NCP1010, NCP1011, NCP1012, NCP1013, NCP1014 Self−Supplied Monolithic Switcher for Low Standby− Power Offline SMPS
The NCP101X series integrates a fixed−frequency current−mode controller and a 700 V MOSFET. Housed in a PDIP −7, PDIP−7 Gull Wing, or SOT−223 package, the NCP101X offers everything needed to build a rugged and low−cost power supply, including soft−start, frequency jittering, short−circuit protection, skip−cycle, a maximum peak current setpoint and a Dynamic Self−Supply (no need for an auxiliary winding). Unlike other monolithic solutions, the NCP101X is quiet by nature: during nominal load operation, the part switches at one of the available frequencies (65 − 100 − 130 kHz). When the current setpoint falls below a given value, e.g. the output power demand diminishes, the IC automatically enters the so−called skip−cycle mode and provides excellent efficiency at light loads. Because this occurs at typically 1/4 of the maximum peak value, no acoustic noise takes place. As a result, standby power is reduced to the minimum without acoustic noise generation. Short−circuit detection takes place when the feedback signal fades away, e.g. in true short−circuit conditions or in broken Optocoupler cases. External disabling is easily done either simply by pulling the feedback pin down or latching it to ground through an inexpensive SCR for complete latched−off. Finally soft−start and frequency jittering further ease the designer task to quickly develop low−cost and robust offline power supplies. For improved standby performance, the connection of an auxiliary winding stops the DSS operation and helps to consume less than 100 mW at high line. In this mode, a built−in latched overvoltage protection prevents from lethal voltage runaways in case the Optocoupler would brake. These devices are available in economical 8−pin dual−in−line and 4−pin SOT−223 packages.
Features
4 1
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4 SOT−223 CASE 318E ST SUFFIX 1 PDIP−7 CASE 626A AP SUFFIX 1 PDIP−7 (Gull Wing) CASE 626AA APL SUFFIX 1 1 P101xAPyy AWL YYWWG AYW 101xy G G
8
1 x y
1xAPLyyy AWL YYWWG
= Current Limit (0, 1, 2, 3, 4) = Oscillator Frequency A (65 kHz), B (100 kHz), C (130 kHz) yy = 06 (65 kHz), 10 (100 kHz), 13 (130 kHz) yyy = 065, 100, 130 A = Assembly Location WL, L = Wafer Lot YY, Y = Year WW, W = Work Week G or G = Pb−Free Package (Note: Microdot may be in either location)
ORDERING INFORMATION
See detailed ordering and shipping information in the package dimensions section on page 21 of this data sheet.
• Built−in 700 V MOSFET with Typical RDSon of 11 W • • • • • • •
and 22 W Large Creepage Distance Between High−Voltage Pins Current−Mode Fixed Frequency Operation: 65 kHz – 100 kHz − 130 kHz Skip−Cycle Operation at Low Peak Currents Only: No Acoustic Noise! Dynamic Self−Supply, No Need for an Auxiliary Winding Internal 1.0 ms Soft−Start Latched Overvoltage Protection with Auxiliary Winding Operation Frequency Jittering for Better EMI Signature
• Auto−Recovery Internal Output Short−Circuit • Below 100 mW Standby Power if Auxiliary Winding • • • •
is Used Internal Temperature Shutdown Direct Optocoupler Connection SPICE Models Available for TRANsient Analysis Pb−Free Packages are Available Protection
Typical Applications
• Low Power AC/DC Adapters for Chargers • Auxiliary Power Supplies (USB, Appliances,TVs, etc.)
© Semiconductor Components Industries, LLC, 2006
October, 2006 − Rev. 17
1
Publication Order Number: NCP1010/D
NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
PIN CONNECTIONS
PDIP−7 VCC 1 NC 2 GND 3 FB 4 (Top View) 5 DRAIN 8 GND 7 GND VCC 1 NC 2 GND 3 FB 4 (Top View) 5 DRAIN PDIP−7 (Gull Wing) 8 GND 7 GND VCC FB DRAIN 1 2 3 (Top View) 4 GND SOT−223
Indicative Maximum Output Power from NCP1014
RDSon − Ip 11 W − 450 mA DSS 11 W − 450 mA Auxiliary Winding 230 Vac 14 W 19 W 100 − 250 Vac 6.0 W 8.0 W
1. Informative values only, with: Tamb = 50°C, Fswitching = 65 kHz, circuit mounted on minimum copper area as recommended.
Vout +
+ 100−250 Vac
1 2 3 8 7
+
4
5
NCP101X
GND
Figure 1. Typical Application Example Quick Selection Table
NCP1010 RDSon [W] Ipeak [mA] Freq [kHz] 65 100 100 130 65 22 250 100 130 65 250 100 130 65 NCP1011 NCP1012 NCP1013 11 350 100 130 65 450 100 NCP1014
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
PIN FUNCTION DESCRIPTION
Pin No. (SOT−223) 1 Pin No. (PDIP−7, PDIP−7/Gull Wing) 1
Pin Name VCC
Function Powers the Internal Circuitry
Description This pin is connected to an external capacitor of typically 10 mF. The natural ripple superimposed on the VCC participates to the frequency jittering. For improved standby performance, an auxiliary VCC can be connected to Pin 1. The VCC also includes an active shunt which serves as an opto fail−safe protection. − − By connecting an optocoupler to this pin, the peak current setpoint is adjusted accordingly to the output power demand. The internal drain MOSFET connection. − − −
− − 2
2 3 4
NC GND FB
− The IC Ground Feedback Signal Input
3 − − 4
5 − 7 8
Drain − GND GND
Drain Connection − The IC Ground The IC Ground
VCC VCC 1 Vclamp* IVCC I?
Startup Source Drain
Iref = 7.4 mA IVCC
− + Rsense
8 GND
UVLO Management
High when VCC t 3 V
R
S Q 250 ns L.E.B.
NC 2 4V
Reset EMI Jittering 65, 100 or 130 kHz Clock Set Flip−Flop DCmax = 65% Reset 18 k Error flag armed? VCC Q Driver
7 GND
GND 3 0.5 V Overload? + −
− + + −
Soft−Start FB 4
Startup Sequence Overload
Drain
5 Drain
*Vclamp = VCCOFF + 200 mV (8.7 V Typical)
Figure 2. Simplified Internal Circuit Architecture
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ Á ÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ Á ÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
MAXIMUM RATINGS
Rating Symbol VCC − Value Unit V V Power Supply Voltage on all pins, except Pin 5 (Drain) Drain Voltage −0.3 to 10 −0.3 to 700 550 1.0 15 Drain Current Peak during Transformer Saturation NCP1010/11 NCP1012/13/14 Maximum Current into Pin 1 when Activating the 8.7 V Active Clamp Thermal Characteristics P Suffix, Case 626A Junction−to−Lead Junction−to−Air, 2.0 oz (70 mm) Printed Circuit Copper Clad 0.36 Sq. Inch (2.32 Sq. Cm) 1.0 Sq. Inch (6.45 Sq. Cm) PL Suffix (Gull Wing), Case 626AA Junction−to−Lead Junction−to−Air, 2.0 oz (70 mm) Printed Circuit Copper Clad 0.36 Sq. Inch (2.32 Sq. Cm) 1.0 Sq. Inch (6.45 Sq. Cm) ST Suffix, Plastic Package Case 318E Junction−to−Lead Junction−to−Air, 2.0 oz (70 mm) Printed Circuit Copper Clad 0.36 Sq. Inch (2.32 Sq. Cm) 1.0 Sq. Inch (6.45 Sq. Cm) Maximum Junction Temperature Storage Temperature Range ESD Capability, Human Body Model (All pins except HV) ESD Capability, Machine Model IDS(pk) mA A mA °C/W RqJL RqJA 9.0 77 60 11.9 92 71 14 74 55 150 −60 to +150 2.0 200 °C °C kV V I_VCC RqJL RqJA RqJL RqJA TJmax − − − Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect device reliability.
