BCD AP1662P-E1 High performance power factor corrector Datasheet

Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
General Description
Features
The AP1662 is an active power factor control IC
which is designed mainly for use as a pre-converter
in electronic ballast, AC-DC adapter and off-line
SMPS applications.
.
The IC includes an internal start-up timer for
stand-alone applications, a one-quadrant multiplier to
realize near unity power factor and a zero current
detector to ensure DCM boundary conduction
operation.
•
•
•
The totem pole output stage is capable of driving
power MOSFET with 600mA source current and
800mA sink current.
•
•
•
•
•
•
•
Designed with advanced BiCMOS process, the
AP1662 features low start-up current, low operation
current and low power dissipation. The AP1662 also
has rich protection features including over-voltage
protection, input under-voltage lockout with
hysteresis and multiplier output clamp to limit
maximum peak current.
•
AP1662
Comply with IEC61000-3-2 Standard
Proprietary Design for Minimum THD
Zero Current Detection Control for DCM
Boundary Conduction Mode
Adjustable Output Voltage with Precise
Over-voltage Protection
Low Start-up Current with 40µA Typical Value
Low Quiescent Current with 2.5mA Typical
Value
1% Precision Internal Reference Voltage @
TJ=25°C
Internal Start-up Timer
Disable Function for Reduced Current
Consumption
Totem Pole Output with 600mA Source and
800mA Sink Current Capability
Under-voltage Lockout with 2.5V Hysteresis
Applications
•
•
•
•
The AP1662 meets IEC61000-3-2 standard even at
one-quadrant load and THD lower than 10% at
high-end line voltage and full load.
Electronic Ballast
AC-DC Adapter
Off-line SMPS
Single Stage PFC LED Driver
The IC is available in SOIC-8 and DIP-8 packages.
SOIC-8
DIP-8
Figure 1. Package Types of AP1662
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
1
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Pin Configuration
M Package
(SOIC-8)
INV
1
8
VCC
COMP
2
7
GD
MULT
3
6
GND
CS
4
5
ZCD
P Package
(DIP-8)
INV
1
8
VCC
COMP
2
7
GD
MULT
3
6
GND
CS
4
5
ZCD
Figure 2. Pin Configuration of AP1662 (Top View)
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
2
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Pin Description
Pin Number
Pin Name
Function
1
INV
2
COMP
Output of the error amplifier
3
MULT
Input of the multiplier
4
CS
5
ZCD
6
GND
7
GD
8
VCC
Inverting input of the error amplifier
Input of the current control loop comparator
Zero current detection input. If it is connected to GND, the
device is disabled
Ground. Current return for gate driver and control circuits of
the IC
Gate driver output
Supply voltage of gate driver and control circuits of the IC
Functional Block Diagram
COMP
INV
MULT
2
1
CS
3
4
40 K
Multiplier
Overvoltage
Detection
Voltage
Regulation
VCC
10 pF
VCC
8
R
S
Internal
R1 Supply 7.5V
24V
Q
7
UVLO
Driver
R2
GD
Vref
Zero Current
Detector
2.1V
1.6V
Starter
Enable
Disable
6
5
GND
ZCD
Figure 3. Functional Block Diagram of AP1662
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
3
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Ordering Information
AP1662
Circuit Type
E1: Lead Free
G1: Green
Package
M: SOIC-8
P: DIP-8
Blank: Tube
TR: Tape & Reel
Package
Temperature
Range
SOIC-8
-40 to 105°C
DIP-8
-
-40 to 105°C
Part Number
Lead Free
Green
Marking ID
Lead Free
Green
Packing
Type
AP1662M-E1
AP1662M-G1
1662M-E1
1662M-G1
Tube
AP1662MTR-E1
AP1662MTR-G1
1662M-E1
1662M-G1
Tape & Reel
AP1662P-E1
AP1662P-G1
AP1662P-E1
AP1662P-G1
Tube
BCD Semiconductor's Pb-free products, as designated with "E1" suffix in the part number, are RoHS compliant.
Products with “G1” suffix are available in green packages.
