 10% THD+N
- 3.1W, at VDD=5V, BTL Mode, RL=3Ω
failure. To simplify the audio system design, the APA2071
combines a stereo bridge-tied load (BTL) mode for
- 2.6W, at VDD=5V, BTL Mode, RL=4Ω
•
Two Output Modes: BTL and SE Modes Selected
•
by SE/BTL Pin
speaker drive and a stereo single-end (SE) mode for headphone drive into a single chip, where both modes are
Low Current Consumption in Shutdown Mode
easily switched by the SE/BTL input control pin signal.
(1µA, Typical)
•
•
Short Circuit Protection
Thermal Shutdown Protection and Over Current
Applications
Protection Circuitry
•
•
•
The OUTN Signal and the INN Signal are Inphase
•
Notebook PC
Power Enhanced Package (DIP-16 / DIP-16A)
•
LCD Monitor or TV
Lead Free and Green Devices Available
(RoHS Compliant)
Simplified Application Circuit
L-CH
Input
LINN
R-CH
Input
RINN
LOUTN
Stereo
Speaker
Stereo
Headphone
LOUTP
APA2071
ROUTN
DC Volume
Control
VOLUME
ROUTP
ANPEC reserves the right to make changes to improve reliability or manufacturability without notice, and advise
customers to obtain the latest version of relevant information to verify before placing orders.
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
1
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APA2071
Ordering and Marking Information
Package Code
J : DIP-16 / DIP-16A
Operating Ambient Temperature Range
I : - 40 to 85 °C
Handling Code
TU : Tube
Assembly Material
L : Lead Free Device G : Halogen and Lead Free Device
APA2071
Assembly Material
Handling Code
Temperature Range
Package Code
APA2071 J :
APA2071
XXXXX
XXXXX - Date Code
Note : ANPEC lead-free products contain molding compounds/die attach materials and 100% matte tin plate termination finish;
which are fully compliant with RoHS. ANPEC lead-free products meet or exceed the lead-free requirements of IPC/JEDEC J-STD020C for MSL classification at lead-free peak reflow temperature. ANPEC defines “Green” to mean lead-free (RoHS compliant) and
halogen free (Br or Cl does not exceed 900ppm by weight in homogeneous material and total of Br and Cl does not exceed
1500ppm by weight).
Pin Configuration
SHUTDOWN
BYPASS
RINN
GND
GND
LINN
VOLUME
SE/BTL
1
2
3
4
5
6
7
8
APA2071
Absolute Maximum Ratings
Symbol
VDD
TA
TJ
ROUTP
VDD
ROUTN
GND
GND
LOUTN
VDD
LOUTP
(Note 1)
Parameter
Rating
Unit
-0.3 to 6
V
Input Voltage (SE/BTL, SHUTDOWN, VOLUME, RINN, LINN to GND)
-0.3 to VDD+ 0.3
V
Output Voltage (LOUTN, LOUTP, ROUTP, ROUTN to GND)
-0.3 to VDD+ 0.3
V
Supply Voltage (VDD to GND)
Operating Ambient Temperature Range
Maximum Junction Temperature
TSTG
Storage Temperature Range
TSDR
Maximum Lead Soldering Temperature, 10 Seconds
PD
16
15
14
13
12
11
10
9
-40 to 85
ο
150
ο
C
C
ο
-65 to +150
Power Dissipation
C
ο
260
C
Internally Limited
W
Note 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired. Exposure to absolute
maximum rating conditions for extended periods may affect device reliability.
Thermal Characteristics
Symbol
θJA
θJC
Parameter
Typical Value
Junction-to-Ambient Resistance in Free Air (Note 2)
Junction-to-Case Resistance in Free Air
(Note 3)
Unit
45
o
8
o
C/W
C/W
Note 2: θJA is measured with the component mounted on a high effective thermal conductivity test board in free air.
Note 3: The case temperature is measured at the center of the GND pin on the beside of the DIP-16 / DIP-16A package.
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
2
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APA2071
Recommended Operating Conditions
Symbol
VDD
VIH
VIL
(Note 4)
Parameter
Range
Supply Voltage
Unit
3.3 ~ 5.5
High Level Threshold Voltage
Low Level Threshold Voltage
SHUTDOWN
0.4VDD ~ VDD
SE/BTL
0.8VDD ~ VDD
SHUTDOWN
0 ~ 1.0
SE/BTL
0 ~ 1.0
VCIM
Common Mode Input Voltage
TA
Ambient Temperature Range
-40 ~ 80
TJ
Junction Temperature Range
-40 ~ 125
RL
Speaker Resistance
RL
Headphone Resistance
V
~ VDD-1.0
ο
C
3~
Ω
16 ~
Note 4 : Refer to the typical application circuit
Electrical Characteristics
Unless otherwise specified, these specifications apply over VDD=5V, VGND=0V and TA= -40 ~ 85 oC. Typical values are at TA=25oC.
Symbol
IDD
ISD
TSTART-UP
Ri
Parameter
APA2071
Test Conditions
Unit
Min.
Typ.
Max.
VSE/BTL =0V
-
9
20
VSE/BTL=5V
-
4
10
Shutdown Current
VSE/BTL=0V, VSHUTDOWN =0V
-
1
-
Start-Up Time from Shutdown
CBYPASS=2.2µF
-
1.6
-
s
-
20
-
kΩ
VDD=5.5V,THD+N=3%, RL=3Ω
-
3.1
-
THD+N=10%, RL=3Ω
-
3.1
-
THD+N =10%, RL=4Ω
-
2.6
-
THD+N =10%, RL=8Ω
-
1.6
-
THD+N =1%, RL=3Ω
-
2.4
-
THD+N =1%, RL=4Ω
-
2
-
THD+N =0.5%, RL=8Ω
1
1.3
-
PO=1.2W, RL=4Ω, fin=1kHz
-
0.09
-
PO=0.9W, RL=8Ω, fin=1kHz
-
0.12
-
-
60
-
dB
-
90
-
dB
Supply Current
Input Resistance
mA
BTL MODE. VDD=5V, GAIN=6dB (UNLESS OTHERWISE NOTED)
PO
THD+N
PSRR
Crosstalk
Output Power, fin=1kHz
Total Harmonic Distortion Pulse
Noise
Power Supply Rejection Ratio
Channel Separation
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
W
%
VDD Ripple=0.1Vrms, RL=8Ω,
CBYPASS=2.2µF, fin=217Hz
CBYPASS=2.2µF, RL=8Ω,
fin=1kHz
3
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APA2071
Electrical Characteristics (Cont.)