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
VCC = 8.0 V unless otherwise noted.)
ELECTRICAL CHARACTERISTICS (For typical values TJ = 25°C, for min/max values TJ = 0°C to +125°C, Max TJ = 150°C,
Rating SUPPLY SECTION AND VCC MANAGEMENT VCC Increasing Level at which the Current Source Turns−off VCC Decreasing Level at which the Current Source Turns−on Hysteresis between VCCOFF and VCCON VCC Decreasing Level at which the Latch−off Phase Ends VCC Decreasing Level at which the Internal Latch is Released Internal IC Consumption, MOSFET Switching at 65 kHz Internal IC Consumption, MOSFET Switching at 100 kHz Internal IC Consumption, MOSFET Switching at 130 kHz Internal IC Consumption, Latch−off Phase, VCC = 6.0 V Active Zener Voltage Positive Offset to VCCOFF Latch−off Current NCP1012/13/14 NCP1010/11 POWER SWITCH CIRCUIT Power Switch Circuit On−state Resistance NCP1012/13/14 (Id = 50 mA) TJ = 25°C TJ = 125°C NCP1010/11 (Id = 50 mA) TJ = 25°C TJ = 125°C Power Switch Circuit and Startup Breakdown Voltage (ID(off) = 120 mA, TJ = 25°C) Power Switch and Startup Breakdown Voltage Off−state Leakage Current TJ = 25°C (Vds = 700 V) TJ = 125°C (Vds = 700 V) Switching Characteristics (RL = 50 W, Vds Set for Idrain = 0.7 x Ilim) Turn−on Time (90%−10%) Turn−off Time (10%−90%) INTERNAL STARTUP CURRENT SOURCE High−voltage Current Source, VCC = 8.0 V NCP1012/13/14 NCP1010/11 High−voltage Current Source, VCC = 0 CURRENT COMPARATOR TJ = 25°C (Note 2) Maximum Internal Current Setpoint, NCP1010 (Note 3) Maximum Internal Current Setpoint, NCP1011 (Note 3) Maximum Internal Current Setpoint, NCP1012 (Note 3) Maximum Internal Current Setpoint, NCP1013 (Note 3) Maximum Internal Current Setpoint, NCP1014 (Note 3) Default Internal Current Setpoint for Skip−Cycle Operation, Percentage of Max Ip Propagation Delay from Current Detection to Drain OFF State 5 5 5 5 5 − − − Ipeak (22) Ipeak (22) Ipeak (11) Ipeak (11) Ipeak (11) ILskip TDEL TLEB 90 225 225 315 405 − − − 100 250 250 350 450 25 125 250 110 275 275 385 495 − − − mA mA mA mA mA % ns ns 1 IC1 5.0 5.0 1 IC2 − 8.0 8.5 10 10 10.3 − mA mA 5 RDSon − 11 19 22 38 5 BVdss IDS(OFF) 5 5 − − 50 30 − − ns 5 5 ton toff − − 20 10 − − 700 − 16 24 35 50 − V mA W 1 1 1 1 1 1 1 1 1 1 1 VCCOFF VCCON − VCClatch VCCreset ICC1 ICC1 ICC1 ICC2 Vclamp ILatch 6.3 5.8 7.4 7.3 9.2 9.0 7.9 6.9 − 4.4 − − − − − 140 8.5 7.5 1.0 4.7 3.0 0.92 0.95 0.98 290 200 9.1 8.1 − 5.1 − 1.1 (Note 2) 1.15 (Note 2) 1.2 (Note 2) − 300 V V V V V mA mA mA mA mV mA Pin Symbol Min Typ Max Unit
Leading Edge Blanking Duration 2. See characterization curves for temperature evolution. 3. Adjust di/dt to reach Ipeak in 3.2 msec.
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
Max TJ = 150°C, VCC= 8.0 V unless otherwise noted.) Rating INTERNAL OSCILLATOR Oscillation Frequency, 65 kHz Version, TJ = 25°C (Note 4) Oscillation Frequency, 100 kHz Version, TJ = 25°C (Note 4) Oscillation Frequency, 130 kHz Version, TJ = 25°C (Note 4) Frequency Dithering Compared to Switching Frequency (with active DSS) Maximum Duty−cycle FEEDBACK SECTION Internal Pull−up Resistor Internal Soft−Start (Guaranteed by Design) SKIP−CYCLE GENERATION Default Skip Mode Level on FB Pin TEMPERATURE MANAGEMENT Temperature Shutdown Hysteresis in Shutdown 4. See characterization curves for temperature evolution. − − TSD − − − 150 50 − − °C °C 4 Vskip − 0.5 − V 4 − Rup Tss − − 18 1.0 − − kW ms − − − − − fOSC fOSC fOSC fdither Dmax 59 90 117 − 62 65 100 130 "3.3 67 71 110 143 − 72 kHz kHz kHz % %
ELECTRICAL CHARACTERISTICS (continued) (For typical values TJ = 25°C, for min/max values TJ = 0°C to +125°C,
Pin Symbol Min Typ Max Unit
TYPICAL CHARACTERISTICS
−2.0 −3.0 −4.0 IC1 ( mA) ICC1 (mA) −5.0 −6.0 −7.0 −8.0 −9.0 −10.0 −25 0 25 50 75 TEMPERATURE (°C) 100 125 1.50 1.40 1.30 1.20 1.10 1.00 0.90 0.80 0.70 0.60 0.50 −25 0 25 50 75 TEMPERATURE (°C) 100 125
Figure 3. IC1 @ VCC = 8.0 V, FB = 1.5 V vs. Temperature
0.40 0.38 0.36 0.34 VCC−OFF ( V ) ICC2 (mA) 0.32 0.30 0.28 0.26 0.24 0.22 0.20 −25 0 25 50 75 TEMPERATURE (°C) 100 125 9.00 8.90 8.80 8.70 8.60 8.50 8.40 8.30 8.20 −25
Figure 4. ICC1 @ VCC = 8.0 V, FB = 1.5 V vs. Temperature
0
25 50 75 TEMPERATURE (°C)
100
125
Figure 5. ICC2 @ VCC = 6.0 V, FB = Open vs. Temperature
Figure 6. VCC OFF, FB = 1.5 V vs. Temperature
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
TYPICAL CHARACTERISTICS
8.00 7.90 7.80 DUTY CYCLE (%) 0 25 50 75 100 125 VCC−ON ( V) 7.70 7.60 7.50 7.40 7.30 7.20 7.10 7.00 −25 TEMPERATURE (°C) 65 −25 0 25 50 75 100 125 TEMPERATURE (°C) 68 68 67 67 66 66
Figure 7. VCC ON, FB = 3.5 V vs. Temperature
Figure 8. Duty Cycle vs. Temperature
9.00 8.80 8.60 8.40 I_Latch (mA) Ipeak (mA) 8.20 8.00 7.80 7.60 7.40 7.20 7.00 −25 0 25 50 75 100 125
500 480 460 440 420 400 380 360 340 320 300 −25 0 25 50 75 100 125 NCP1013
Figure 9. ILatch, FB = 1.5 V vs. Temperature
160 140 120 fOSC (kHz) 100 80 60 40 −25 100 kHz 130 kHz 25.00 20.00 15.00 10.00 5.00 0.00 −25
TEMPERATURE (°C)
Figure 10. Ipeak−RR, VCC = 8.0 V, FB = 3.5 V vs. Temperature
TEMPERATURE (°C)
0
25 50 75 TEMPERATURE (°C)
100
125
RDSon (W)
0
25 50 75 TEMPERATURE (°C)
100
125
Figure 11. Frequency vs. Temperature
Figure 12. ON Resistance vs. Temperature, NCP1012/1013
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
APPLICATION INFORMATION
Introduction