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
4
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Absolute Maximum Ratings (Note 1)
Parameter
Power Supply Voltage
Operating Supply Current
Input/Output of Error Amplifier,
Input of Multiplier
Current Sense Input
Symbol
Value
Unit
VCC
Self-limited
V
ICC
VINV, VCOMP,
VMULT
VCS
30
mA
-0.3 to 7
V
-0.3 to 7
V
Zero Current Detector Input
IZCD
Power Dissipation and Thermal
characteristics @ TA=50°C
PTOT
Thermal Resistance
(Junction to Ambient)
RθJA
Source
-50
Sink
10
DIP-8
1
SOIC-8
0.65
DIP-8
100
SOIC-8
150
mA
W
ºC/W
Operating Junction Temperature
TJ
-40 to 150
ºC
Storage Temperature Range
Lead Temperature (Soldering, 10
Seconds)
ESD (Human Body Model)
TSTG
-65 to 150
ºC
TLEAD
260
ºC
VESD(HBM)
3000
V
ESD (Machine Model)
VESD(MM)
200
V
Note 1: Stresses greater than those listed under “Absolute Maximum Ratings” may cause permanent damage to
the device. These are stress ratings only, and functional operation of the device at these or any other conditions
beyond those indicated under “Recommended Operating Conditions” is not implied. Exposure to “Absolute
Maximum Ratings” for extended periods may affect device reliability.
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
5
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Electrical Characteristics
VCC =12V, TJ =-25°C to 125°C, CO=1nF, unless otherwise specified.
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
Under Voltage Lockout Section
Turn-on Threshold
VCC-ON
VCC Rising
11
12
13
V
Turn-off Threshold
VCC-OFF
VCC Falling
8.7
9.5
10.3
V
Hysteresis
VCC-HYS
2.2
2.5
2.8
V
22
V
VCC Operating Range
VCC
After turn-on
Zener Voltage
VZ
ICC=20mA
10.3
22
24
V
Total Supply Current Section
Start-up Current
ISTART-UP
VCC=11V before turn-on
40
70
µA
Frequency=70kHz
3.5
5
Operating Supply Current
ICC
In OVP condition
VINV =2.7V
1.4
2.2
Quiescent Current
IQ
After turn on
2.5
3.75
mA
Quiescent Current
IQ
2.2
mA
µA
VZCD≤150mV, VCC>VCC-OFF
VZCD≤150mV, VCC<VCC-OFF
20
50
90
2.465
2.5
2.535
mA
Error Amplifier Section
Voltage Feedback Input
Threshold
VINV
Line Regulation
TJ =25ºC
10.3V<VCC<20V
VCC=10.3V to 20V
Input Bias Current
IINV
VINV=0 to 3V
Voltage Gain
GV
Open Loop
Gain Bandwidth
GB
Output
Voltage
Output
Current
May. 2011
Upper Clamp
Voltage
Low Clamp
Voltage
Source
Current
Sink Current
2.44
60
2.56
2
5
mV
-0.1
-1
µA
80
dB
1
MHz
VCOMP-H
ISOURCE=0.5mA
5.8
VCOMP-L
ISINK=0.5mA
2.25
ICOMP-H
VCOMP=4V, VINV =2.4V
-2
-4
ICOMP-L
VCOMP=4V, VINV=2.6V
2.5
4.5
Rev. 1. 0
V
V
-8
mA
BCD Semiconductor Manufacturing Limited
6
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Electrical Characteristics (Continued)
VCC =12V, TJ =-25°C to 125°C, CO=1nF, unless otherwise specified.