Unless otherwise specified, these specifications apply over VDD=5V, VGND=0V and TA= -40 ~ 85 oC. Typical values are at TA=25oC.
Symbol
Parameter
APA2071
Test Conditions
Min.
Unit
Typ.
Max.
BTL MODE. VDD=5V, GAIN=6dB (UNLESS OTHERWISE NOTED) (CONT.)
VOS
Output Offset Voltage
S/N
Signal to Noise Ratio
RL=4Ω
-
5
-
mV
PO=1.1W, RL=8Ω, A_weighting
-
95
-
dB
THD+N=10%, RL=16Ω
-
220
-
THD+N =10%, RL=32Ω
-
120
-
THD+N =1%, RL=16Ω
-
160
-
THD+N =1%, RL=32Ω
-
95
-
PO=125mW, RL=16Ω, fin=1kHz
-
0.12
-
PO=65mW, RL=32Ω, fin=1kHz
-
0.11
-
-
60
-
dB
SE MODE. VDD=5V, GAIN=0dB
Po
THD+N
PSRR
Crosstalk
Output Power, fin=1kHz
Total Harmonic Distortion
Pulse Noise
Power Supply Rejection Ratio
VDD Ripple =0.1Vrms, RL=32Ω,
CBYPASS =2.2µF, fin=217Hz
mW
%
Channel Separation
CBYPASS=2.2µF, RL=32Ω, fin=1kHz
-
60
-
dB
VOS
Output Offset Voltage
RL=32Ω
-
5
-
mV
S/N
Signal to Noise Ratio
PO=75mW, RL=32Ω, A_weighting
-
100
-
dB
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
4
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APA2071
Typical Operating Characteristics
THD+N vs. Output Power
THD+N vs. Output Power
10
10
RL = 4Ω
THD+N (%)
1
VDD = 5V
AV =12dB
fin = 1kHz
SE Mode
RL = 3Ω
THD+N (%)
VDD = 5V
AV =18dB
fin = 1kHz
BTL Mode
RL = 8Ω
0.1
0.01
1
RL = 16Ω
RL = 32Ω
0.1
0
0.5
1
1.5
2
2.5
Output Power (W)
3
0.01
3.5
0
40m
THD+N vs. Output Power
10
VDD = 5V
AV =18dB
RL =3Ω
BTL Mode
VDD = 5V
fin =1kHz
RL =3Ω
BTL Mode
THD+N (%)
THD+N (%)
160m 200m 240m
120m
Output Power (W)
THD+N vs. Output Power
10
80m
1
AV = 18dB
fin = 20kHz
1
fin= 20Hz
0.1
fin= 1kHz
AV = 6dB
0.01
0
0.5
1
1.5
2
2.5
Output Power (W)
0.1
3
0.05
10m
3.5
THD+N vs. Frequency
VDD = 5V
RL =3Ω
PO = 1.8W
BTL Mode
1
AV=18dB
0.1
VDD = 5V
AV = 6dB
RL =3Ω
BTL Mode
1
PO=1.8W
0.1
AV=6dB
0.01
20
100
1k
Frequency (Hz)
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
5
THD+N vs. Frequency
10
THD+N (%)
THD+N (%)
10
100m
1
Output Power (W)
PO=0.9W
0.01
10k 20k
5
20
100
1k
Frequency (Hz)
10k 20k
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APA2071
Typical Operating Characteristics (Cont.)
THD+N vs. Output Power
THD+N vs. Output Power
10
10
THD+N (%)
VDD = 5V
fin =1kHz
RL =4Ω
BTL Mode
THD+N (%)
1
AV = 18dB
fin = 20Hz
0.1
0.1
fin = 1kHz
VDD = 5V
AV =18dB
RL =4Ω
BTL Mode
0.01
10m
100m
1
Output Power (W)
AV = 6dB
0.01
fin= 20kHz
1
0
0.5
1
1.5
2
2.5
3
3.5
Output Power (W)
THD+N vs. Frequency
THD+N vs. Frequency
10
10
VDD = 5V
AV= 6dB
RL=4Ω
BTL Mode
1
1
THD+N (%)
THD+N (%)
VDD = 5V
RL=4Ω
PO=1.5W
BTL Mode
AV=6dB
0.1
PO=1.5W
0.1
AV=18dB
0.01
20
100
PO=0.8W
1k
0.01
10k 20k
20
100
Frequency (Hz)
VDD = 5V
fin= 1kHz
RL=8Ω
BTL Mode
THD+N (%)
THD+N (%)
10k 20k
THD+N vs. Output Power
10
1
AV = 6dB
VDD = 5V
AV = 18dB
RL=8Ω
BTL Mode
1
fin = 20kHz
fin = 20Hz
0.1
0.1
fin = 1kHz
AV = 18dB
0.01
1k
Frequency (Hz)
THD+N vs. Output Power
10
5
0
0.5
1
1.5
2
2.5
Output Power (W)
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
3
0.01
10m
3.5
100m
1
5
Output Power (W)
6
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APA2071
Typical Operating Characteristics (Cont.)