The NCP101X offers a complete current−mode control solution (actually an enhanced NCP1200 controller section) together with a high−voltage power MOSFET in a monolithic structure. The component integrates everything needed to build a rugged and low−cost Switch−Mode Power Supply (SMPS) featuring low standby power. The Quick Selection Table on Page 2, details the differences between references, mainly peak current setpoints and operating frequency. No need for an auxiliary winding: ON Semiconductor Very High Voltage Integrated Circuit technology lets you supply the IC directly from the high−voltage DC rail. We call it Dynamic Self−Supply (DSS). This solution simplifies the transformer design and ensures a better control of the SMPS in difficult output conditions, e.g. constant current operations. However, for improved standby performance, an auxiliary winding can be connected to the VCC pin to disable the DSS operation. Short−circuit protection: By permanently monitoring the feedback line activity, the IC is able to detect the presence of a short−circuit, immediately reducing the output power for a total system protection. Once the short has disappeared, the controller resumes and goes back to normal operation. Fail−safe optocoupler and OVP: When an auxiliary winding is connected to the VCC pin, the device stops its internal Dynamic Self−Supply and takes its operating power from the auxiliary winding. A 8.7 V active clamp is connected between VCC and ground. In case the current injected in this clamp exceeds a level of 7.4 mA (typical), the controller immediately latches off and stays in this position until VCC cycles down to 3.0 V (e.g. unplugging the converter from the wall). By adjusting a limiting resistor in series with the VCC terminal, it becomes possible to implement an overvoltage protection function, latching off the circuit in case of broken optocoupler or feedback loop problems. Low standby−power: If SMPS naturally exhibits a good efficiency at nominal load, it begins to be less efficient when the output power demand diminishes. By skipping unneeded switching cycles, the NCP101X drastically reduces the power wasted during light load conditions. An auxiliary winding can further help decreasing the standby power to extremely low levels by invalidating the DSS operation. Typical measurements show results below 80 mW @ 230 Vac for a typical 7.0 W universal power supply.
No acoustic noise while operating: Instead of skipping cycles at high peak currents, the NCP101X waits until the peak current demand falls below a fixed 1/4 of the maximum limit. As a result, cycle skipping can take place without having a singing transformer … You can thus select cheap magnetic components free of noise problems. SPICE model: A dedicated model to run transient cycle−by−cycle simulations is available but also an averaged version to help close the loop. Ready−to−use templates can be downloaded in OrCAD’s PSpice, and INTUSOFT’s IsSpice4 from ON Semiconductor web site, NCP101X related section.
Dynamic Self−Supply
When the power supply is first powered from the mains outlet, the internal current source (typically 8.0 mA) is biased and charges up the VCC capacitor from the drain pin. Once the voltage on this VCC capacitor reaches the VCCOFF level (typically 8.5 V), the current source turns off and pulses are delivered by the output stage: the circuit is awake and activates the power MOSFET. Figure 13 details the internal circuitry.
Vref OFF = 8.5 V Vref ON = 7.5 V Vref Latch = 4.7 V* + − Internal Supply Drain
Startup Source
VCC
+ Vref
VCCOFF +200 mV (8.7 V Typ.)
+
CVCC
*In fault condition
Figure 13. The Current Source Regulates VCC by Introducing a Ripple
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
8.5 V Vcc
6.00
8.00
7.5 V
4.00
2.00
Device Internally Pulses
0
Startup Period Figure 14. The Charge/Discharge Cycle Over a 10 mF VCC Capacitor
The protection burst duty−cycle can easily be computed through the various timing events as portrayed by Figure 16. Being loaded by the circuit consumption, the voltage on the VCC capacitor goes down. When the DSS controller detects that VCC has reached 7.5 V (VCCON), it activates the internal current source to bring VCC toward 8.5 V and stops again: a cycle takes place whose low frequency depends on the VCC capacitor and the IC consumption. A 1.0 V ripple takes place on the VCC pin whose average value equals (VCCOFF + VCCON)/2. Figure 14 portrays a typical operation of the DSS. As one can see, the VCC capacitor shall be dimensioned to offer an adequate startup time, i.e. ensure regulation is reached before VCC crosses 7.5 V (otherwise the part enters the fault condition mode). If we know that DV = 1.0 V and ICC1 (max) is 1.1 mA (for instance we selected an 11 W device switching at 65 kHz), then the VCC capacitor can suppose that the SMPS needs 10 ms to startup, then we will calculate C to offer a 15 ms period. As a result, C should be greater than 20 mF thus the selection of a 33 mF/16 V capacitor is appropriate.
Short Circuit Protection ICC1 · tstartup (eq. 1) be calculated using: C w . Let’s DV
for the presence of the error flag every time VCC crosses VCCON. If the error flag is low (peak limit not active) then the IC works normally. If the error signal is active, then the NCP101X immediately stops the output pulses, reduces its internal current consumption and does not allow the startup source to activate: VCC drops toward ground until it reaches the so−called latch−off level, where the current source activates again to attempt a new restart. When the error is gone, the IC automatically resumes its operation. If the default is still there, the IC pulses during 8.5 V down to 7.5 V and enters a new latch−off phase. The resulting burst operation guarantees a low average power dissipation and lets the SMPS sustain a permanent short−circuit. Figure 15 shows the corresponding diagram.