Parameter
Symbol
Test Conditions
Min
Typ
0 to 3
0 to
3.5
VMULT: 0 to 0.5V,
VCOMP=Upper Clamp Voltage
1.65
1.9
VMULT=1V, VCOMP=4V
0.6
0.75
Max
Unit
Multiplier Section
Linear Input Voltage
Range
Output Maximum
Slope
VMULT
△ VCS/
△VMULT
Gain
k
V
0.9
1/V
-1
µA
Current Sense Section
Input Bias Current
Current Sense Offset
Voltage
Current Sense
Reference Clamp
Delay to Output
ICS
VCS-OFFSET
VCS-CLAMP
VCS=0V
VMULT=0V
VMULT=2.5V
VCOMP = Upper Clamp
Voltage, VMULT = 2.5V
30
5
1.6
td(H-L)
mV
1.7
1.8
V
200
350
ns
Zero Current Detection Section
Arming Voltage
(positive-going edge)
Triggering Voltage
(negative-going edge)
VZCDA
(Note 2)
2.1
V
VZCDT
(Note 2)
1.6
V
Upper Clamp Voltage
VZCD-H
Lower Clamp Voltage
VZCD-L
Source Current
Capability
Sink Current
Capability
IZCD=20µA
4.5
5.1
5.9
IZCD=3mA
4.7
5.2
6.1
IZCD= -3mA
0.3
0.65
1
V
-10
mA
IZCD-SR
-2.5
IZCD-SN
3
Sink Bias Current
IZCD-B
Disable Threshold
VZCD-DIS
Disable Hysteresis
VZCD-HYS
Restart Current After
Disable
IZCD-RES
1V ≤ VZCD ≤ 4.5 V
VZCD<VDIS, VCC>VCC-OFF
mA
µA
2
150
-80
V
200
250
mV
100
mV
-120
µA
Note 2: Limits over the full temperature are guaranteed by design, but not tested in production.
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
7
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Electrical Characteristics (Continued)
VCC =12V, TJ =-25°C to 125°C, CO=1nF, unless otherwise specified.
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
IGD-SOURCE=200mA
2.5
3
IGD-SOURCE=20mA
2
2.8
IGD-SINK=200mA
0.9
1.9
tR
40
80
ns
tF
30
70
ns
11
13
V
1.1
V
Drive Output Section
VOH
Dropout Voltage
VOL
Output
Time
Voltage
Rise
Output Voltage Fall Time
Output Clamp Voltage
UVLO Saturation
VO-CLAMP
VOS
IGD-SOURCE=5mA
VCC=20V
VCC=0 to VCC-ON,
ISINK=10mA
9
V
Output Over Voltage Section
OVP Triggering Current
Static OVP Threshold
IOVP
35
40
45
µA
VOVP_TH
2.1
2.25
2.4
V
tSTART
75
130
300
µs
Starter
Start Timer Period
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
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Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Typical Performance Characteristics
3.0
12.5
12.0
2.5
VCC-ON
Voltage (V)
Supply Current (mA)
11.5
2.0
1.5
CO=1nF
f=70kHz
o
TJ=25 C
1.0
11.0
10.5
10.0
0.5
9.5
0.0
0
5
10
15
20
9.0
-50
25
Supply Voltage (V)
VCC-OFF
0
50
100
150
o
Junction Temperature ( C)
Figure 4. Supply Current vs. Supply Voltage
Figure 5. Start-up & UVLO vs. TJ
28
8
4
Quiescent
27
26
1
0.5
0.25
Disabled or during OVP
VCC=12V
CO=1nF
f=70kHz
VCC-CLAMP (V)
ICC (mA)
2
0.125
Before start-up
0.0625
25
24
23
0.03125
-50
0
50
100
22
-50
150
o
50
100
150
o
Figure 6. ICC Consumption vs. TJ
May. 2011
0
Junction Temperature ( C)
Junction Temperature ( C)
Figure 7. VCC Zener Voltage vs. TJ
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
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Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Typical Performance Characteristics (Continued)
2.60
43.0
42.5
VCC=12V
VCC=12V
2.55
42.0
IOVP (µA)
VREF (V)
41.5
2.50
2.45
41.0
40.5
40.0
39.5
2.40
-50
0
50
100
39.0
-50
150
0
O
50
100
150
o
Junction Temperature ( C)
Junction Temperature ( C)
Figure 8. Feedback Reference Voltage vs. TJ
Figure 9. OVP Current vs. TJ
500
6.0
5.5
VCC=12V
400
Upper Clamp
5.0
VCOMP (V)
td(H-L) (ns)
VCC=12V
4.5
300
200
4.0
3.5
3.0
100
Lower Clamp
2.5
0
-50
0
50
100
2.0
-50
150
o
50
100
150
o
Junction Temperature ( C)
Junction Temperature ( C)
Figure 10. Delay-to-Output vs. TJ
May. 2011
0
