POWERINT RDR-83

Title
Reference Design Report for 1.6 W,
Linear Replacement Adapter with 10 kV
surge withstand
Specification 85–265 VAC Input, 7.7 V, 210 mA Output
Application
Cordless Phone Adapter
Author
Power Integrations Applications Department
Document
Number
RDR-83
Date
Sept 29, 2006
Revision
1.0
Summary and Features
• Highly efficient, low cost switching solution
• Replacement for existing AC line transformer based design
• Designed to withstand 10 kV common-mode surges
• Ideal for applications connected to telephone network
• EcoSmart® – meets all existing and proposed harmonized energy efficiency
standards including: CECP (China), CEC, EPA, AGO, European Commission
• No-load power consumption <220 mW at 265 VAC
• 61.3% active-mode efficiency (exceeds requirement of 53.2%)
• Integrated LinkSwitch safety/reliability features:
• Accurate (± 5%), auto-recovering, hysteretic thermal shutdown function
maintains safe PCB temperatures under all conditions
• Auto-restart protects against output short circuits and open feedback loops
• Meets EN55022 and CISPR-22 Class B conducted EMI with >15 dBµV margin
• Meets IEC61000-4-5 Class 4 AC line surge
The products and applications illustrated herein (including circuits external to the products and transformer
construction) may be covered by one or more U.S. and foreign patents or potentially by pending U.S. and foreign
patent applications assigned to Power Integrations. A complete list of Power Integrations’ patents may be found at
www.powerint.com.
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
Table Of Contents
1
2
Introduction.................................................................................................................3
Power Supply Specification ........................................................................................4
2.1
Typical Output Characteristic and limits ..............................................................5
3 Schematic...................................................................................................................6
4 Circuit Description ......................................................................................................7
4.1
Input Stage ..........................................................................................................7
4.2
LinkSwitch-LP......................................................................................................7
4.3
Feedback.............................................................................................................8
4.4
Output Rectification .............................................................................................9
5 PCB Layout ..............................................................................................................10
6 Bill Of Materials ........................................................................................................11
7 Transformer Specification.........................................................................................12
7.1
Electrical Diagram .............................................................................................12
7.2
Electrical Specifications.....................................................................................12
7.3
Materials............................................................................................................12
7.4
Transformer Build Diagram ...............................................................................13
7.5
Transformer Construction..................................................................................13
8 Design Spreadsheets ...............................................................................................14
9 Performance Data ....................................................................................................19
9.1
Efficiency ...........................................................................................................19
9.1.1
Active Mode ENERGY STAR / CEC Efficiency Measurement Data...........20
9.2
No-load Input Power..........................................................................................21
9.3
Available Standby Output Power.......................................................................21
9.4
Regulation .........................................................................................................22
9.4.1
VI Curve vs. Input Voltage..........................................................................22
10
Thermal Performance ...........................................................................................23
10.1 LNK562 Temperature Rise................................................................................23
10.2 Thermal Image ..................................................................................................23
11
Waveforms............................................................................................................24
11.1 Drain Voltage and Current, Normal Operation...................................................24
11.2 Output Voltage Start-up Profile..........................................................................24
11.3 Drain Voltage and Current Start-up Profile ........................................................25
11.4 Load Transient Response (50% to 100% Load Step) .......................................26
11.5 Output Ripple Measurements............................................................................27
11.5.1 Ripple Measurement Technique ................................................................27
11.5.2 Measurement Results ................................................................................28
12
Line Surge.............................................................................................................29
13
Conducted EMI .....................................................................................................30
14
Revision History ....................................................................................................32
Important Note:
Although this board is designed to satisfy safety isolation requirements, the engineering prototype
has not been agency approved. Therefore, all testing should be performed using an isolation
transformer to provide the AC input to the prototype board.
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 2 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
1 Introduction
This reference design report describes a switched-mode power supply that was designed
to replace line frequency transformer based solutions. The supply uses a member of the
LinkSwitch-LP family of devices, and is capable of withstanding common-mode line
surges of up to 10 kV. That is often a requirement for applications that connect to a
telephone line, such as modems, cordless phones and answering machines.
The report includes the power supply specification, a circuit diagram, a bill of materials,
transformer documentation, a printed circuit layout board, and performance data.
Figure 1 – Populated Circuit Board Photograph.
Page 3 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
2 Power Supply Specification
Description
Input
Voltage
Frequency
No-load Input Power (230 VAC)
Output
Output Voltage 1
Output Ripple Voltage 1
Output Current 1
Total Output Power
Continuous Output Power
No Load Output Voltage
Efficiency
Full Load
Required average efficiency at
25, 50, 75 and 100 % of POUT
Symbol
Min
Typ
Max
Units
Comment
VIN
fLINE
85
47
265
64
0.3
VAC
Hz
W
2 Wire – no P.E.
50/60
VOUT1
VRIPPLE1
IOUT1
6.7
7.7
8.7
400
0.21
0.21
V
mV
A
POUT
1.4
1.6
11
20 MHz bandwidth
W
V
η
60
%
Measured at POUT 25 C
ηCEC
53
%
Per ENERGY STAR / CEC
requirements
o
Environmental
Conducted EMI
Meets CISPR22B / EN55022B
Designed to meet IEC950, UL1950
Class II
Safety
Surge
Differential Mode
Common Mode
2
6
Surge
kV
kV
10
2
Ambient Temperature
TAMB
0
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
KV
50
o
C
1.2/50 µs surge, IEC 1000-4-5,
Series Impedance:
Differential Mode: 2 Ω
Common Mode: 12 Ω
100 kHz ring wave, 500 A short
circuit current, differential
Free convection, sea level
Page 4 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
2.1 Typical Output Characteristic and Limits
The following diagram shows the output characteristic of the LinkSwitch-LP solution and
that of the linear transformer solution it was designed to replace. As can be seen, the
LinkSwitch-LP solution provides a more controlled output characteristic.