Current Sense Information
4V
FB
Division Max Ip VCC
+ − VCCON Signal
To Latch Reset
The internal protection circuitry involves a patented arrangement that permanently monitors the assertion of an internal error flag. This error flag is, in fact, a signal that instructs the controller that the internal maximum peak current limit is reached. This naturally occurs during the startup period (Vout is not stabilized to the target value) or when the optocoupler LED is no longer biased, e.g. in a short−circuit condition or when the feedback network is broken. When the DSS normally operates, the logic checks
Clamp Active?
Flag
Figure 15. Simplified NCP101X Short−Circuit Detection Circuitry
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
Tsw 1 V Ripple Tstart TLatch
Latch−off Level
Figure 16. NCP101X Facing a Fault Condition (Vin = 150 Vdc)
The rising slope from the latch−off level up to 8.5 V is expressed by: Tstart + DV1 · C . The time during which IC1 the IC actually pulses is given by tsw + DV2 · C . ICC1 the latch−off time can be derived
Vds(t) toff Vin Vr dt
Finally,
using the same formula topology: TLatch + DV3 · C . ICC2 can be computed: dc +
dc + Tsw (eq. 2) . Tstart ) Tsw ) TLatch
From these three definitions, the burst duty−cycle
DV2 (eq. 3) . DV3 DV2 ICC1 · ICC1 ) DV1 ) ICC2 IC1
Feeding
the
ton Tsw
t
equation with values extracted from the parameter section gives a typical duty−cycle of 13%, precluding any lethal thermal runaway while in a fault condition.
DSS Internal Dissipation
Figure 17. A typical drain−ground waveshape where leakage effects are not accounted for.
The Dynamic Self−Supplied pulls energy out from the drain pin. In Flyback−based converters, this drain level can easily go above 600 V peak and thus increase the stress on the DSS startup source. However, the drain voltage evolves with time and its period is small compared to that of the DSS. As a result, the averaged dissipation, excluding capacitive losses, can be derived by: PDSS + ICC1 · t Vds(t) u . (eq. 4) . Figure 17 portrays a typical drain−ground waveshape where leakage effects have been removed.
By looking at Figure 17, the average result can easily be derived by additive square area calculation:
t Vds(t) u+ Vin · (1 * d) ) Vr · toff Tsw
(eq. 5)
By developing Equation 5, we obtain:
t Vds(t) u+ Vin * Vin · ton ) Vr · toff Tsw Tsw
(eq. 6)
toff can be expressed by: toff + Ip · can be evaluated by: ton + Ip ·
Lp (eq. 8) . Vin
Lp (eq. 7) where ton Vr
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
Plugging Equations 7 and 8 into Equation 6 leads to ICC1 (eq. 9) . The worse case occurs at high line, when Vin equals 370 Vdc. With ICC1 = 1.1 mA (65 kHz version), we can expect a DSS dissipation around 407 mW. If you select a higher switching frequency version, the ICC1 increases and it is likely that the DSS consumption exceeds that number. In that case, we recommend to add an auxiliary winding in order to offer more dissipation room to the power MOSFET. Please read application note AND8125/D, “Evaluating the Power Capability of the NCP101X Members” to help in selecting the right part/configuration for your application.
t Vds(t) u+ Vin and thus, PDSS + Vin Lowering the Standby Power with an Auxiliary Winding
The DSS operation can bother the designer when its dissipation is too high and extremely low standby power is a must. In both cases, one can connect an auxiliary winding to disable the self−supply. The current source then ensures the startup sequence only and stays in the off state as long as VCC does not drop below VCCON or 7.5 V. Figure 18 shows that the insertion of a resistor (Rlimit) between the auxiliary DC level and the VCC pin is mandatory to not damage the internal 8.7 V active Zener diode during an overshoot for instance (absolute maximum current is 15 mA) and to implement the fail−safe optocoupler protection as offered by the active clamp. Please note that there cannot be bad interaction between the clamping voltage of the internal Zener and VCCOFF since this clamping voltage is actually built on top of VCCOFF with a fixed amount of offset (200 mV typical). Self−supplying controllers in extremely low standby applications often puzzles the designer. Actually, if a SMPS operated at nominal load can deliver an auxiliary voltage of an arbitrary 16 V (Vnom), this voltage can drop to below 10 V (Vstby) when entering standby. This is because the recurrence of the switching pulses expands so much that the low frequency refueling rate of the VCC capacitor is not enough to keep a constant auxiliary voltage. Figure 19 portrays a typical scope shot of a SMPS entering deep standby (output unloaded). So care must be taken when calculating Rlimit 1) to not trigger the VCC over current latch [by injecting 6.3 mA (min. value) into the active clamp] in normal operation but 2) not to drop too much voltage over Rlimit when entering standby. Otherwise the DSS could reactivate and the standby performance would degrade. We are thus able to bound Rlimit between two equations:
Vnom * Vclamp Itrip v Rlimit v Vstby * VCCON (eq. 10) ICC1
Itrip is the current corresponding to the nominal operation. It must be selected to avoid false tripping in overshoot conditions. ICC1 is the controller consumption. This number slightly decreases compared to ICC1 from the spec since the part in standby almost does not switch. VCCON is the level above which Vaux must be maintained to keep the DSS in the OFF mode. It is good to shoot around 8.0 V in order to offer an adequate design margin, e.g. to not reactivate the startup source (which is not a problem in itself if low standby power does not matter). Since Rlimit shall not bother the controller in standby, e.g. keep Vaux to around 8.0 V (as selected above), we purposely select a Vnom well above this value. As explained before, experience shows that a 40% decrease can be seen on auxiliary windings from nominal operation down to standby mode. Let’s select a nominal auxiliary winding of 20 V to offer sufficient margin regarding 8.0 V when in standby (Rlimit also drops voltage in standby…). Plugging the values in Equation 10 gives the limits within which Rlimit shall be selected:
20 * 8.7 v Rlimit v 12 * 8 6.3 m 1.1 m , that is to say: (eq. 11) 1.8 k t Rlimit t 3.6 k
Where: Vnom is the auxiliary voltage at nominal load. Vstdby is the auxiliary voltage when standby is entered.
If we design a power supply delivering 12 V, then the ratio between auxiliary and power must be: 12/20 = 0.6. The OVP latch will activate when the clamp current exceeds 6.3 mA. This will occur when Vaux increases to: 8.7 V + 1.8 k x (6.4m + 1.1m) = 22.2 V for the first boundary or 8.7 V + 3.6 k x (6.4m +1.1m) = 35.7 V for second boundary. On the power output, it will respectively give 22.2 x 0.6 = 13.3 V and 35.7 x 0.6 = 21.4 V. As one can see, tweaking the Rlimit value will allow the selection of a given overvoltage output level. Theoretically predicting the auxiliary drop from nominal to standby is an almost impossible exercise since many parameters are involved, including the converter time constants. Fine tuning of Rlimit thus requires a few iterations and experiments on a breadboard to check Vaux variations but also output voltage excursion in fault. Once properly adjusted, the fail−safe protection will preclude any lethal voltage runaways in case a problem would occur in the feedback loop. When an OVP occurs, all switching pulses are permanently disabled, the output voltage thus drops to zero. The VCC cycles up and down between 8.5–4.7 V and stays in this state until the user unplugs the power supply and forces VCC to drop below 3.0 V (VCCreset). Below this value, the internal OVP latch is reset and when the high voltage is reapplied, a new startup sequence can take place in an attempt to restart the converter.