Figure 11. E/A Output Clamp Levels vs. TJ
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
10
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
2.0
1.0
1.8
0.8
Multiplier Gain
VCS-CLAMP (V)
Typical Performance Characteristics (Continued)
1.6
1.4
VCC=12V
VCOMP=Upper Clamp
1.2
1.0
-50
0
50
100
VCC=12V
VCOMP=4V
VMULT=1V
0.6
0.4
0.2
0.0
-50
150
0
o
50
100
150
o
Junction Temperature ( C)
Junction Temperature ( C)
Figure 12. VCS-CLAMP vs. TJ
Figure 13. Multiplier Gain vs. TJ
0
7
VCC=12V
VZCD=Lower Clamp
-2
6
Upper Clamp
VZCD (V)
IZCD (mA)
5
-4
VCC=12V
IZCD= + 2.5mA
4
3
2
-6
Lower Clamp
1
-8
-50
0
50
100
0
-50
150
o
50
100
150
o
Junction Temperature ( C)
Junction Temperature ( C)
Figure 14. ZCD Source Capability vs. TJ
May. 2011
0
Figure 15. ZCD Clamp Levels vs. TJ
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
11
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Typical Performance Characteristics (Continued)
200
1.8
VCC=12V
VCOMP=MAX
VCOMP=5.0
VCOMP=4.5
1.6
VCOMP=3.5
VCOMP=4.0
180
1.4
170
1.2
VCS (V)
tSTART (µS)
190
160
VCOMP=3.2
1.0
0.8
VCOMP=3.0
150
0.6
140
0.4
VCOMP=2.8
130
0.2
120
-50
0.0
0.0
0
50
100
150
VCOMP=2.6
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
VMULT (V)
o
Junction Temperature ( C)
Figure 16. Start-up Timer vs. TJ
Figure 17. Multiplier Characteristics
VGD (V)
6
VCC-2.0
5
VGD (V)
4
o
TJ=25 C
VCC=11V
SOURCE
VCC-2.5
o
TJ=25 C
VCC=11V
SINK
VCC-3.0
3
VCC-3.5
2
VCC-4.0
1
0
0
200
400
600
800
1000
0
IGD (mA)
200
300
400
500
600
700
IGD (mA)
Figure 18. Gate-driver Output Low Saturation
May. 2011
100
Figure 19. Gate-driver Output High Saturation
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
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Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Typical Performance Characteristics (Continued)
15
1.1
VCC=0V
1.0
14
VCC=20V
VGD_OFF (V)
VGD_CLAMP (V)
0.9
13
12
0.8
0.7
11
0.6
10
-50
0
50
100
0.5
-50
150
50
100
150
Junction Temperature ( C)
Junction Temperature ( C)
Figure 20. Gate-driver Clamp vs. TJ
May. 2011
0
o
o
Figure 21. UVLO Saturation vs. TJ
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
13
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
disabled and the drive signal is stopped. If the output
over voltage lasts so long that the output of error
amplifier goes below 2.25V, static OVP will take
place. Also the IC will be disabled until the output of
error amplifier goes back to its linear region. R1 and
R2 (see Fig. 22) will be selected as below:
Functional Block Description
AP1662 is a high performance power factor
correction controller which operates in DCM
boundary conduction mode. The PFC converter's
switch will be turned on when the inductor current
reduces to zero and turned off when the sensed
inductor current reaches the required reference which
is decided by the output of multiplier.
Error Amplifier
Protection
and
AP1662
R1
V
= O −1
R 2 2.5V
Over-Voltage
R1 =
The error amplifier regulates the PFC output voltage.
The internal reference on the non-inverting input of
the error amplifier is 2.5V. The error amplifier's
inverting input (INV) is connected to an external
resistor divider which senses the output voltage. The
output of error amplifier is one of the two inputs of
multiplier. A compensation loop is connected outside
between INV and the error amplifier output.
Normally, the compensation loop bandwidth is set
very low to realize high power factor for PFC
converter.