18
115 VAC
UPPER LIMIT
LOWER LIMIT
Linear Adapter
RD-83 115 VAC
16
14
Volts
12
10
8
6
4
2
0
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Amps
Figure 2 – Output Characteristic Comparison and Limits.
Page 5 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
3 Schematic
Figure 3 – Schematic.
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 6 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
4 Circuit Description
4.1 Input Stage
Components C1, C6, L1 and L3 comprise a balanced π filter. Resistor R5 dampens low
frequency conducted EMI. The supply needs no Y1-type capacitor (that normally bridges
the primary to secondary isolation barrier) due to U1’s frequency jitter function and the
E-Shield™ techniques used in the design of transformer T1. This minimizes audible
noise in applications connected to a phone line, by eliminating a path for line frequency
leakage currents to pass onto the output of the supply. The supply easily meets
EN55022B conducted EMI limits, with more than 15 dBµV of margin.
A metal oxide varistor (RV1) and a wire wound resistor (RF1) attenuate differential line
surges. The varistor is required to meet the 2 kV differential surge requirement. In
applications where only 1 kV of surge immunity is required, RV1 can be eliminated. The
wire wound resistor (RF1) must be able to withstand high transient dissipation from initial
inrush current (when AC power is applied) and during line surges.
4.2 LinkSwitch-LP
The LinkSwitch-LP family of ICs were designed to replace linear transformer solutions in
low-power charger and adapter applications. Feedback to the LNK562P IC (U1) is
derived from a resistor divider (R1 and R2) across the bias supply (D3 and C3), which
lowers cost by eliminating the need for an optocoupler.
Linear transformers typically use thermal fuses (over temperature cut-outs) for overload
protection. However, once a thermal fuse trips, the entire charger or adapter must be
thrown away, since thermal fuses cannot be reset or repaired. Latching thermal
shutdown functions are typically used in ringing choke converter (RCC) based supplies.
However, AC input power must be removed and reapplied to reset most thermal latches.
Since customers typically don’t know this, they often return good units they thought were
defective, simply because the thermal latch tripped and shut the unit off. The LinkSwitchLP family’s hysteretic thermal shutdown function has a very tight tolerance (142 °C,
±5%), and automatically restarts the power supply once the IC temperature drops below
the lower temperature threshold. This maintains the average PCB temperature at a safe
level under all conditions, and reduces the return rate of good units from the field. The
auto-recovery feature also eliminates the noise sensitivity and component aging
problems associated with discrete latching circuits.
Pin 6 is eliminated from the IC package to extend the creepage distance between the
DRAIN pin and all other low voltage pins; both at the package and on the PCB. This
reduces the likelihood that tracking or arcing will occur due to moisture or board surface
contamination (from dust and dirt), which improves reliability in high humidity and high
pollution environments. During an output short circuit or an open loop condition, the
LinkSwitch-LP’s auto-restart function limits output power to about 12% of the maximum.
This protects both the load and the supply during prolonged overload conditions.
Page 7 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
The LinkSwitch-LP family of ICs are self-biased, via a high-voltage current source that is
internally connected to the DRAIN pin of the package. A capacitor (C2) connected to the
BYPASS (BP) pin of the IC provides energy storage and local decoupling of the internal
chip power. To further reduce no-load power consumption, a resistor can be used to
provide operating current to the IC from the bias winding (once the power supply is
operating). In this design, the bias winding voltage is about 14 V and the BP pin voltage
is 5.8 V. Therefore, R6 (100 kΩ) provides about 80 µA of current to the BP pin. If the
value of R6 were reduced, it could provide the entire 220 µA of IC supply current, which
would further reduce the no-load power consumption of the supply.
The worst-case, no-load power consumption of this supply is approximately 200 mW at
an input voltage of 265 VAC, which is well below the maximum limit of most energy
efficiency standards. Heat generation is also kept to a minimum in this design, given the
high operating efficiency at all line and load conditions.
4.3 Feedback
The output voltage of the supply is regulated based on feedback from the primary-side
bias supply. The bias winding voltage is rectified and filtered by D3 and C3. The leakage
inductance between the output winding and the bias winding induces error in the bias
winding voltage. Using a standard rectifier diode for D3 makes the bias winding voltage
more accurately track the output voltage. Resistor R7 preloads (3 mA) the output of the
bias supply, which further reduces the error and also limits the no-load output voltage.
A resistor divider (R1 and R2) provides the feedback voltage to the FB pin of U1. The
values of R1 and R2 are selected so that when the output voltage is at the desired
nominal value, the voltage on the FB pin is 1.69 V, and about 70 µA flows into the FB pin.
The LinkSwitch-LP family of devices use ON/OFF control to regulate the output of the
supply. During constant voltage (CV) operation, switching cycles are skipped when the
current into the FB pin exceeds 70 µA. As the load on the output of the supply reduces,
more switching cycles are skipped. As the load increases, fewer cycles are skipped.
The result is that the average or effective switching frequency varies with the load. This
makes the efficiency fairly consistent over the entire load range, since the switching
losses scale with the load on the output of the supply.
When the load on the output of the supply reaches its maximum power capability, no
switching cycles are skipped. If the load is increased beyond that point, the output
voltage of the supply will start to drop. As the output voltage drops, the voltage on the FB
pin also drops, and the IC linearly reduces its switching frequency. This keeps the output
current from increasing significantly. Once the FB pin voltage falls below 0.8 V for more
than 100 ms, all LinkSwitch-LP devices enter an auto-restart mode. While in auto-restart,
the controller enables MOSFET switching for 100 ms. If the FB pin voltage does not
exceed 0.8 V during the 100 ms, the controller disables MOSFET switching. MOSFET
switching is alternately enabled and disables at a duty cycle of about 12% until the fault
condition clears. This protects both the supply and the load.