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
VCCON = 8.5 V VCCOFF = 7.5 V + − + Drain
Startup Source VCC Rlimit D1
+ − + Vclamp = 8.7 V typ. Permanent Latch + − + CVcc + Caux Laux
+
I > 7.4m (Typ.) Ground
Figure 18. A more detailed view of the NCP101X offers better insight on how to properly wire an auxiliary winding.
u30 ms
Figure 19. The burst frequency becomes so low that it is difficult to keep an adequate level on the auxiliary VCC . . .
Lowering the Standby Power with Skip−Cycle
Skip−cycle offers an efficient way to reduce the standby power by skipping unwanted cycles at light loads. However, the recurrent frequency in skip often enters the audible range and a high peak current obviously generates acoustic noise in the transformer. The noise takes its origins in the resonance of the transformer mechanical structure
which is excited by the skipping pulses. A possible solution, successfully implemented in the NCP1200 series, also authorizes skip−cycle but only when the power demand has dropped below a given level. At this time, the peak current is reduced and no noise can be heard. Figure 20 pictures the peak current evolution of the NCP101X entering standby.
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12
NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
100% Peak current at nominal power
Skip−cycle current limit 25%
Figure 20. Low Peak Current Skip−Cycle Guarantees Noise−Free Operation
Full power operation involves the nominal switching frequency and thus avoids any noise when running. Experiments carried on a 5.0 W universal mains board unveiled a standby power of 300 mW @ 230 Vac with the DSS activated and dropped to less than 100 mW when an auxiliary winding is connected.
Frequency Jittering for Improved EMI Signature
By sweeping the switching frequency around its nominal value, it spreads the energy content on adjacent frequencies rather than keeping it centered in one single ray. This offers
the benefit to artificially reduce the measurement noise on a standard EMI receiver and pass the tests more easily. The EMI sweep is implemented by routing the VCC ripple (induced by the DSS activity) to the internal oscillator. As a result, the switching frequency moves up and down to the DSS rhythm. Typical deviation is "3.3% of the nominal frequency. With a 1.0 V peak−to−peak ripple, the frequency will equal 65 kHz in the middle of the ripple and will increase as VCC rises or decrease as VCC ramps down. Figure 21 portrays the behavior we have adopted.
VCC Ripple
VCCOFF 67.15 kHz
65 kHz
62.85 kHz VCCON
Internal Sawtooth
Figure 21. The VCC ripple is used to introduce a frequency jittering on the internal oscillator sawtooth. Here, a 65 kHz version was selected.
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13
NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
Soft−Start
The NCP101X features an internal 1.0 ms soft−start activated during the power on sequence (PON). As soon as VCC reaches VCCOFF, the peak current is gradually increased from nearly zero up to the maximum internal clamping level (e.g. 350 mA). This situation lasts 1.0 ms and further to that time period, the peak current limit is blocked to the maximum until the supply enters regulation. The soft−start is also activated during the over current burst
VCC
(OCP) sequence. Every restart attempt is followed by a soft−start activation. Generally speaking, the soft−start will be activated when VCC ramps up either from zero (fresh power−on sequence) or 4.7 V, the latch−off voltage occurring during OCP. Figure 22 portrays the soft−start behavior. The time scales are purposely shifted to offer a better zoom portion.
8.5 V
0 V (Fresh PON) or 4.7 V (Overload) Current Sense Max Ip
1.0 ms
Figure 22. Soft−Start is activated during a startup sequence or an OCP condition. Non−Latching Shutdown
In some cases, it might be desirable to shut off the part temporarily and authorize its restart once the default has disappeared. This option can easily be accomplished through a single NPN bipolar transistor wired between FB
and ground. By pulling FB below the internal skip level (Vskip), the output pulses are disabled. As soon as FB is relaxed, the IC resumes its operation. Figure 23 depicts the application example.
1 2 3 4 5 8 7
Drain
ON/OFF
+
CVcc
Figure 23. A non−latching shutdown where pulses are stopped as long as the NPN is biased.
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14
NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
Full Latching Shutdown
Other applications require a full latching shutdown, e.g. when an abnormal situation is detected (overtemperature or overvoltage). This feature can easily be implemented through two external transistors wired as a discrete SCR. When the OVP level exceeds the Zener breakdown
OVP 10 k Rhold 12 k
voltage, the NPN biases the PNP and fires the equivalent SCR, permanently bringing down the FB pin. The switching pulses are disabled until the user unplugs the power supply.
1 2
8 7
BAT54
3 4 5
Drain
+ 10 k
CVcc
Figure 24. Two Bipolars Ensure a Total Latch−Off of the SMPS in Presence of an OVP
Rhold ensures that the SCR stays on when fired. The bias current flowing through Rhold should be small enough to let the VCC ramp up (8.5 V) and down (7.5 V) when the SCR is fired. The NPN base can also receive a signal from a temperature sensor. Typical bipolars can be MMBT2222 and MMBT2907 for the discrete latch. The MMBT3946 features two bipolars NPN+PNP in the same package and could also be used.
Power Dissipation and Heatsinking
maximum power the device can thus evacuate is: 1.0 W for an ambient of 50°C. The losses inherent to the MOSFET RDSon can be evaluated using the following formula: Pmos + 1 · Ip2 · d · RDSon
3
(eq. 13)
T * Tambmax (eq. 12) which gives around Pmax + Jmax RqJA
, where Ip
The NCP101X welcomes two dissipating terms, the DSS current−source (when active) and the MOSFET. Thus, Ptot = PDSS + PMOSFET. When the PDIP−7 package is surrounded by copper, it becomes possible to drop its thermal resistance junction−to−ambient, RqJA down to 75°C/W and thus dissipate more power. The
is the worse case peak current (at the lowest line input), d is the converter operating duty−cycle and RDSon, the MOSFET resistance for TJ = 100°C. This formula is only valid for Discontinuous Conduction Mode (DCM) operation where the turn−on losses are null (the primary current is zero when you restart the MOSFET). Figure 25 gives a possible layout to help drop the thermal resistance. When measured on a 35 mm (1 oz) copper thickness PCB, we obtained a thermal resistance of 75°C/W.
Figure 25. A Possible PCB Arrangement to Reduce the Thermal Resistance Junction−to−Ambient http://onsemi.com
15
NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
Design Procedure
The design of an SMPS around a monolithic device does not differ from that of a standard circuit using a controller
and a MOSFET. However, one needs to be aware of certain characteristics specific of monolithic devices:
350
250
150
50.0
> 0 !!
− 50.0
1.004M
1.011M
1.018M
1.025M
1.032M
Figure 26. The Drain−Source Wave Shall Always be Positive . . .