THD+N vs. Frequency
THD+N vs. Frequency
10
VDD = 5V
AV = 6dB
RL=8Ω
BTL Mode
THD+N (%)
THD+N (%)
10
1
PO=0.5W
VDD=5V
RL=8Ω
PO=0.9W
BTL Mode
1
AV=6dB
0.1
0.1
AV=18dB
PO=0.9W
0.01
20
100
1k
Frequency (Hz)
0.01
10k 20k
20
VDD=5V
fin=1kHz
RL=16Ω
SE Mode
1
AV = 0dB
0.1
VDD=5V
AV=12dB
RL=16Ω
CO=1000µF
1 SE Mode
fin = 20kHz
0
fin = 1kHz
0.01
40m 80m 120m 160m 200m 240m
10m
50m 100m 200m 300m
Output Power (W)
Output Power (W)
THD+N vs. Frequency
THD+N vs. Frequency
10
VDD=5V
RL=16Ω
PO=125mW
CO=1000µF
SE Mode
1
THD+N (%)
THD+N (%)
10
AV=0dB
0.1
VDD=5V
AV=0dB
RL=16Ω
CO=1000µF
SE Mode
1
PO=125mW
0.1
AV=12dB
0.01
fin = 20Hz
0.1
AV = 12dB
0.01
10k 20k
10
THD+N (%)
THD+N (%)
1k
Frequency (Hz)
THD+N vs. Output Power
THD+N vs. Output Power
10
100
20
100
1k
Frequency (Hz)
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
PO=60mW
0.01
10k 20k
7
20
100
1k
Frequency (Hz)
10k 20k
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APA2071
Typical Operating Characteristics (Cont.)
THD+N vs. Output Power
THD+N vs. Output Power
10
VDD=5V
AV=12dB
RL=32Ω
CO=1000µF
SE Mode
VDD=5V
fin=1kHz
RL=32Ω
SE Mode
THD+N (%)
THD+N (%)
10
1
AV = 0dB
1
fin = 20Hz
fin = 20kHz
0.1
0.1
AV = 12dB
0.01
40m
0
80m
fin = 1kHz
0.01
10m
120m 160m 200m 240m
50m
THD+N vs. Frequency
THD+N (%)
THD+N (%)
THD+N vs. Frequency
10
VDD=5V
RL=32Ω
PO=65mW
CO=1000µF
SE Mode
1
200m300m
Output Power (W)
Output Power (W)
10
100m
AV=0dB
VDD=5V
AV=12dB
RL=32Ω
CO=1000µF
SE Mode
1
PO=65mW
0.1
0.1
AV=12dB
0.01
20
PO=30mW
0.01
100
1k
Frequency (Hz)
10k 20k
20
100
Frequency Response
1k
Frequency (Hz)
10k 20k
Frequency Response
+20
+20
+80
+80
Amplitude( 14dB)
+0
Phase( 6dB)
+8
+4
+0
-40
VDD=5V
RL=4Ω
PO=0.8W
BTL Mode
10
100
Amplitude( 6dB)
1k
10k
200k
Amplitude(dB)
Phase( 14dB)
+12
+16
Phase (Degrees)
Amplitude(dB)
+40
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
Phase( 14dB)
+12
+8
+4
-120
+0
10
8
+0
Phase( 6dB)
-80
Frequency (Hz)
+40
-40
VDD=5V
RL=8Ω
PO=0.5W
BTL Mode
100
Amplitude( 6dB)
1k
10k
Frequency (Hz)
Phase (Degrees)
Amplitude( 14dB)
+16
-80
200k
-120
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APA2071
Typical Operating Characteristics (Cont.)
Frequency Response
Frequency Response
+14
+40
+10
+0
Phase(0dB)
+0
-40
Amplitude(0dB)
VDD=5V
RL=16Ω
CO=1000µF
PO=60mW
SE Mode
-4
-8
10
100
+80
1k
10k
Frequency (Hz)
200k
+0
+4
Phase(0dB)
-40
+0
-80
-4
-120
-8
Amplitude(0dB)
VDD=5V
RL=32Ω
CO=1000µF
PO=30mW
SE Mode
10
Crosstalk(dB)
Corsstalk(dB)
-120
Right to Left
Left to Right
20
100
1k
+0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
Left to Right
-120
20
10k 20k
100
-30
VDD=5V
RL=16Ω
CO=1000µF
PO=125mW
SE Mode
-10
-20
-40
Right to Left
-60
Left to Right
-30
-50
-80
-80
-90
-90
-100
20
-100
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
9
Right to Left
-60
-70
10k 20k
VDD=5V
RL=32Ω
CO=1000µF
PO=65mW
SE Mode
-40
-70
100
1k
Frequency (Hz)
10k 20k
Crosstalk vs. Response
+0
-50
1k
Frequency (Hz)
Corsstalk(dB)
Corsstalk(dB)
-20
-120
Right to Left
Crosstalk vs. Response
-10
200k
VDD=5V
RL=4Ω
PO=1.5W
BTL Mode
Frequency (Hz)
+0
10k
Crosstalk vs. Frequency
-50
-60
-70
-110
1k
Frequency (Hz)
VDD=5V
RL=8Ω
PO=0.9W
BTL Mode
-80
-90
-100
-80
100
Crosstalk vs. Frequency
+0
-10
-20
-30
-40
+40
Phase(12dB)
Phase (Degrees)
+4
Amplitude(dB)
Phase(12dB)
Phase (Degrees)
Amplitude(dB)
+14
Amplitude(12dB)
Amplitude(12dB)
+10
+80
Left to Right
20
100
1k
Frequency (Hz)
10k 20k
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APA2071
Typical Operating Characteristics (Cont.)
Output Noise Voltage vs. Frequency
Output Noise Voltage vs. Frequency
100µ
Output Noise Voltage(dB)
Output Noise Voltage(dB)
100µ
Filter BW<22kHz
20µ
A-weighting
10µ
VDD=5V
AV=6dB
RL=4Ω
BTL Mode
1µ
20
100
1k
Filter BW<22kHz
20µ
10µ
A-weighting
1µ
20
10k 20k
VDD=5V
AV=0dB
RL=32Ω
SE Mode
100
Frequency (Hz)
PSRR vs. Frequency
PSRR vs. Frequency
+0
PSRR(dB)
VDD=5V
RL=4Ω
VIN=200mV
AV=18dB
BTL Mode
-10
-20
-30
PSRR(dB)
-20
-30
-40
-50
-60
-50
-60
-70
-80
-80
-90
-90
20
100
1k
-100
20
10k 20k
VDD=5V
RL=32Ω
VIN=200mV
AV=12dB
SE Mode
-40
-70
-100
100
Frequency (Hz)
10k 20k
Shutdown Attenuation vs. Frequency
+0
VDD=5V
RL=8Ω
VIN=1Vrms
AV=6dB
BTL Mode
Shutdown Attenuation(dB)
Mute Attenuation(dB)
1k
Frequency (Hz)
Mute Attenuation vs. Frequency
+0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
10k 20k
Frequency (Hz)
+0
-10
1k
-10
-20
-30
-40
VDD=5V
RL=8Ω
VIN=1Vrms
AV=6dB
BTL Mode
-50
-60
-70
-80
-90
-100
-110
20
100
1k
10k
-120
20
20k
Frequency (Hz)
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
100
10k 20k
1k
Frequency (Hz)
10
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APA2071
Typical Operating Characteristics (Cont.)