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 8 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
4.4 Output Rectification
The transformer secondary winding is rectified by D4 and filtered by C4. A small preload
resistor (R8) limits the no-load output voltage. Decreasing the value of the preload
resistor will further reduce the no-load output voltage, at the expense of increasing the
no-load input power consumption. In this design, a fast diode (rather than an ultra-fast)
was used for D4 to lower cost and EMI emissions.
Page 9 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
5 PCB Layout
During a common mode surge, the specified surge voltage appears across the isolation
barrier. Elimination of the optocoupler and Y1-type capacitor in the design allowed the
necessary PCB clearance and creepage distance to be obtained, so that the supply can
withstand a 10 kV surge without resorting to expensive, special components.
To increase the creepage and clearance, the standard triple insulated wire used for the
secondary winding was terminated as flying leads that were soldered directly into the
PCB, instead of being terminated to transformer bobbin pins.
A 0.185 inch long, 4.7 mm wide slot was placed along the isolation barrier. Additionally,
the primary and secondary traces are separated by 0.4 inches (10 mm). A spark gap
was added across the isolation barrier (marked as points (B) in Figure 4), so that any
arcing that might occur would take place at a designated point with a well defined path.
On the primary side of the isolation barrier, the spark gap trace returns directly to C6,
which keeps surge currents away from the low-voltage pins of U1. Two additional spark
gaps were placed across L1 and L3, to prevent the breakdown of insulation on those
parts. Note: During 10 kV common mode surge testing, no arcing occurred across any
of the spark gaps.
(A)
(B)
(B)
Figure 4 – RD83 Printed Circuit Layout (2.175” x 1.475” / 55.25 mm x 37.47 mm).
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 10 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
6 Bill Of Materials
1
Ref
Description
Des
2 C1, C6 3.3 µF, 400 V, Electrolytic, (8 x 11.5)
2
1 C2
100 nF, 50 V, Ceramic, Z5U
Panasonic
ECU-S1H104MEA
3
1 C3
10 µF, 50 V, Electrolytic, Gen. Purpose, (5 x 11)
Nippon Chemi-Con
EKMG500ELL100ME11D
4
1 C4
5
1 D1
Nippon Chemi-Con
100 µF, 25 V, Electrolytic, Low ESR,
250 mΩ, (6.3 x 11.5)
600 V, 1 A, Fast Recovery Diode, 200 ns, DO-41 Vishay
6
2 D2, D3 600 V, 1 A, Rectifier, DO-41
Vishay
1N4005
7
1 D4
50 V, 1 A, Fast Recovery, 200 ns, DO-41
Vishay
1N4933
8
2 J1, J2
Test Point, WHT, THRU-HOLE MOUNT
Keystone
5012
9
1 J3
Output cord, 6 ft, 22 AWG, 0.25 Ω,
2.1 mm connector
Generic
10
2 J4, J5
PCB Terminal Hole, 22 AWG
N/A
N/A
11
2 L1, L3 1 mH, 0.15 A, Ferrite Core
Tokin
SBCP-47HY102B
12
1 R1
22.1 kΩ, 1%, 1/4 W, Metal Film
Yageo
MFR-25FBF-22K1
13
1 R2
3.01 kΩ, 1%, 1/4 W, Metal Film
Yageo
MFR-25FBF-3K01
14
Yageo
CFR-25JB-4K7
15
3 R5, R7, 4.7 kΩ, 5%, 1/4 W, Carbon Film
R8
1 R6
100 kΩ, 5%, 1/4 W, Carbon Film
Yageo
CFR-25JB-100K
16
1 RF1
10 Ω, 2.5 W, Fusible/Flame Proof Wire Wound
Vitrohm
CRF253-4 10R
17
1 RV1
275 V, 23 J, 7 mm, RADIAL
Littlefuse
V275LA4
Custom Transformer
Core: EE16,
See Power Integration's document EPR-83 for
Transformer Specification
Hical Magnetics
SIL6043
CWS
EP-83
Santronics
SNX1388
Bobbin: Horizontal Extended Creepage 5+5 pin
Taiwan Shulin
TF-1613
www.bobbin.com.tw
LinkSwitch-LP, LNK562P, DIP-8B
Power Integrations
Item Qty
18
19
1
1
T1
U1
Manufacturer
Manufacturer Part #
Nippon Chemi-Con
ESMQ401ELL3R3MHB5D
ELXZ250ELL101MFB5D
1N4937
LNK562P
Note: For reduced line frequency ripple at 85 VAC, increase the values of C1 and C6 to 4.7 µF.
Page 11 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
7 Transformer Specification
7.1
Electrical Diagram
FL
3
Bias/Core
Cancellation
29T #37AWG X 2
1 LAYER
4
2
WD #4
Secondary
17T
#30AWG TIW
FL
Primary
176T #37AWG
3 LAYERS
Shield
WD #3
15T
#32 AWG X 2
WD #1
WD #2
1
NC
1
Figure 5 –Transformer Electrical Diagram.
7.2
Electrical Specifications
Electrical Strength
Primary Inductance
Resonant Frequency
Primary Leakage Inductance
7.3
1 second, 60 Hz, from Pins 1-4 to Flying leads
Pins 1-2, all other windings open, measured at
100 kHz, 0.4 VRMS
Pins 1-2, all other windings open
Pins 1-2, with flying leads shorted, measured at
100 kHz, 0.4 VRMS
6000 VAC
3.5 mH, ±10%
250 kHz (Min.)