1. In any case, the lateral MOSFET body−diode shall never be forward biased, either during startup (because of a large leakage inductance) or in normal operation as shown by Figure 26. As a result, the Flyback voltage which is reflected on the drain at the switch opening cannot be larger than the input voltage. When selecting components, you thus must adopt a turn ratio which adheres to the following equation: N · (Vout ) Vf) t Vin min (eq. 14) . For instance, if operating from a 120 V DC rail, with a delivery of 12 V, we can select a reflected voltage of 100 Vdc maximum: 120–100 > 0. Therefore, the turn ratio Np:Ns must be smaller than 100/(12 + 1) = 7.7 or Np:Ns < 7.7. We will see later on how it affects the calculation. 2. A current−mode architecture is, by definition, sensitive to subharmonic oscillations. Subharmonic oscillations only occur when the SMPS is operating in Continuous Conduction Mode (CCM) together with a duty−cycle greater than 50%. As a result, we recommend to operate the device in DCM only, whatever duty−cycle it implies (max = 65%). However, CCM operation with duty−cycles below 40% is possible. 3. Lateral MOSFETs have a poorly dopped body−diode which naturally limits their ability to sustain the avalanche. A traditional RCD clamping network shall thus be installed to protect the MOSFET. In some low power applications, a simple capacitor can also be used since
Vdrain max + Vin ) N · (Vout ) Vf) ) Ip ·
(eq. 15)
Ctot is the total capacitance at the drain node (which is increased by the capacitor wired between drain and source), N the Np:Ns turn ratio, Vout the output voltage, Vf the secondary diode forward drop and finally, Ip the maximum peak current. Worse case occurs when the SMPS is very close to regulation, e.g. the Vout target is almost reached and Ip is still pushed to the maximum. Taking into account all previous remarks, it becomes possible to calculate the maximum power that can be transferred at low line. When the switch closes, Vin is applied across the primary inductance Lp until the current reaches the level imposed by the feedback loop. The duration of this event is called the ON time and can be defined by:
ton + Lp · Ip Vin
(eq. 16)
At the switch opening, the primary energy is transferred to the secondary and the flyback voltage appears across Lp, resetting the transformer core with a slope of
N · (Vout ) Vf) . toff, the OFF time is thus: Lp toff + Lp · Ip N · (Vout ) Vf)
(eq. 17)
If one wants to keep DCM only, but still need to pass the maximum power, we will not allow a dead−time after the core is reset, but rather immediately restart. The switching time can be expressed by:
Tsw + toff ) ton + Lp · Ip · 1) 1 Vin N · (Vout ) Vf)
(eq. 18)
Lf Ctot
, where Lf is the leakage inductance,
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
The Flyback transfer formula dictates that: Ip and plugging into Equation 19, leads to:
Tsw + Lp Pout + 1 · Lp · Ip2 · Fsw (eq. 19) which, by extracting h 2 2 · Pout · 1 ) 1 Vin N · (Vout ) Vf) h · Fsw · Lp Example 1. A 12 V 7.0 W SMPS operating on a large mains with NCP101X:
(eq. 20)
Extracting Lp from Equation 20 gives:
Lpcritical +
(eq. 21)
(Vin · Vr)2 · h 2 · Fsw · [Pout · (Vr2 ) 2 · Vr · Vin ) Vin2)]
Vin = 100 Vac to 250 Vac or 140 Vdc to 350 Vdc once rectified, assuming a low bulk ripple Efficiency = 80% Vout = 12 V, Iout = 580 mA Fswitching = 65 kHz Ip max = 350 mA – 10% = 315 mA Applying the above equations leads to: Selected maximum reflected voltage = 120 V with Vout = 12 V, secondary drop = 0.5 V → Np:Ns = 1:0.1 Lp critical = 3.2 mH Ip = 292 mA Duty−cycle worse case = 50% Idrain RMS = 119 mA PMOSFET = 354 mW at RDSon = 24 W (TJ > 100°C) PDSS = 1.1 mA x 350 V = 385 mW, if DSS is used Secondary diode voltage stress = (350 x 0.1) + 12 = 47 V (e.g. a MBRS360T3, 3.0 A/60 V would fit)
Example 2. A 12 V 16 W SMPS operating on narrow European mains with NCP101X:
, with Vr = N . (Vout + Vf) and h the efficiency. If Lp critical gives the inductance value above which DCM operation is lost, there is another expression we can write to connect Lp, the primary peak current bounded by the NCP101X and the maximum duty−cycle that needs to stay below 50%: corresponds to the lowest rectified bulk voltage, hence the longest ton duration or largest duty−cycle. Ip max is the available peak current from the considered part, e.g. 350 mA typical for the NCP1013 (however, the minimum value of this parameter shall be considered for reliable evaluation). Combining Equations 21 and 22 gives the maximum theoretical power you can pass respecting the peak current capability of the NCP101X, the maximum duty−cycle and the discontinuous mode operation:
Pmax :+ Tsw2 · Vinmin2 · Vr2 · h · Fsw (2 · Lpmax · Vr2 ) 4 · Lpmax · Vr · Vinmin (eq. 23) ) 2 · Lpmax · Vinmin2) Lpmax + DCmax · Vinmin · Tsw (eq. 22) where Vinmin Ipmax
From Equation 22 we obtain the operating duty−cycle
d+
Vin = 230 Vac " 15%, 276 Vdc for Vin min to 370 Vdc once rectified Efficiency = 80% Vout = 12 V, Iout = 1.25 A Fswitching = 65 kHz Ip max = 350 mA – 10% = 315 mA Applying the equations leads to: Selected maximum reflected voltage = 250 V with Vout = 12 V, secondary drop = 0.5 V → Np:Ns = 1:0.05 Lp = 6.6 mH Ip = 0.305 mA Duty−cycle worse case = 0.47 Idrain RMS = 121 mA PMOSFET = 368 mW at RDSon = 24 W (TJ > 100°C) PDSS = 1.1 mA x 370 V = 407 mW, if DSS is used below an ambient of 50°C. Secondary diode voltage stress = (370 x 0.05) + 12 = 30.5 V (e.g. a MBRS340T3, 3.0 A/40 V) Please note that these calculations assume a flat DC rail whereas a 10 ms ripple naturally affects the final voltage available on the transformer end. Once the Bulk capacitor has been selected, one should check that the resulting ripple (min Vbulk?) is still compatible with the above calculations. As an example, to benefit from the largest operating range, a 7.0 W board was built with a 47 mF bulk capacitor which ensured discontinuous operation even in the ripple minimum waves.
current circulating in the MOSFET:
IdRMS + Ip · d (eq. 25) . From this equation, we 3
Ip · Lp Vin · Tsw
(eq. 24)
which lets us calculate the RMS
obtain
the
average
dissipation
(eq. 26)
in
the
MOSFET:
losses shall be added. If we stick to Equation 23, compute Lp and follow the above calculations, we will discover that a power supply built with the NCP101X and operating from a 100 Vac line minimum will not be able to deliver more than 7.0 W continuous, regardless of the selected switching frequency (however the transformer core size will go down as Fswitching is increased). This number increases significantly when operated from a single European mains (18 W). Application note AND8125/D, “Evaluating the Power Capability of the NCP101X Members” details how to assess the available power budget from all the NCP101X series.