Gain vs. Volume Voltage
Supply Current vs. Supply Voltage
20
10.0
No Load
10
9.0
Down
-10
Gain(dB)
Supply Current (mA)
0
-20
Up
-30
-40
-50
-60
VDD=5V
No Load
BTL Mode
-70
BTL
8.0
7.0
6.0
5.0
SE
4.0
3.0
-80
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0
2.0
3.0
3.5
DC Voltage (V)
200
1.8
180
RL=3Ω
1.4
RL=4Ω
1.2
1.0
0.8
RL=8Ω
0.6
0.4
0.0
0.5
1.0
1.5
5.0
5.5
RL=8Ω
160
140
120
RL=16Ω
100
80
RL=32Ω
60
40
VDD=5V
BTL Mode
0.2
0.0
4.5
Power Dissipation vs. Output Power
Power Dissipation(mW)
Power Dissipation(W)
Power Dissipation vs.Output Power
2.0
1.6
4.0
Supply Voltage(V)
2.0
2.5
3.0
VDD=5V
SE Mode
20
0
3.5
Output Power (W)
0
50
100
150
200
250
Output Power(mW)
Output Power vs. Supply Voltage
4.0
Output Power (W)
3.5
3.0
RL=3Ω,THD+N=10%
RL=4Ω,THD+N=10%
RL=3Ω,THD+N=1%
2.5
2.0
1.5
1.0
0.5
0.0
BTL Mode
RL=8Ω,THD+N=1%
AV=6dB
RL=8Ω,THD+N=10%
RL=4Ω,THD+N=1%
4.50
4.75
5.00
5.25
5.50
Supply Voltage (V)
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
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APA2071
Pin Description
PIN
FUNCTION
NO.
NAME
1
SHUTDOWN
2
BYPASS
3
RINNN
4,5,12,13
GND
Ground connection. Connect all of the GND pins to ground plane.
6
LINN
Left channel input terminal
7
VOLUME
8
SE/BTL
Output mode control input, high for SE output mode and low for BTL mode.
9
LOUTP
Left channel positive output in BTL mode and high impedance in SE mode.
10,15
VDD
11
LOUTN
Left channel negative output in BTL mode and SE mode.
14
ROUTN
Right channel negative output in BTL mode and SE mode.
16
ROUTP
Right channel positive output in BTL mode and high impedance in SE mode.
Shutdown control pin. Pulling low the voltage on this pin shuts off the IC. In
shutdown mode, the IC only draws 1µA (typical) of supply current.
Bypass capacitor connection pin for the bias voltage generator.
Right channel input terminal
DC voltage input pin for internal volume gain setting (DC Volume control).
Supply voltage input pin. Connect all of the VDD pins to supply voltage.
Block Diagram
LOUTN
LINN
DC
Volume
Control
LOUTP
RINN
Bias Voltage
Generator
BYPASS
ROUTN
VOLUME
ROUTP
SE/BTL
SHUTDOWN
SE/BTL Mode
Selection
VDD
Power and Depop
Circuit
Shutdown
Circuit
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
12
GND
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APA2071
Typical Application Circuit
VDD
CS
0.1µ F
VDD
Ci
1µF
L-CH
Input
100 µ F
GND
220 µ F
LINN
Control
Pin Ring
SE/BTL
Signal
LOUTP
RINN
R-CH
Input
CBYPASS
Bias Voltage
Generator
100k Ω
2.2 µ F
4Ω
Shutdown SHUTDOWN
Signal
CC
220 µ F
VOLUME
SE/BTL
Sleeve
Tip
Headphone
Jack
BYPASS
ROUTN
VDD
50k Ω
100kΩ
1kΩ
4Ω
DC
Volume
Control
Ci
1 µF
VDD
CC
LOUTN
SE/BTL Mode
Selection
1k Ω
ROUTP
Shutdown
Circuit
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
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APA2071
DC Volume Control Table_BTL Mode
G a in(dB)
V o ltage Range (% of V D D )
V o ltage Range (V D D = 5 V )
H igh(%)
L o w (%)
Recommended (%)
H igh(V)
L o w (V)
Recommended (V)
18
2.40
0 .00
0 .00
0 .12
0 .00
0.00
17.5
4.60
3 .40
4 .00
0 .23
0 .17
0.20
17
6.80
5 .60
6 .20
0 .34
0 .28
0.31
16.5
9.20
7 .80
8 .60
0 .46
0 .39
0.43
16
11.40
10.20
10.80
0 .57
0 .51
0.54
15.5
13.80
12.40
13.00
0 .69
0 .62
0.65
15
16.00
14.60
15.40
0 .80
0 .73
0.77
14.5
18.20
16.80
17.60
0 .91
0 .84
0.88
14
20.60
19.20
19.80
1 .03
0 .96
0.99
13
22.80
21.40
22.00
1 .14
1 .07
1.10
12
25.00
23.60
24.40
1 .25
1 .18
1.22
10
27.40
25.80
26.60
1 .37
1 .29
1.33
8
29.60
28.20
28.80
1 .48
1 .41
1.44
6
31.80
30.40
31.20
1 .59
1 .52
1.56
4
34.20
32.60
33.40
1 .71
1 .63
1.67
2
36.40
34.80
35.60
1 .82
1 .74
1.78
0
38.60
37.00
37.80
1 .93
1 .85
1.89
-2
41.00
39.40
40.20
2 .05
1 .97
2.01
-4
43.20
41.60
42.40
2 .16
2 .08
2.12
-7
45.60
43.80
44.60
2 .28
2 .19
2.23
-1 0
47.80
46.00
47.00
2 .39
2 .30
2.35
-1 3
50.00
48.40
49.20
2 .50
2 .42
2.46
-1 6
52.40
50.60
51.40
2 .62
2 .53
2.57
-1 9
54.60
52.80
53.80
2 .73
2 .64
2.69
-2 2
56.80
55.00
5 6.00
2 .84
2 .75
2.80
-2 5
59.20
57.40
58.20
2 .96
2 .87
2.91
-2 8
61.40
59.60
60.40
3 .07
2 .98
3.02
-3 1
63.60
61.80
62.80
3 .18
3 .09
3.14
-3 4
66.00
64.00
65.00
3 .30
3 .20
3.25
-3 7
68.20
66.40
67.20
3 .41
3 .32
3.36
-4 0
70.40
68.60
69.60
3 .52
3 .43
3.48
-8 0
100.00
70.80
100.00
5 .00
3 .54
5.00
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
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APA2071
Function Description
Bridge-Tied Load (BTL) Operation
need for an output coupling capacitor which is required in
a single supply, SE configuration.