115 µH (Max.)
Materials
Item
[1]
[2]
[3]
[4]
[5]
[6]
[7]
Description
Core: PC40EE16-Z, TDK or equivalent gapped for AL of 114 nH/T2. Gap approx. 0.2 mm.
Bobbin: EE16 Horizontal 10 pin Taiwan Shulin TF-1613 or equivalent
Magnet Wire: #37 AWG
Magnet Wire: #32 AWG
Triple Insulated Wire: #30 AWG
Tape, 3M 1298 Polyester Film, 2.0 Mils thick, 8 mm wide
Varnish
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 12 of 36
29-Sept-06
7.4
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
Transformer Build Diagram
Tape
WD #4
Secondary
FLYING LEAD
FLYING LEAD (MARKED)
Tape
Pin 1
Pin 1
NC
Tape
WD #3
Shield
WD #2
Primary
Pin 2
Pin 3
Pin 4
Tape
WD #1
Cancellation
Figure 6 – Transformer Build Diagram.
7.5
Transformer Construction
Bobbin orientation is such that primary pins are on the left hand side of the winding spindle
WD1
Cancellation and
Bias Winding
Primary pin side of the bobbin oriented to the left hand side. Temporarily
start at pin 7. Wind 29 bifilar turns of item [3] from right to left. Wind with
tight tension evenly across the bobbin. Terminate finish on pin 4. Take
the end of the winding that was started on pin 7 and terminate it on pin 3.
Insulation
1 Layer of tape [6] for insulation.
WD #2
Primary Winding
Insulation
WD #3
Shield Winding
Start at Pin 2. Wind 58 turns of item [3] from left to right. Then wind 59
turns on the next layer from right to left. Wind 59 turns from left to right
on the third layer. Wind with tight tension evenly across the bobbin.
Bring the wire across the bobbin and terminate the finish on pin 1.
Use one layer of tape [6] for basic insulation.
Temporarily start at Pin 7. Wind 15 bifilar turns of item [4]. Wind from
right to left with tight tension across the entire bobbin width. Terminate on
pin 1. Cut the wire from Pin 7 and leave it unconnected.
Core Assembly and
trim flying leads
Use three layers of tape [6] for basic insulation.
Temporarily start at Pin 7 (allow 1” of wire at the start for the flying lead).
Wind 17 turns of item [5] from right to left with tight tension. Allow 1” of
wire at the finish for the flying lead, at the right side of bobbin. Remove
the start from pin 7 and mark. Exit start at right hand side of the bobbin.
Wrap windings with three layers of tape [6].
Gap core such that the inductance between pins 1 & 2 is 3.5 mH ±10%.
The gap is approximately 0.2 mm.
Assemble and secure the core halves. Trim flying leads to 0.65”±0.05”.
Tin leads 0.15”±0.05”. Cut bobbin pins 5,6,7 and 8.
Varnish
Dip varnish assembly with item [7].
Insulation
WD #4
Secondary Winding
Outer insulation
Gap Core
Page 13 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
8 Design Spreadsheets
ACDC_LinkSwitchLP_053106; Rev.1.12;
Copyright Power
Integrations 2006
INPUT
INFO
OUTPUT UNIT
ENTER APPLICATION VARIABLES
ACDC_LinkSwitch-LP_053106_Rev1-12.xls;
LinkSwitch-LP Continuous/Discontinuous
Flyback Transformer Design Spreadsheet
RDR-83
VACMIN
85
Volts
Minimum AC Input Voltage
VACMAX
265
Volts
Maximum AC Input Voltage
fL
50
Hertz
AC Mains Frequency
VO
7.70
Volts
IO
0.21
Amps
Output Voltage (main) measured at the end of
output cable (For CV/CC designs enter typical
CV tolerance limit)
Power Supply Output Current (For CV/CC
designs enter typical CC tolerance limit)
Choose "YES" from the 'CV/CC output' drop
down box at the top of this spreadsheet for
approximate CV/CC output. Choose "NO" for CV
only output
Enter the resistance of the output cable (if used)
Constant Voltage /
Constant Current Output
YES
Output Cable Resistance
CVCC Volts
0.25
0.25 Ohms
PO
1.63 Watts
Feedback Type
BIAS
Bias
Winding
Add Bias Winding
YES
Yes
Clampless design
YES
Clample
ss
n
0.65
0.65
Z
0.35
0.35
tC
2.90
CIN
9.40
Input Rectification Type
Loss Allocation Factor (Secondary side losses /
Total losses)
mSeconds Bridge Rectifier Conduction Time Estimate
UFarads
H
Output Power (VO x IO + dissipation in output
cable)
Choose 'BIAS' for Bias winding feedback and
'OPTO' for Optocoupler feedback from the
'Feedback Type' drop down box at the top of this
spreadsheet
Choose 'YES' in the 'Bias Winding' drop down
box at the top of this spreadsheet to add a Bias
winding. Choose 'NO' to continue design without
a Bias winding. Addition of Bias winding can