∆VOVP
40µA
Multiplier
The multiplier has two inputs. One (Pin 3) is the
divided AC sinusoidal voltage which makes the
current sense comparator threshold voltage vary from
zero to peak value. The other input is the output of
error amplifier (Pin 2). In this way, the input average
current wave will be sinusoidal as well as reflects the
load status. Accordingly a high power factor and
good THD are achieved. The multiplier transfer
character is designed to be linear over a wide
dynamic range, namely, 0V to 3V for Pin 3 and 2V to
5.8V for Pin 2. The relationship between the
multiplier output and inputs is described as below
equation:
VCS = k × (VCOMP − 2.5) × VMULT
where VCS (Multiplier output) is the reference for the
current sense, k is the multiplier gain, VCOMP is the
voltage on pin 2 (error amplifier output) and VMULT is
the voltage on pin 3.
To make the over voltage protection fast, the internal
OVP function is added. If the output over voltage
happens, excess current will flow into the output pin
of the error amplifier through the feedback
compensation capacitor. (see Figure 22) The AP1662
monitors the current flowing into the error amplifier
output pin. When the detected current is higher than
40µA, the dynamic OVP is triggered. The IC will be
Current
Sense/Current
Comparator
Sense
The PFC switch's turn-on current is sensed through
an external resistor in series with the switch. When
the sensed voltage exceeds the threshold voltage (the
multiplier output), the current sense comparator will
become low and the external MOSFET will be turned
off. This insures a cycle-by-cycle current mode
control operation. The maximum current sense
reference is 1.8V. The max value usually happens at
startup process or abnormal conditions such as short
load.
Figure 22. Error Amplifier and OVP Block
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
14
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
ZCD pin voltage decreases below 1.6V, the gate
drive signal becomes high to turn on the external
MOSFET. 500mV of hysteresis is provided to avoid
false triggering. The ZCD pin can be used for
disabling the IC. Making its voltage below 0.15V or
short to the ground will disable the device thus
reduce the IC supply current consumption.
Functional Block Description
(Continued)
Zero Current Detection
AP1662 is a DCM boundary conduction current
mode PFC controller. Usually, the zero current
detection (ZCD) voltage signal comes from the
auxiliary winding of the boost inductor. When the
Typical Application
Figure 23. 85 to 265V Wide Range Input 90W PFC Demo Board Electrical Schematic Circuit
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
15
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Mechanical Dimensions
SOIC-8
4.700(0.185)
5.100(0.201)
7°
Unit: mm(inch)
0.320(0.013)
1.350(0.053)
1.750(0.069)
8°
8°
7°
0.675(0.027)
0.725(0.029)
D
5.800(0.228)
1.270(0.050)
6.200(0.244)
TYP
D
20:1
0.800(0.031)
0.300(0.012)
R0.150(0.006)
0.100(0.004)
0.200(0.008)
0°
8°
1.000(0.039)
3.800(0.150)
4.000(0.157)
0.330(0.013)
0.190(0.007)
0.250(0.010)
1°
5°
0.510(0.020)
0.900(0.035)
R0.150(0.006)
0.450(0.017)
0.800(0.031)
Note: Eject hole, oriented hole and mold mark is optional.
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
16
Preliminary Datasheet
HIGH PERFORMANCE POWER FACTOR CORRECTOR
AP1662
Mechanical Dimensions (Continued)
DIP-8
Unit: mm(inch)
0.700(0.028)
7.620(0.300)TYP
1.524(0.060) TYP
6°
5°
6°
3.200(0.126)
3.600(0.142)
3.710(0.146)
4.310(0.170) 4°
4
0.510(0.020)MIN
3.000(0.118)
3.600(0.142)
0.204(0.008)
0.360(0.014)
8.200(0.323)
9.400(0.370)
0.254(0.010)TYP
2.540(0.100) TYP
0.360(0.014)
0.560(0.022)
0.130(0.005)MIN
6.200(0.244)
6.600(0.260)
R0.750(0.030)
Φ3.000(0.118)
Depth
0.100(0.004)
0.200(0.008)
9.000(0.354)
9.400(0.370)
Note: Eject hole, oriented hole and mold mark is optional.