The APA2071’s output stage of each channel, which consists of one pair of operational amplifiers, provides op-
Single-Ended (SE) Operation
tion for BTL operation shown as figure 1.
To consider the single-supply SE configuration shown in
Typical Application Circuit, a coupling capacitor is required
to block the DC offset voltage from reaching the load.
OUTN
Volume Control
amplifier output
signal
These capacitors can be quite large (approximately 33µF
to 1000µF), so they tend to be expensive, occupy valu-
OP1
able PCB area, and have the additional drawback of limiting low-frequency performance of the system (refer to
RL
the Output Coupling Capacitor). The rules described still
OUTP
Bias Voltage
Generator
hold with the addition of the following relationship:
1
≤ 1 << 1
(1)
Cbypass x 130kΩ
2RiCi
2RLCC
OP2
Figure 1: APA2071 Internal Configuration
(each channel)
SE/BTL Mode Selection Function
The power amplifier’s (OP1) gain is set by internal unity
The best cost saving feature of APA2071 is that it can be
switched easily between BTL and SE modes. This fea-
gain and input audio signal comes from internal volume
control amplifier while the second amplifier (OP2) is in-
ture eliminates the requirement for an additional headphone amplifier in applications where internal stereo
ternally fixed in a unity-gain, inverting configuration. Figure 1 shows that the output of OP1 is connected to the
input to OP2, which results in the output signals of both
amplifiers with identical in magnitude but out of phase
speakers are driven in BTL mode but external headphone
or speakers must be accommodated.
Inside of the APA2071, two separated amplifiers drive
OUTP and OUTN (See Figure 1). The SE/BTL input con-
180°. Consequently, the differential gain for each channel is 2 x (Gain of SE mode). The OUTN signal and the
trols the operation of the follower amplifier that drives
LOUTP and ROUTN.
INN signal are inphase, and the OUTP signal and the
INN signal are out of phase.
By driving the load differentially through outputs OUTP
and OUTN, an amplifier configuration is commonly re-
When SE/BTL keeps low, the OP2 turns on and the
APA2071 is in the BTL mode.
•
•
ferred to bridged mode is established. BTL mode operation is different from the classical single-ended (SE) am-
When SE/BTL keeps high, the OP2 is in a high output
impedance state, which configures the APA2071 as
SE driver from OUTP. IDD is reduced by approximately
one-half in SE mode.
plifier configuration where one side of its load is connected to the ground.
A BTL amplifier design has a few distinct advantages over
the SE configuration, as it provides differential drive to the
The control of the SE/BTL input can be a logic-level TTL
source or a resistor divider network or the stereo headphone jack with switch pin as shown in the Typical Application Circuit.
load, thus doubles the output swing for a specified supply voltage.
When placed under the same conditions, a BTL amplifier
has four times the output power of a SE amplifier. A BTL
1kΩ
VDD
100kΩ
configuration, such as the one used in APA2071, also
creates a second advantage over SE amplifiers. Since
Ring
SE/BTL
the differential outputs, ROUTP, ROUTN, LOUTP, and
LOUTN, are biased at half-supply, it’s not necessary for
Tip
Sleeve
Headphone Jack
DC voltage to be across the load. This eliminates the
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
Control
Pin
Figure 2: SE/BTL Input Selection by Phonejack Plug
15
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APA2071
Function Description (Cont.)
SE/BTL Mode Selection Function (Cont.)
For the highest accuracy, the voltage shown in the ‘recommended voltage’column of the table is used to select
In Figure 2, input SE/BTL operates as below:
When the phonejack plug is inserted, the 1kΩ resistor is
a desired gain. This recommended voltage is exactly halfway between the two nearest transitions. The gain levels
disconnected and the SE/BTL input is pulled high to enable the SE mode. Meanwhile, the OUTN amplifier shuts
are 32 steps from 18dB to -40dB in BTL mode, and the
last step at -80dB as mute mode.
down which turns the speaker to be mute. The OUTP
amplifier then drives through the output capacitor into the
Shutdown Function
headphone jack. When there is no headphone plugged
into the system, the contact pin of the headphone jack is
In order to reduce power consumption while not in use,
the APA2071 contains a shutdown pin to externally turn
connected from the signal pin, and the voltage divider is
set up by resistors 100kΩ and 1kΩ. Resistor 1kΩ then is
off the amplifier bias circuitry. This shutdown feature
turns the amplifier off when a logic low is placed on the
pulled low the SE/BTL pin, enabling the BTL function.
SHUTDOWN pin. The trigger point between a logic high
and logic low level is typically 2.0V. It would be better to
DC Volume Control Function
switch between the ground and the supply VDD to provide
maximum device performance.