lower no load consumption
Choose 'YES' from the 'clampless Design' drop
down box at the top of this spreadsheet for a
clampless design. Choose 'NO' to add an
external clamp circuit. Clampless design lowers
the total cost of the power supply
Efficiency Estimate at output terminals. For CV
only designs enter 0.7 if no better data available
H
Input Capacitance
Choose H for Half Wave Rectifier and F for Full
Wave Rectification from the 'Rectification' drop
down box at the top of this spreadsheet
ENTER LinkSwitch-LP VARIABLES
LinkSwitch-LP
Chosen Device
ILIMITMIN
LinkSwitch-LP device
LNK562
LNK562
0.124 Amps
Minimum Current Limit
ILIMITMAX
0.146 Amps
Maximum Current Limit
fSmin
61000 Hertz
Minimum Device Switching Frequency
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 14 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
I^2fMIN
1099 A^2Hz
I^2fTYP
1221 A^2Hz
VOR
90.00
90 Volts
Reflected Output Voltage
10 Volts
LinkSwitch-LP on-state Drain to Source Voltage
0.90
0.9 Volts
Output Winding Diode Forward Voltage Drop
VDS
VD
I^2f Minimum value (product of current limit
squared and frequency is trimmed for tighter tolerance)
I^2f typical value (product of current limit squared
and frequency is trimmed for tighter tolerance)
KP
1.99
Ripple to Peak Current Ratio (0.9<KRP<1.0 :
1.0<KDP<6.0)
ENTER TRANSFORMER CORE/CONSTRUCTION VARIABLES
Core Type
EE16
EE16
P/N:
PC40EE16-Z
EE16_B
OBBIN
P/N:
EE16_BOBBIN
Core
Bobbin
User-Selected transformer core
EE16
AE
0.192 cm^2
LE
3.5 cm
AL
Core Effective Cross Sectional Area
Core Effective Path Length
1140 nH/T^2
BW
Ungapped Core Effective Inductance
8.6 mm
M
Bobbin Physical Winding Width
0 mm
L
Safety Margin Width (Half the Primary to
Secondary Creepage Distance)
Number of primary layers
2
NS
17
Number of Secondary Turns
NB
44
Number of Bias winding turns
VB
22.26 Volts
Bias Winding Voltage
R1
37.47 k-ohms
R2
3.00 k-ohms
Resistor divider component between bias
wiinding and FB pin of LinkSwitch-LP
Resistor divider component between FB pin of
LinkSwitch-LP and primary RTN
Place this diode on the return leg of the bias
winding for optimal EMI. See LinkSwitch-LP
Design guide for more information
Recommended Bias Diode
1N4003
DC INPUT VOLTAGE PARAMETERS
VMIN
73 Volts
Minimum DC Input Voltage
VMAX
375 Volts
Maximum DC Input Voltage
DMAX
0.45
Maximum Duty Cycle
IAVG
0.04 Amps
Average Primary Current
CURRENT WAVEFORM SHAPE PARAMETERS
IP
0.12 Amps
Minimum Peak Primary Current
IR
0.12 Amps
Primary Ripple Current
IRMS
0.05 Amps
Primary RMS Current
TRANSFORMER PRIMARY DESIGN PARAMETERS
LP
LP_TOLERANCE
Page 15 of 36
3486 uHenries
10 %
Typical Primary Inductance. +/- 10%
Primary inductance tolerance
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
NP
178
Primary Winding Number of Turns
ALG
110 nH/T^2
Gapped Core Effective Inductance
BM
1490 Gauss
ur
1654
Maximum Operating Flux Density, BM<1500 is
recommended
AC Flux Density for Core Loss Curves (0.5 X
Peak to Peak)
Relative Permeability of Ungapped Core
BAC
745 Gauss
LG
0.20 Mm
Gap Length (Lg > 0.1 mm)
BWE
17.2 Mm
Effective Bobbin Width
OD
0.10 Mm
INS
0.02 Mm
DIA
0.07 Mm
Maximum Primary Wire Diameter including
insulation
Estimated Total Insulation Thickness (= 2 * film
thickness)
Bare conductor diameter
AWG
41 AWG
CM
8 Cmils
CMA
Primary Wire Gauge (Rounded to next smaller
standard AWG value)
Bare conductor effective area in circular mils
150 Cmils/Amp Primary Winding Current Capacity (150 < CMA <
500)
TRANSFORMER SECONDARY DESIGN PARAMETERS
Lumped parameters
ISP
1.30 Amps
Peak Secondary Current
ISRMS
0.47 Amps
Secondary RMS Current
IRIPPLE
0.42 Amps
Output Capacitor RMS Ripple Current
CMS
93 Cmils
AWGS
30 AWG
DIAS
0.26 Mm
ODS
0.51 Mm
INSS
0.12 Mm
Secondary Bare Conductor minimum circular
mils
Secondary Wire Gauge (Rounded up to next
larger standard AWG value)
Secondary Minimum Bare Conductor Diameter
Secondary Maximum Outside Diameter for Triple
Insulated Wire
Maximum Secondary Insulation Wall Thickness
VOLTAGE STRESS PARAMETERS
VDRAIN
- Volts
PIVS
44 Volts
Peak Drain Voltage is highly dependent on
Transformer capacitance and leakage
inductance. Please verify this on the bench and
ensure that it is below 650 V to allow 50 V
margin for transformer variation.