Pavg + 1 · Ip2 · d · RDSon 3
to which switching
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
MOSFET Protection
As in any Flyback design, it is important to limit the drain excursion to a safe value, e.g. below the MOSFET
HV HV Rclamp
BVDSS which is 700 V. Figure 27 presents possible implementations:
HV Cclamp Dz
D 1 2 3 CVcc + 4 NCP101X 5 CVcc C + 8 7 1 2 3 4 NCP101X 5 CVcc + 8 7 1 2 3 4 NCP101X 5 8 7
D
A
B Figure 27. Different Options to Clamp the Leakage Spike
C
Figure 27A: The simple capacitor limits the voltage according to Equation 15. This option is only valid for low power applications, e.g. below 5.0 W, otherwise chances exist to destroy the MOSFET. After evaluating the leakage inductance, you can compute C with Equation 15. Typical values are between 100 pF and up to 470 pF. Large capacitors increase capacitive losses. Figure 27B: This diagram illustrates the most standard circuitry called the RCD network. Rclamp and Cclamp are calculated using the following formulas:
Rclamp + 2 · Vclamp · (Vclamp * (Vout ) Vf sec) · N) Lleak · Ip2 · Fsw Cclamp + Vclamp Vripple · Fsw · Rclamp
(eq. 27) (eq. 28)
Vclamp is usually selected 50−80 V above the reflected value N x (Vout + Vf). The diode needs to be a fast one and a MUR160 represents a good choice. One major drawback of the RCD network lies in its dependency upon the peak current. Worse case occurs when Ip and Vin are maximum and Vout is close to reach the steady−state value.
Figure 27C: This option is probably the most expensive of all three but it offers the best protection degree. If you need a very precise clamping level, you must implement a Zener diode or a TVS. There are little technology differences behind a standard Zener diode and a TVS. However, the die area is far bigger for a transient suppressor than that of Zener. A 5.0 W Zener diode like the 1N5388B will accept 180 W peak power if it lasts less than 8.3 ms. If the peak current in the worse case (e.g. when the PWM circuit maximum current limit works) multiplied by the nominal Zener voltage exceeds these 180 W, then the diode will be destroyed when the supply experiences overloads. A transient suppressor like the P6KE200 still dissipates 5.0 W of continuous power but is able to accept surges up to 600 W @ 1.0 ms. Select the Zener or TVS clamping level between 40 to 80 V above the reflected output voltage when the supply is heavily loaded.
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
Typical Application Examples
A 6.5 W NCP1012−Based Flyback Converter
Figure 28 shows a converter built with a NCP1012 delivering 6.5 W from a universal input. The board uses the Dynamic Self−Supply and a simplified Zener−type
feedback. This configuration was selected for cost reasons and a more precise circuitry can be used, e.g. based on a TL431:
D6 B150 E3 470 m/25 V
D1 1N4007
D2 1N4007 E1 10 m/400 V
1 TR1 8 7 R2 150 k C1 2.2 nF IC1 NCP1012 1 E2 10 m/16 V VCC HV FB GND 5 4 8 2 GND 3 GND 7 GND IC2 PC817 D5 U160 6 5
4
2 1 J2 CZM5/2
R1 47 R 1 2 J1 CEE7.5/2 D3 1N4007 D4 1N4007
ZD1 11 V R3 100 R
R4 180 R
C2 2n2/Y
Figure 28. An NCP1012−Based Flyback Converter Delivering 6.5 W
The converter built according to Figure 29 layouts, gave the following results: • Efficiency at Vin = 100 Vac and Pout = 6.5 W = 75.7% • Efficiency at Vin = 230 Vac and Pout = 6.5 W = 76.5%
Figure 29. The NCP1012−Based PCB Layout . . . and its Associated Component Placement
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
A 7.0 W NCP1013−based Flyback Converter Featuring Low Standby Power
Figure 30 depicts another typical application showing a NCP1013−65 kHz operating in a 7.0 W converter up to 70°C of ambient temperature. We can increase the output
Vbulk 1N4148 D4
power since an auxiliary winding is used, the DSS is disabled, and thus offering more room for the MOSFET. In this application, the feedback is made via a TLV431 whose low bias current (100 mA min) helps to lower the no−load standby power.
R4 22
+ C10 33 mF/25 V
T1 Aux
C8 10 nF 400 V
R7 100 k/ 1W
D2 MBRS360T3 + T1 +
L2 22 mH
C6 C8 470 mF/16 V
12 V @ 0.6 A + 100 mF/16 V C7 GND
R2 3.3 k
D3 MUR160 NCP1013P06 R3 1k
C2 47 mF/ 450 V
+
1 VCC GND 8 2 NC 3 GND 4 FB D5 GND 7
R5 39 k
+ 100 mF/10 V C3
C4 C9 1 nF IC1 SFH6156−2 100 nF
IC2 TLV431 C5 2.2 nF Y1 Type
R6 4.3 k
Figure 30. A Typical Converter Delivering 7.0 W from a Universal Mains
Measurements have been taken from a demonstration board implementing the diagram in Figure 30 and the following results were achieved, with either the auxiliary winding in place or through the Dynamic Self−Supply: Vin = 230 Vac, auxiliary winding, Pout = 0, Pin = 60 mW Vin = 100 Vac, auxiliary winding, Pout = 0, Pin = 42 mW Vin = 230 Vac, Dynamic Self−Supply, Pout = 0, Pin = 300 mW Vin = 100 Vac, Dynamic Self−Supply, Pout = 0, Pin = 130 mW Pout = 7.0 W, h = 81% @ 230 Vac, with auxiliary winding Pout = 7.0 W, h = 81.3 @ 100 Vac, with auxiliary winding
For a quick evaluation of Figure 30 application example, the following transformers are available from Coilcraft: A9619−C, Lp = 3.0 mH, Np:Ns = 1:0.1, 7.0 W application on universal mains, including auxiliary winding, NCP1013−65kHz. A0032−A, Lp = 6.0 mH, Np:Ns = 1:0.055, 10 W application on European mains, DSS operation only, NCP1013−65 kHz. Coilcraft 1102 Silver Lake Road CARY IL 60013 Email: info@coilcraft.com Tel.: 847−639−6400 Fax.: 847−639−1469
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NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
ORDERING INFORMATION
Device Order Number NCP1010AP065 NCP1010AP065G NCP1010AP100 NCP1010AP100G NCP1010AP130 NCP1010AP130G NCP1011APL065R2G NCP1010ST65T3 NCP1010ST65T3G NCP1010ST100T3 NCP1010ST100T3G NCP1010ST130T3 NCP1010ST130T3G NCP1011AP065 NCP1011AP065G NCP1011APL065R2G NCP1011AP100 NCP1011AP100G NCP1011AP130 NCP1011AP130G NCP1011APL130R2G NCP1011ST65T3 NCP1011ST65T3G NCP1011ST100T3 NCP1011ST100T3G NCP1011ST130T3 NCP1011ST130T3G NCP1012AP065 NCP1012AP065G NCP1012APL065R2G NCP1012AP100 NCP1012AP100G Frequency (kHz) 65 65 100 100 130 130 65 65 65 100 100 130 130 65 65 65 100 100 130 130 130 65 65 100 100 130 130 65 65 65 100 100 Package Type PDIP−7 PDIP−7 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 (Gull Wing) (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 (Gull Wing) (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 (Gull Wing) (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 (Gull Wing) (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) 50 Units / Rail 50 Units / Rail 1000 / Tape & Reel 4000 / Tape & Reel 1000 / Tape & Reel 50 Units / Rail 50 Units / Rail 1000 / Tape & Reel 4000 / Tape & Reel 1000 / Tape & Reel 50 Units / Rail Shipping † RDSon (W) 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 11 11 11 11 11 Ipk (mA) 100 100 100 100 100 100 250 100 100 100 100 100 100 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250 250
†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specifications Brochure, BRD8011/D. Additional Gull Wing option may be available upon request. Please contact your ON Semiconductor representative.