The APA2071 has an internal stereo volume control whose
setting is the function of the DC voltage applied to the
By switching the SHUTDOWN pin to low, the amplifier
VOLUME input pin. The APA2071 volume control consists
of 32 steps that are individually selected by a variable DC
enters a low-current state, IDD<1µA. APA2071 is in shutdown mode. On normal operation, SHUTDOWN pin is
voltage level on the VOLUME control pin. The range of
the steps, controlled by the DC voltage, are from 18dB
pulled to high level to keep the IC out of the shutdown
mode. The SHUTDOWN pin should be tied to a defi-
to -80dB. Each gain step corresponds to a specific input
voltage range, as shown in table. To minimize the effect of
nite voltage to avoid unwanted state changing.
noise on the volume control pin, which can affect the selected gain level, hysteresis and clock delay are
Thermal Protection
The thermal protection circuit limits the junction temperature of the APA2071. When the junction temperature ex-
implemented. The amount of hysteresis corresponds to
half of the step width, as shown in the volume control
ceeds T J = +150 oC, a thermal sensor turns off the
amplifier, allowing the devices to cool. The thermal sen-
graph.
sor allows the amplifier to start-up after the junction temperature down about 125 oC. The thermal protection is
APA2071 DC Volume Control Curve (BTL)
20
designed with a 25oC hysteresis to lower the average TJ
during continuous thermal overload conditions, which is
10
0
increasing lifetime of the IC.
Gain (dB)
-10
Forward
-20
-30
Over-Current Protection
Backward
The APA2071 monitors the output current. When the cur-
-40
rent exceeds the current-limit threshold, the APA2071 turns
off the output to prevent the IC from damages in over-
-50
-60
current or short-circuit condition. When the over-current
occurs in power amplifier, the output buffer’s current will
-70
-80
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0
be foldbacked to a low setting level, and it will release
when over-current situation is no long existence. On the
DC Volume (V)
contrary, if the over-current period is long enough and the
IC’s junction temperature reaches the thermal protection
Figure 3: Gain setting vs. VOLUME pin voltage
threshold, the IC will enter thermal protection mode.
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
16
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APA2071
Application Information
Input Capacitor (Ci)
than 0.485VDD, the APA2071 will enter mute condition. The
value of VBYPASS can be calculated as blew:
In the typical application, an input capacitor, Ci, is required
to allow the amplifier to bias the input signal to the proper
DC level for optimum operation. In this case, Ci and the
fixed input impedance Ri form a high-pass filter with the
VBYPASS = 0.5VDD - ILeakage × 130k Ω
(4)
corner frequency is determined in the following equation:
fC(highpass ) =
1
2 πR iC i
Where
(2)
ILeakage =Leakage current of CBYPASS
The value of Ci must be considered carefully because it
directly affects the low frequency performance of the
Therefore, it is recommended that CBYPASS ’s leakage current should be no more than 0.5µA for properly work of
circuit. Consider the example where Ri is 20kΩ and the
specification calls for a flat bass response down to 40Hz.
the APA2071.
To avoid the start-up pop noise, the bypass voltage should
rise slower than the input bias voltage and the relation-
The equation is reconfigured below :
Ci =
ship shown in equation should be maintained.
1
2 π R i fc
(3)
1
1
<<
( C BYPASS X130k Ω )
C i X20k Ω
Consider the variation of input resistance (Ri), the value
of Ci should be 0.2µF. Therefore, it’s better to choose a
(5)
value in the range from 0.22µF to 1.0µF. A further consideration for this capacitor is the leakage path from the in-
The capacitor is fed from a 130kΩ resistor inside of
the amplifier and the 20kΩ is the fixed input resistance.
put source through the input network (Ri + Rf, Ci) to the
Bypass capacitor, C BYPASS, values of 2.2µF to 10µF ceramic or tantalum low-ESR capacitors are recom-
load.
This leakage current creates a DC offset voltage at the
input to the amplifier that reduces useful headroom, es-
mended for the best THD+N and noise performance.
The bypass capacitance also affects the start-up time. It
pecially in high gain applications. For this reason, a lowleakage tantalum or ceramic capacitor is the best choice.
is determined in the following equation:
When polarized capacitors are used, the positive side of
the capacitors should face the amplifiers’ inputs in most
Tstart up = 5X(C BYPASS X130k Ω )
applications because the DC level of the amplifiers’ inputs are held at VDD/2. Please note that it is important to
(6)
Output Coupling Capacitor (CC)
In the typical single-supply SE configuration, an output
confirm the capacitor polarity in the application.
coupling capacitor (CC) is required to block the DC bias at
the output of the amplifier thus preventing DC currents in
Effective Bypass Capacitor (CBYPASS)
A power amplifier, proper supply bypassing, is critical for
low noise performance and high power supply rejection.
the load. As with the input coupling capacitor, the output
coupling capacitor and impedance of the load form a high-
The capacitor location on the BYPASS pin should be as
close to the device as possible. The effect of a larger
pass filter governed by the equation.
supply bypass capacitor is to improve PSRR due to increased half-supply stability. Two critical criteria of by-
FC(highpass) =
st
1
2πRLCC
(7)
pass capacitor (CBYPASS): 1 , it depends upon desired PSRR
requirements and click-and-pop performance; 2 nd, the
For example, a 330µF capacitor with an 8Ω speaker would
leakage current of CBYPASS will induce the voltage drop of
VBYPASS (voltage of BYPASS pin), and if the VBYPASS is less
attenuate low frequencies below 60.6Hz. The main
disadvantage, from a performance standpoint, is the load
Copyright  ANPEC Electronics Corp.
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APA2071
Application Information (Cont.)
Output Coupling Capacitor (CC) (Cont.)
impedance is typically small, which drives the low-frequency corner higher degrading the bass response.
This capacitor discharges through the internal 10kΩ
resistors. Depending on the size of CC, the time constant
Large values of CC are required to pass low frequencies
into the load.
can be relatively large. To reduce transients in SE mode,
an external 1kΩ resistor can be placed in parallel with the
internal 10kΩ resistor. The tradeoff for using this resistor
Power Supply Decoupling Capacitor (CS)
The APA2071 is a high-performance CMOS audio ampli-
is an increase in quiescent current. In the most cases,
choosing a small value of Ci in the range of 0.33µF to
fier that requires adequate power supply decoupling to
ensure the output total harmonic distortion (THD+N) is
1µF, CBYPASS being equal to 4.7µF and an external 1kΩ
resistor should be placed in parallel with the internal 10kΩ
as low as possible. Power supply decoupling also prevents the oscillations caused by long lead length between
resistor should produce a virtually clickless and popless
turn-on.
the amplifier and the speaker. The optimum decoupling
is achieved by using two different type capacitors that tar-
A high gain amplifier intensifies the problem as the small
delta in voltage is multiplied by the gain, so it is advanta-
get on different types of noise on the power supply leads.