Output Rectifier Maximum Peak Inverse Voltage
TRANSFORMER SECONDARY DESIGN PARAMETERS (MULTIPLE OUTPUTS)
1st output
VO1
7.7 Volts
IO1
0.211 Amps
PO1
1.63 Watts
VD1
0.9 Volts
NS1
17.00
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Main Output Voltage (if unused, defaults to
single output design)
Output DC Current
Output Power
Output Diode Forward Voltage Drop
Output Winding Number of Turns
Page 16 of 36
29-Sept-06
ISRMS1
IRIPPLE1
PIVS1
Recommended Diodes
Pre-Load Resistor
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
0.470 Amps
0.42 Amps
44 Volts
SB160,
11DQ06
Output Winding RMS Current
Output Capacitor RMS Ripple Current
Output Rectifier Maximum Peak Inverse Voltage
Recommended Diodes for this output
3 k-Ohms
CMS1
94 Cmils
AWGS1
30 AWG
DIAS1
0.26 mm
ODS1
0.51 mm
Recommended value of pre-load resistor
Output Winding Bare Conductor minimum
circular mils
Wire Gauge (Rounded up to next larger standard
AWG value)
Minimum Bare Conductor Diameter
Maximum Outside Diameter for Triple Insulated
Wire
2nd output
VO2
Volts
Output Voltage
IO2
Amps
Output DC Current
PO2
0.00 Watts
VD2
0.7 Volts
NS2
ISRMS2
IRIPPLE2
PIVS2
1.38
Output Winding Number of Turns
0.000 Amps
0.00 Amps
Output Winding RMS Current
Output Capacitor RMS Ripple Current
3 Volts
Output Rectifier Maximum Peak Inverse Voltage
0 Cmils
Output Winding Bare Conductor minimum
circular mils
Wire Gauge (Rounded up to next larger standard
AWG value)
Minimum Bare Conductor Diameter
Recommended Diode
CMS2
Output Power
Output Diode Forward Voltage Drop
Recommended Diodes for this output
AWGS2
AWG
DIAS2
mm
ODS2
mm
Maximum Outside Diameter for Triple Insulated
Wire
3rd output
VO3
Volts
Output Voltage
IO3
Amps
Output DC Current
PO3
0.00 Watts
VD3
0.7 Volts
NS3
ISRMS3
IRIPPLE3
PIVS3
1.38
Output Winding Number of Turns
0.000 Amps
0.00 Amps
Output Capacitor RMS Ripple Current
Output Rectifier Maximum Peak Inverse Voltage
0 Cmils
Output Winding Bare Conductor minimum
circular mils
Wire Gauge (Rounded up to next larger standard
AWG value)
Minimum Bare Conductor Diameter
Recommended Diodes for this output
AWGS3
AWG
DIAS3
mm
ODS3
mm
Page 17 of 36
Output Winding RMS Current
3 Volts
Recommended Diode
CMS3
Output Power
Output Diode Forward Voltage Drop
Maximum Outside Diameter for Triple Insulated
Wire
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
Total power
1.63 Watts
Total Output Power
Negative Output
N/A
If negative output exists enter Output number;
eg: If VO2 is negative output, enter 2
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 18 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
9 Performance Data
All measurements performed at room temperature, 60 Hz input frequency.
9.1
Efficiency
90
Efficiency (%)
80
70
60
50
40
30
50
75
100
125
150
175
200
225
250
275
300
AC Input Voltage (V)
Figure 7 – Efficiency vs. Input Voltage, Room Temperature, 60 Hz.
Page 19 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
9.1.1 Active Mode ENERGY STAR / CEC Efficiency Measurement Data
All single output cordless phone adapters manufactured for sale in California after
July 1st, 2007 must meet the CEC requirement for minimum active mode efficiency and
no-load input power. Cordless phone adapters must also meet this specification on a
voluntary basis to be able to display the ENERGY STAR logo. Minimum active mode
efficiency is defined as the average efficiency of 25, 50, 75 and 100% of rated output
power, based on the nameplate output power:
ENERGY STAR / CEC Active Mode Efficiency Specification
Nameplate
Output (PO)
Minimum Efficiency in Active Mode
of Operation
<1W
≥ 1 W to ≤ 49 W
> 49 W
0.49 × PO
0.09 × ln (PO) + 0.49 [ln = natural log]
0.84 x PO
For adapters that are single input voltage only, the measurement is made at the rated,
single nominal input voltage (115 VAC or 230 VAC). For universal input adapters, the
measurement for ENERGY STAR qualification is made at both nominal input voltages
(115 VAC and 230 VAC); for CEC qualification, measurements are made at 115 VAC
only. To meet the standard, the measured average efficiency (or efficiencies for
universal input supplies) must be greater than or equal to the efficiency specified by the
CEC / ENERGY STAR standard.
Percent of
Full Load
25
50
75
100
Average
CEC
specified
minimum
average
efficiency (%)
Efficiency (%)
115 VAC
230 VAC
61.0
65.4
66.5
67.4
65.1
56.1
62.6
63.6
62.9
61.3
53.2
More states within the USA and other countries are adopting this standard. For the latest
information, please visit the PI Green Room at:
http://www.powerint.com/greenroom/regulations.htm
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 20 of 36
29-Sept-06
9.2
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
No-load Input Power
The supply easily meets the ENERGY STAR / CEC and European no-load power
consumption specifications of 0.5 W and 0.3 W (respectively).
0.3
Input Power (W)
0.25
0.2
0.15
0.1
0.05
0
0
50
100
150
200
250
300
AC Input Voltage (V)
Figure 8 – No Load Input Power vs. Input Line Voltage, Room Temperature, 60 Hz.
9.3 Available Standby Output Power
The supply provides >500 mW of available output power, at an input power of 1 W.
1
0.9
Available Output Power (W)
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0
0
50
100
150
200
250
300
AC Input Voltage (V)
Figure 9 – Available Output Power at 1 Watt Input Power vs. Input Voltage.
Page 21 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
9.4
29-Sept-06
Regulation
9.4.1 VI Curve vs. Input Voltage
12
LOWER LIMIT
UPPER LIMIT
115 VAC
85 VAC
230 VAC
265 VAC
Output Voltage (V)
10
8
6
4
2
0
0
0.1
0.2
0.3
0.4
0.5
Output Current (A)
0.6
0.7
0.8
Figure 10 – Output VI Curve, Room Temperature.
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 22 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
10 Thermal Performance
10.1 LNK562 Temperature Rise
The RD-83 was installed within a sealed plastic enclosure, placed inside a sealed
cardboard box, and placed into a thermal chamber at 50 °C. The cardboard box
prevented the chamber circulation fan from blowing air across the plastic enclosure. A
thermocouple, attached to pin 2 of U1, was used to monitor its temperature.