May. 2011
Rev. 1. 0
BCD Semiconductor Manufacturing Limited
17
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IMPORTANT
NOTICE
BCD Semiconductor
BCD
Semiconductor Manufacturing
Manufacturing Limited
Limited reserves
reserves the
the right
right to
to make
make changes
changes without
without further
further notice
notice to
to any
any products
products or
or specifispecifications herein.
cations
herein. BCD
BCD Semiconductor
Semiconductor Manufacturing
Manufacturing Limited
Limited does
does not
not assume
assume any
any responsibility
responsibility for
for use
use of
of any
any its
its products
products for
for any
any
particular purpose,
particular
purpose, nor
nor does
does BCD
BCD Semiconductor
Semiconductor Manufacturing
Manufacturing Limited
Limited assume
assume any
any liability
liability arising
arising out
out of
of the
the application
application or
or use
use
of any
of
any its
its products
products or
or circuits.
circuits. BCD
BCD Semiconductor
Semiconductor Manufacturing
Manufacturing Limited
Limited does
does not
not convey
convey any
any license
license under
under its
its patent
patent rights
rights or
or
other rights
other
rights nor
nor the
the rights
rights of
of others.
others.
MAIN SITE
SITE
MAIN
- Headquarters
BCD
Semiconductor Manufacturing Limited
BCD
Semiconductor
Manufacturing Limited
- Wafer
Fab
No.
1600, Zi
Xing Road,
Shanghai ZiZhu
Science-basedLimited
Industrial Park, 200241, China
Shanghai
SIM-BCD
Semiconductor
Manufacturing
Tel:
Fax: +86-21-24162277
800,+86-21-24162266,
Yi Shan Road, Shanghai
200233, China
Tel: +86-21-6485 1491, Fax: +86-21-5450 0008
REGIONAL SALES OFFICE
Shenzhen OfficeSALES OFFICE
REGIONAL
- Wafer
FabSemiconductor Manufacturing Limited
BCD
Shanghai
SIM-BCD
Semiconductor Manufacturing Co., Ltd.
- IC Design
Group
800 Yi
Shan Road,
Shanghai
200233,
China Corporation
Advanced
Analog
Circuits
(Shanghai)
Tel: +86-21-6485
1491,YiFax:
0008200233, China
8F, Zone B, 900,
Shan+86-21-5450
Road, Shanghai
Tel: +86-21-6495 9539, Fax: +86-21-6485 9673
Taiwan Office
Shanghai
Semiconductor Manufacturing Co., Ltd., Shenzhen Office
BCD Taiwan
Semiconductor
Shenzhen SIM-BCD
Office
Office (Taiwan) Company Limited
Unit
A Room
1203, Skyworth
Bldg., Gaoxin
Ave.1.S., Nanshan
Shenzhen,
4F, 298-1,
Guang Road,(Taiwan)
Nei-Hu District,
Taipei,
Shanghai
SIM-BCD
Semiconductor
Manufacturing
Co., Ltd.District,
Shenzhen
Office
BCDRui
Semiconductor
Company
Limited
China
Taiwan
Advanced Analog Circuits (Shanghai) Corporation Shenzhen Office
4F, 298-1, Rui Guang Road, Nei-Hu District, Taipei,
Tel:
+86-755-8826
Tel: +886-2-2656
2808
Room
E, 5F, Noble 7951
Center, No.1006, 3rd Fuzhong Road, Futian District, Shenzhen 518026, China
Taiwan
Fax:
+86-755-88267951
7865
Fax: +886-2-2656
28062808
Tel: +86-755-8826
Tel: +886-2-2656
Fax: +86-755-8826 7865
Fax: +886-2-2656 2806
USA Office
BCD Office
Semiconductor Corp.
USA
30920Semiconductor
Huntwood Ave.Corporation
Hayward,
BCD
CA 94544,
USA Ave. Hayward,
30920
Huntwood
Tel :94544,
+1-510-324-2988
CA
U.S.A
Fax:: +1-510-324-2988
+1-510-324-2788
Tel
Fax: +1-510-324-2788
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