For higher frequency transients, spikes, or digital hash
geous to use low-gain configurations.
on the line, a good low equivalent-series-resistance
(ESR) ceramic capacitor, typically 0.1µF, is placed as close
BTL Amplifier Efficiency
as possible to the device VDD lead works best. For filtering
lower-frequency noise signals, it is recommended to
An easy-to-use equation to calculate efficiency starts out
as being equal to the ratio of power from the power sup-
place a large aluminum electrolytic capacitor of 10µF or
greater near the audio power amplifier
ply to the power delivered to the load.
The following equations are the basis for calculating
amplifier efficiency.
Optimizing Depop Circuitry
Circuitry has been included in the APA2071 to minimize
the amount of popping noise at power-up and when com-
Efficiency =
ing out of shutdown mode. Popping occurs whenever a
voltage step is applied to the speaker. In order to elimi-
PO
P SUP
(8)
Where
nate clicks and pops, all capacitors must be fully discharged before turn-on. Rapid on/off switching of the de-
PO =
vice or the shutdown function will cause the click and pop
circuitry.
The value of Ci will also affect turn-on pops (Refer to
VO, RMS =
Effective Bypass Capacitance). The bypass voltage ramp
up should be slower than input bias voltage. Although the
P SUP = V DD × I DD , AVG = V DD ×
VO,RMS
2
RL
=
VP2
2R L
VP
(9)
2
2VP
πR L
(10)
bypass pin current source cannot be modified, the size of
Efficiency of a BTL configuration :
CBYPASS can be changed to alter the device turn-on time
and the amount of clicks and pops. By increasing the value
of CBYPASS, turn-on pop can be reduced. However, the
PO
=
P SUP
tradeoff for using a larger bypass capacitor is to increase
the turn-on time for this device. There is a linear relation-
VP2
πV P
2R L
=
2VP
4V DD
V DD ×
πR L
(11)
Table 1 is for calculating efficiencies for four different out-
ship between the size of CBYPASS and the turn-on time. In a
SE configuration, the output coupling capacitor (CC), is of
put power levels.
particular concern.
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
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APA2071
Application Information (Cont.)
BTL Amplifier Efficiency (Cont.)
BTL mode : PD, MAX =
Note that the efficiency of the amplifier is quite low for
lower power levels and rises sharply as power to the load
4VDD2
2π2RL
(13)
Since the APA2071 is a dual channel power amplifier, the
is increased resulting in a nearly flat internal power dissipation over the normal operating range. In addition, the
maximum internal power dissipation is 2 times that both
of equations depend on the mode of operation. Even with
internal dissipation at full output power is less than in the
half power range. Calculating the efficiency for a specific
this substantial increase in power dissipation, the
APA2071 does not require extra heatsink. The power dis-
system is the key to proper power supply design. For a
stereo 1W audio system with 8Ω loads and a 5V supply,
sipation from equation (14), assuming a 5V-power supply and an 8Ω load, must not be greater than the power
the maximum draw on the power supply is almost 3W.
A final point to remember about linear amplifiers (either
dissipation that results from the equation (16):
SE or BTL) is how to manipulate the terms in the efficiency equation to utmost advantage when possible. Note
PD, MAX =
that in equation, VDD is in the denominator. This indicates
that as VDD goes down, efficiency goes up. In other words,
TJ, MAX - TA
θJA
(14)
For DIP-16 / DIP-16A package, the thermal resistance (θJA)
is equal to 45οC/W.
Since the maximum junction temperature (TJ,MAX) of the
use the efficiency analysis to choose the correct supply
voltage and speaker impedance for the application.
Po (W)
Efficiency (%)
IDD(A)
VPP(V)
PD (W)
APA2071 is 150οC and the ambient temperature (TA) is
defined by the power system design, the maximum power
0.25
31.25
0.16
2.00
0.55
dissipation which the IC package is able to handle can be
obtained from equation16.
0.50
47.62
0.21
2.83
0.55
1.00
66.67
0.30
4.00
0.5
Once the power dissipation is greater than the maximum
limit (P D,MAX ), either the supply voltage (V DD) must be
decreased, the load impedance (RL) must be increased
or the ambient temperature should be reduced.
1.25
78.13
0.32
4.47
0.35
Thermal Consideration
Linear power amplifiers dissipate a significant amount of
**High peak voltages cause the THD+N to increase.
heat in the package under normal operating conditions.
The first consideration to calculate maximum ambient
Table 1. Efficiency vs. Output Power in 5-V/8Ω BTL Systems
Power Dissipation
temperatures is the numbers from the Power Dissipation vs. Output Power graphs are per channel values, so
Whether the power amplifier is operated in BTL or SE
mode, power dissipation is the major concern. Equation
the dissipation of the IC heat needs to be doubled for
two-channel operation. Given θJA, the maximum allow-
(14) states the maximum power dissipation point for a
SE mode operating at a given supply voltage and driving
able junction temperature (TJMAX), and the total internal
dissipation (PD), the maximum ambient temperature can
a specified load.
be calculated with the following equation. The maximum
recommended junction temperature for the APA2071 is
SE mode: PD, MAX =
VDD2
2π2RL
(12)
150°C. The internal dissipation figures are taken from
the Power Dissipation vs. Output Power graphs.
In BTL mode operation, the output voltage swing is
doubled as in SE mode. Thus, the maximum power dis-
TAMax = TJMax -θJAPD
150 - 45(0.8*2) = 78°C
sipation point for a BTL mode operating at the same given
conditions is 4 times as in SE mode.
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
(15)
19
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APA2071
Application Information (Cont.)