Item
Temperature (°C)
85 VAC
265 VAC
Ambient
50
50
LinkSwitch (U1)
78
84
This result indicates acceptable thermal margin of approximately of 16 °C to the
recommended maximum SOURCE pin temperature of 100 °C
10.2 Thermal Image
An infrared thermograph of the board was taken to measure the temperature of other
components. This identified U1 and D4 as the highest temperature components. Using
the results from the previous section, this indicates that D4 would also have an
acceptable temperature rise at 50 °C ambient.
Figure 11 – Thermal Image of the RD-83 at Full Load, 85 VAC Input and Ambient Temperature of 22 °C.
Page 23 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
11 Waveforms
11.1 Drain Voltage and Current, Normal Operation
Figure 12 – 85 VAC, Full Load .
Upper: IDRAIN, 0.1 A / div.
Lower: VDRAIN, 200 V/Div, 2 µs / div.
Figure 13 – 265 VAC, Full Load.
Upper: IDRAIN, 0.1 A / div.
Lower: VDRAIN, 200 V/Div, 2 µs / div.
11.2 Output Voltage Start-up Profile
The output was loaded with a 39 Ω resistive load.
Figure 14 – Start-up Profile, 115VAC.
2 V, 20 ms / div.
Figure 15 – Start-up Profile, 230 VAC.
2 V, 20 ms / div.
The start-up waveforms show minimal output overshoot (<200 mV).
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 24 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
11.3 Drain Voltage and Current Start-up Profile
The output was loaded with a 39 Ω resistive load and the output profile captured. These
waveforms show no sign of core saturation and acceptable margin to the recommended
maximum drain voltage of 650 VPK.
Figure 16 – 85 VAC Input and Maximum Load.
Upper: IDRAIN, 0.1 A / div.
Lower: VDRAIN, 100 V & 1 ms / div.
Page 25 of 36
Figure 17 – 265 VAC Input and Maximum Load.
Upper: IDRAIN, 0.1 A / div.
Lower: VDRAIN, 200 V & 1 ms / div.
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
11.4 Load Transient Response (50% to 100% Load Step)
In the figures shown below, signal averaging was used to better enable viewing the load
transient response. The oscilloscope was triggered using the load current step as a
trigger source. Since the output switching and line frequency occur essentially at random
with respect to the load transient, contributions to the output ripple from these sources
will average out, leaving the contribution only from the load step response.
Figure 18 – Transient Response, 115 VAC, 50-10050% Load Step.
Top: Load Current, 0.1 A/div.
Bottom: Output Voltage
200 mV, 500 µs / div.
Figure 19 – Transient Response, 230 VAC, 50-10050% Load Step.
Upper: Load Current, 0.1 A/ div.
Bottom: Output Voltage
200 mV, 500 uS / div.
These results were significantly lower than the linear adapter where ripple and transient
response variation was greater than 1 VP-P.
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 26 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
11.5 Output Ripple Measurements
11.5.1 Ripple Measurement Technique
For DC output ripple measurements, a modified oscilloscope test probe must be utilized
in order to reduce the pickup of spurious signals. Details of the probe modification are
provided in Figure 20 and Figure 21.
The 5125BA probe adapter (from probe master) is affixed with two capacitors tied in
parallel across the probe tip. The capacitors include one (1) 0.1 µF/50 V ceramic type
and one (1) 1.0 µF/50 V aluminum electrolytic. The aluminum electrolytic type capacitor
is polarized, so proper polarity across DC outputs must be maintained (see Figure 21).
Probe Ground
Probe Tip
Figure 20 – Oscilloscope Probe Prepared for Ripple Measurement (End Cap and Ground Lead Removed).
Figure 21 – Oscilloscope Probe with Probe Master 5125BA BNC Adapter (Modified with wires for probe
ground for ripple measurement, and two parallel decoupling capacitors added).
Page 27 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
11.5.2 Measurement Results
Figure 22 – Ripple, 85 VAC, Full Load.
5 ms, 50 mV / div (240 mVP-P).
Figure 23 – Ripple, 115 VAC, Full Load.
5 ms, 50 mV / div (80 mVP-P).
Figure 24 – Ripple, 230 VAC, Full Load.
5 ms, 50 mV /div (130mVP-P).
Figure 25 – Ripple of a Linear adaptor, 115 VAC
Input, Full Load.
2 ms, 200 mV/div (800 mVP-P).
Figure 22 shows increased line frequency ripple. If required, this could be lowered to the
level shown in Figure 23 by increasing the value of C6 and C1 to 4.7 µF.
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 28 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
12 Line Surge
Differential and common mode 1.2/50 µs surge testing was completed on a single test
unit, to IEC61000-4-5. Input voltage was set at 230 VAC / 60 Hz. The output of the
supply was loaded to full load, and correct operation was verified following each surge
event.
Surge
Level (V)
+2000
-2000
+10000
-10000
Input
Voltage
(VAC)
230
230
230
230
Injection
Location
Injection
Phase (°)
Test Result
(Pass/Fail)
L to N
L to N
L,N to RTN
L,N to RTN
90
90
90
90
Pass
Pass
Pass
Pass
Unit passed under all test conditions.
Page 29 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
13 Conducted EMI
Measurements were made with the output RTN of the supply connected to the artificial
hand connection on the LISN (line impedance stabilization network) to represent worstcase conditions.
The results show excellent margin of >15 dBµV to both the quasi-peak and the average
limit lines.