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21
NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
ORDERING INFORMATION
Device Order Number NCP1012APL100R2G NCP1012AP133 NCP1012AP133G NCP1012APL130R2G NCP1012ST65T3 NCP1012ST65T3G NCP1012ST100T3 NCP1012ST100T3G NCP1012ST130T3 NCP1012ST130T3G NCP1013AP065 NCP1013AP065G NCP1013AP100 NCP1013AP100G NCP1013AP133 NCP1013AP133G NCP1013ST65T3 NCP1013ST65T3G NCP1013ST100T3 NCP1013ST100T3G NCP1013ST130T3 NCP1013ST130T3G NCP1014AP065 NCP1014AP065G NCP1014APL065R2G NCP1014AP100 NCP1014AP100G NCP1014APL100R2G NCP1014ST65T3 NCP1014ST65T3G NCP1014ST100T3 NCP1014ST100T3G Frequency (kHz) 100 130 130 130 65 65 100 100 130 130 65 65 100 100 130 130 65 65 100 100 130 130 65 65 65 100 100 100 65 65 100 100 Package Type PDIP−7 (Gull Wing) (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 (Gull Wing) (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 (Gull Wing) (Pb−Free) PDIP−7 PDIP−7 (Pb−Free) PDIP−7 (Gull Wing) (Pb−Free) SOT−223 SOT−223 (Pb−Free) SOT−223 SOT−223 (Pb−Free) 4000 / Tape & Reel 50 Units / Rail 1000 / Tape & Reel 50 Units / Rail 1000 / Tape & Reel 4000 / Tape & Reel 50 Units / Rail 4000 / Tape & Reel 4000 / Tape & Reel 50 Units / Rail 1000 / Tape & Reel Shipping † 1000 / Tape & Reel RDSon (W) 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 Ipk (mA) 250 250 250 250 250 250 250 250 250 250 350 350 350 350 350 350 350 350 350 350 350 350 450 450 450 450 450 450 450 450 450 450
†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specifications Brochure, BRD8011/D. Additional Gull Wing option may be available upon request. Please contact your ON Semiconductor representative.
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22
NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
PACKAGE DIMENSIONS
PDIP−7 AP SUFFIX CASE 626A−01 ISSUE O
NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: MILLIMETER. 3. PACKAGE CONTOUR OPTIONAL (ROUND OR SQUARE CORNERS). 4. DIMENSION L TO CENTER OF LEAD WHEN FORMED PARALLEL. 5. DIMENSIONS A AND B ARE DATUMS.
8
5
B
1 4
L M J
F
NOTE 3
A
C −T−
SEATING PLANE
N D K
M
DIM A B C D F G H J K L M N
MILLIMETERS MIN MAX 9.40 10.16 6.10 6.60 3.94 4.45 0.38 0.51 1.02 1.78 2.54 BSC 0.76 1.27 0.20 0.30 2.92 3.43 7.62 BSC −−− 10_ 0.76 1.01
INCHES MIN MAX 0.370 0.400 0.240 0.260 0.155 0.175 0.015 0.020 0.040 0.070 0.100 BSC 0.030 0.050 0.008 0.012 0.115 0.135 0.300 BSC −−− 10_ 0.030 0.040
H
G 0.13 (0.005) TA
M
B
M
A H
4 R 0.030 1
PDIP−7, GULL WING APL SUFFIX CASE 626AA−01 ISSUE O
0.015 DP MAX Bottom Ejector Pin BS
NOTES: 1. DIMENSIONS AND TOLERANCING PER ASME Y14.5M, 1994. 2. DIMENSIONS IN INCHES. INCHES MIN MAX 0.365 0.385 0.240 0.260 0.120 0.150 0.124 0.162 0.018 TYP 0.039 TYP 0.045 0.065 0.100 BSC 0.023 0.033 0.010 TYP 0.004 0.012 0.036 0.044 0_ 8_ 12 _ TYP 0.300 BSC 0.372 0.388
5
8
E D TOP VIEW P N
F
BOTTOM VIEW
T C C1
GAUGE PLANE 0.015
− H− J 0.004
DIM A B C C1 D E F G H J K L M N P S
R 0.016 TYP
G SIDE VIEW
K
L FRONT VIEW
M
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23
NCP1010, NCP1011, NCP1012, NCP1013, NCP1014
PACKAGE DIMENSIONS
SOT−223 ST SUFFIX CASE 318E−04 ISSUE L
D b1
NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: INCH. MILLIMETERS NOM MAX 1.63 1.75 0.06 0.10 0.75 0.89 3.06 3.20 0.29 0.35 6.50 6.70 3.50 3.70 2.30 2.40 0.94 1.05 1.75 2.00 7.00 7.30 10° − INCHES NOM 0.064 0.002 0.030 0.121 0.012 0.256 0.138 0.091 0.037 0.069 0.276 −
4
HE
1
2
3
E
e1
b e A q L1 C
DIM A A1 b b1 c D E e e1 L1 HE
q
MIN 1.50 0.02 0.60 2.90 0.24 6.30 3.30 2.20 0.85 1.50 6.70 0°
MIN 0.060 0.001 0.024 0.115 0.009 0.249 0.130 0.087 0.033 0.060 0.264 0°
MAX 0.068 0.004 0.035 0.126 0.014 0.263 0.145 0.094 0.041 0.078 0.287 10°
0.08 (0003)
A1
SOLDERING FOOTPRINT*
3.8 0.15 2.0 0.079
2.3 0.091
2.3 0.091
6.3 0.248
2.0 0.079 1.5 0.059
SCALE 6:1 mm inches
*For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D.
The products described herein (NCP1010, 1011, 1012, 1013, 1014), may be covered by one or more of the following U.S. patents: 6,271,735, 6,362,067, 6,385,060, 6,429,709, 6,587,357, 6,633,193. There may be other patents pending.
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NCP1010/D