Thermal Consideration (Cont.)
The APA2071 is designed with a thermal shutdown protection that turns the device off when the junction temperature surpasses 150°C to prevent damaging the IC.
Layout Consideration
Via diameter
=0.3mm x 24
4mm
3mm
20mm
Ground plane
for GND pin
16mm
Figure 5: APA 2071 Land Pattern Recommendation
1. All components should be placed close to the APA2071.
For example, the input capacitor (Ci) should be close
to APA2071’s input pins to avoid causing noise coupling to APA2071’s high impedance inputs; the
decoupling capacitor (CS) should be placed by the
APA2071’s power pin to decouple the power rail noise.
2. The output traces should be short, wide (>50mil), and
symmetric.
3. The input trace should be short and symmetric.
4. The power trace width should be greater than 50mil.
5. The APA2071’s GND pin should be soldered on ground
plane of the PCB.
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2008
20
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APA2071
Package Information
DIP-16
E1
D
0.38
A
L
A1
A2
E
b
D1
b2
e
c
eA
eB
S
Y
M
B
O
L
DIP-16
MILLIMETERS
MIN.
INCHES
MIN.
MAX.
A
MAX.
0.210
5.33
0.015
A1
0.38
A2
2.92
4.95
0.115
0.195
b
0.36
0.56
0.014
0.022
0.070
b2
1.14
1.78
0.045
c
0.20
0.35
0.008
0.014
D
18.6
20.31
0.732
0.800
D1
0.13
E
7.62
8.26
0.300
0.325
E1
6.10
7.11
0.240
0.280
0.005
e
2.54 BSC
0.100 BSC
eA
7.62 BSC
0.300 BSC
eB
L
0.430
10.92
2.92
0.115
3.81
0.150
Note : 1. Followed from JEDEC MS-001AB
2. Dimension D, D1 and E1 do not include mold flash or
protrusions. Mold flash or protrusions shall not exceed
10 mil.
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Package Information
DIP-16A
E1
D
L
A1
0.38
A
A2
E
b
D1
b2
e
c
eA
eB
S
Y
M
B
O
L
DIP-16A
MILLIMETERS
MIN.
INCHES
MAX.
A
MIN.
MAX.
5.33
0.210
0.015
A1
0.38
A2
2.92
4.95
0.115
0.195
b
0.36
0.56
0.014
0.022
b2
1.14
1.78
0.045
0.070
0.014
0.800
c
0.20
0.35
0.008
D
18.6
20.31
0.732
D1
0.13
E
7.62
8.26
0.300
0.325
E1
6.10
7.11
0.240
0.280
0.005
e
2.54 BSC
0.100 BSC
eA
7.62 BSC
0.300 BSC
eB
L
0.430
10.92
2.92
0.115
3.81
0.150
Note : 1. Followed from JEDEC MS-001AB
2. Dimension D, D1 and E1 do not include mold flash or
protrusions. Mold flash or protrusions shall not exceed
10 mil.
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Reflow Condition
(IR/Convection or VPR Reflow)
tp
TP
Critical Zone
TL to TP
Temperature
Ramp-up
TL
tL
Tsmax
Tsmin
Ramp-down
ts
Preheat
25
t 25°C to Peak
Time
Reliability Test Program
Test item
SOLDERABILITY
HOLT
PCT
TST
ESD
Latch-Up
Method
MIL-STD-883D-2003
MIL-STD-883D-1005.7
JESD-22-B, A102
MIL-STD-883D-1011.9
MIL-STD-883D-3015.7
JESD 78
Description
245°C, 5 sec
1000 Hrs Bias @125°C
168 Hrs, 100%RH, 121°C
-65°C~150°C, 200 Cycles
VHBM > 2KV, VMM > 200V
10ms, 1tr > 100mA
Classification Reflow Profiles
Profile Feature
Average ramp-up rate
(TL to TP)
Preheat
- Temperature Min (Tsmin)
- Temperature Max (Tsmax)
- Time (min to max) (ts)
Time maintained above:
- Temperature (TL)
- Time (tL)
Peak/Classification Temperature (Tp)
Time within 5°C of actual
Peak Temperature (tp)
Ramp-down Rate
Sn-Pb Eutectic Assembly
Pb-Free Assembly
3°C/second max.
3°C/second max.
100°C
150°C
60-120 seconds
150°C
200°C
60-180 seconds
183°C
60-150 seconds
217°C
60-150 seconds
See table 1
See table 2
10-30 seconds
20-40 seconds
6°C/second max.
6°C/second max.
6 minutes max.
8 minutes max.
Time 25°C to Peak Temperature
Note: All temperatures refer to topside of the package. Measured on the body surface.
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Classification Reflow Profiles (Cont.)
Table 1. SnPb Eutectic Process – Package Peak Reflow Temperatures
3
Package Thickness
Volume mm
<350
<2.5 mm
240 +0/-5°C
≥2.5 mm
225 +0/-5°C
3
Volume mm
≥350
225 +0/-5°C
225 +0/-5°C
Table 2. Pb-free Process – Package Classification Reflow Temperatures
3
3
3
Package Thickness
Volume mm
Volume mm
Volume mm
<350
350-2000
>2000
<1.6 mm
260 +0°C*
260 +0°C*
260 +0°C*
1.6 mm – 2.5 mm
260 +0°C*
250 +0°C*
245 +0°C*
≥2.5 mm
250 +0°C*
245 +0°C*
245 +0°C*
*Tolerance: The device manufacturer/supplier shall assure process compatibility up to and including the
stated classification temperature (this means Peak reflow temperature +0°C. For example 260°C+0°C)
at the rated MSL level.
Customer Service
Anpec Electronics Corp.
Head Office :
No.6, Dusing 1st Road, SBIP,
Hsin-Chu, Taiwan
Tel : 886-3-5642000
Fax : 886-3-5642050
Taipei Branch :
2F, No. 11, Lane 218, Sec 2 Jhongsing Rd.,
Sindian City, Taipei County 23146, Taiwan
Tel : 886-2-2910-3838
Fax : 886-2-2917-3838
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Rev. A.3 - Nov., 2008
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