Power Integrations
28.Aug 06 09:43
Att 10 dB AUTO
dBµV
80
70
1 QP
CLRWR
EN55022Q
2 AV
CLRWR
EN55022A
RBW
9 kHz
MT
500 ms
PREAMP OFF
1 MHz
LIMIT CHECK
MARG
LINE EN55022A MARG
LINE EN55022Q MARG
Marker 1 [T1 ]
28.50 dBµV
182.849162999 kHz
10 MHz
SGL
60
50
TDF
40
1
30
20
10
0
-10
-20
150 kHz
30 MHz
Figure 26 – Conducted EMI, Maximum Steady State Load, 115 VAC, 60 Hz, and EN55022 B Limits.
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 30 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
Power Integrations
28.Aug 06 09:53
Att 10 dB AUTO
dBµV
80
70
1 QP
CLRWR
EN55022Q
2 AV
CLRWR
EN55022A
RBW
9 kHz
MT
500 ms
PREAMP OFF
1 MHz
LIMIT CHECK
MARG
LINE EN55022A MARG
LINE EN55022Q MARG
Marker 1 [T1 ]
28.76 dBµV
182.849162999 kHz
10 MHz
SGL
60
50
TDF
40
1
30
20
10
0
-10
-20
150 kHz
30 MHz
Figure 27 – Conducted EMI, Maximum Steady State Load, 230 VAC, 60 Hz, and EN55022 B Limits.
Page 31 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
14 Revision History
Date
29-Sept-06
Author
JAC
Revision
1.0
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Description & changes
Initial Release
Reviewed
PV, JJ, DA
Page 32 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
Notes
Page 33 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
Notes
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
Page 34 of 36
29-Sept-06
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
Notes
Page 35 of 36
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
RDR-83 7.7 V, 210 mA Adapter with 10 kV surge withstand
29-Sept-06
For the latest updates, visit our website: www.powerint.com
Power Integrations reserves the right to make changes to its products at any time to improve reliability or manufacturability. Power
Integrations does not assume any liability arising from the use of any device or circuit described herein. POWER INTEGRATIONS
MAKES NO WARRANTY HEREIN AND SPECIFICALLY DISCLAIMS ALL WARRANTIES INCLUDING, WITHOUT
LIMITATION, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, AND
NON-INFRINGEMENT OF THIRD PARTY RIGHTS.
PATENT INFORMATION
The products and applications illustrated herein (including transformer construction and circuits external to the products) may be
covered by one or more U.S. and foreign patents, or potentially by pending U.S. and foreign patent applications assigned to Power
Integrations. A complete list of Power Integrations’ patents may be found at www.powerint.com. Power Integrations grants its
customers a license under certain patent rights as set forth at http://www.powerint.com/ip.htm.
The PI Logo, TOPSwitch, TinySwitch, LinkSwitch, DPA-Switch, PeakSwitch, EcoSmart, Clampless, E-Shield,
Filterfuse, PI Expert and PI FACTS are trademarks of Power Integrations, Inc. Other trademarks are property of their respective
companies. ©Copyright 2006 Power Integrations, Inc.
Power Integrations Worldwide Sales Support Locations
WORLD HEADQUARTERS
5245 Hellyer Avenue
San Jose, CA 95138, USA.
Main:
+1-408-414-9200
Customer Service:
Phone:
+1-408-414-9665
Fax:
+1-408-414-9765
e-mail: [email protected]
GERMANY
Rueckertstrasse 3
D-80336, Munich
Germany
Phone:
+49-89-5527-3910
Fax:
+49-89-5527-3920
e-mail: [email protected]
JAPAN
Keihin Tatemono 1st Bldg
2-12-20
Shin-Yokohama, Kohoku-ku,
Yokohama-shi, Kanagawa ken,
Japan 222-0033
Phone:
+81-45-471-1021
Fax:
+81-45-471-3717
e-mail:
[email protected]
TAIWAN
5F, No. 318, Nei Hu Rd., Sec. 1
Nei Hu Dist.
Taipei, Taiwan 114, R.O.C.
Phone:
+886-2-2659-4570
Fax:
+886-2-2659-4550
e-mail:
[email protected]
CHINA (SHANGHAI)
Rm 807-808A,
Pacheer Commercial Centre,
555 Nanjing Rd. West
Shanghai, P.R.C. 200041
Phone:
+86-21-6215-5548
Fax:
+86-21-6215-2468
e-mail: [email protected]
INDIA
261/A, Ground Floor
7th Main, 17th Cross,
Sadashivanagar
Bangalore, India 560080
Phone:
+91-80-41138020
Fax:
+91-80-41138023
e-mail: [email protected]
KOREA
RM 602, 6FL
Korea City Air Terminal B/D,
159-6
Samsung-Dong, Kangnam-Gu,
Seoul, 135-728, Korea
Phone:
+82-2-2016-6610
Fax:
+82-2-2016-6630
e-mail:
[email protected]
UNITED KINGDOM
1st Floor, St. James’s House
East Street, Farnham
Surrey, GU9 7TJ
United Kingdom
Phone:
+44 (0) 1252-730-140
Fax:
+44 (0) 1252-727-689
e-mail: [email protected]
CHINA (SHENZHEN)
Room 2206-2207, Block A,
Elec. Sci. Tech. Bldg.
2070 Shennan Zhong Rd.
Shenzhen, Guangdong,
China, 518031
Phone:
+86-755-8379-3243
Fax:
+86-755-8379-5828
e-mail: [email protected]
ITALY
Via De Amicis 2
20091 Bresso MI – Italy
Phone: +39-028-928-6000
Fax: +39-028-928-6009
e-mail: [email protected]
SINGAPORE
51 Newton Road,
#15-08/10 Goldhill Plaza,
Singapore, 308900
Phone:
+65-6358-2160
Fax:
+65-6358-2015
e-mail:
[email protected]
APPLICATIONS HOTLINE
World Wide +1-408-414-9660
Power Integrations
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
APPLICATIONS FAX
World Wide +1-408-414-9760
Page 36 of 36