™ LinkSwitch-HP Family Energy Efficient, High-Power Off-Line Switcher With Accurate Primary-Side Regulation (PSR) Product Highlights EcoSmart™- Energy Efficient • Multi-mode control maximizes efficiency over full load range • No-load consumption below 30 mW at 230 VAC (LNK67xx) • >75% efficiency with 1 W input at 230 VAC • >50% efficiency with 0.1 W input at 230 VAC High Design Flexibility for Low System Cost • Dramatically simplifies power supply designs • Eliminates optocoupler and all secondary control circuitry • ±5% or better output voltage tolerance • 132 kHz operation reduces transformer and power supply size • Accurate programmable current limit • Compensation over line limits overload power • Frequency jittering reduces EMI filter cost • Fully integrated soft-start for minimum start-up stress • 725 V MOSFET simplifies meeting derating requirements (LNK677x) • 650 V MOSFET for lowest system cost (LNK676x/LNK666x) • Fast transient response family option (LNK666x) Extensive Protection Features • Auto-restart limits power delivery to 3% during overload faults • Output short-circuit protection (SCP) • Output overload/over-current protection (OPP, OCP) • Optional extended shutdown delay time • Output overvoltage protection (OVP), auto-restart or latching • Line brown-in/out protection (line UV) • Line overvoltage (OV) shutdown extends line surge withstand • Accurate thermal shutdown (OTP), hysteretic or latching Advanced Green Package Options • eSIP™-7C package: • Vertical orientation for minimum PCB footprint • Simple heat sink mounting using clip or adhesive pad • eSOP™-12B package: • Low profile surface mounted for ultra-slim designs • Heat transfer to PCB via exposed pad and SOURCE pins • Supports either wave or IR reflow soldering • eDIP™-12B package: • Low profile through-hole mounted for ultra-slim designs • Heat transfer to PCB via exposed pad or optional metal heat sink • Extended creepage to DRAIN pin • Heat sink is connected to SOURCE for low EMI • Halogen free and RoHS compliant Typical Applications • LCD Monitor and TV • Adapter • Appliances • Embedded power supplies (DVD, set-top box) • Industrial CONTROL Figure 1. Typical Application Schematic. Exposed Pad eSIP-7C (E Package) Figure 2. Exposed Pad eSOP-12B (K Package) eDIP-12B (V Package) Package Options. Output Power Table 230 VAC ±15% Product4 Heat Sink LNK6xx3K/V LNK6xx3K LNK6xx3E LNK6xx4K/V LNK6xx4K LNK6xx4E LNK6xx5K/V LNK6xx5K LNK6xx5E LNK6xx6K/V LNK6xx6K LNK6xx6E LNK6xx7K/V LNK6xx7K LNK6xx7E PCB-W1 PCB-R2 Metal PCB-W1 PCB-R2 Metal PCB-W1 PCB-R2 Metal PCB-W1 PCB-R2 Metal PCB-W1 PCB-R2 Metal 85-265 VAC Adapter Open Frame Adapter Open Frame 15 W 21 W 21 W 16 W 22 W 30 W 19 W 26 W 40 W 21 W 30 W 60 W 25 W 36 W 853 W 25 W 35 W 35 W 28 W 39 W 47 W 30 W 42 W 593 W 34 W 48 W 883 W 41 W 59 W 1173 W 9W 12 W 13 W 11 W 15 W 20 W 13 W 18 W 26 W 15 W 22 W 40 W 19 W 27 W 55 W 15 W 21 W 27 W 20 W 28 W 36 W 22 W 31 W 45 W 26 W 37 W 683 W 30 W 43 W 903 W Table 1. Output Power Table. Notes: 1. PCB heat sink with wave soldering. 2. PCB heat sink with IR reflow soldering (exposed pad thermally connected to PCB). 3. Maximum power specified based on proper thermal dissipation. 4. Packages: E: eSIP-7C, K: eSOP-12B, V: eDIP-12B. See Table 2 for all device options. www.powerint.com March 2014 This Product is Covered by Patents and/or Pending Patent Applications. LinkSwitch-HP BYPASS (BP) LATCH/HYSTERETIC DRAIN (D) 5.75 V REGULATOR THERMAL SHUTDOWN FAULT FILTER BYPASS PROGRAM + 5.75 V 4.9 V MULTI-CYCLE MODE CONTROL COMPENSATION (CP) - MCM 2V REFERENCE VOLTAGE + OV AUTORESTART SOFTSTART FEEDBACK (FB) HIGH GAIN TRANSCONDUCTANCE AMPLIFIER OUTPUT OVERVOLTAGE AUTO-RESTART S/H LINE OVERVOLTAGE/ UNDERVOLTAGE DETECTION GATE DRIVER CLOCK OSC DCMAX LUV LOV OSCILLATOR LINE COMP PROGRAM/ DELAY (PD) ERROR VOLTAGE + AMP LINE COMPENSATION S Q R Q LEB + CUSTOM SHUTDOWN DELAY CURRENT LIMIT COMPARATOR PROGRAM ILIM CURRENT LIMIT SETTING SOURCE (S) PI-6565-072012 40% ~ 100% Figure 3. Block Diagram. LNK 6 X X X E/V/K Part Number Series TMCM(OFF)2 6 = 0.5 ms 7 = 4.0 ms BVDSS1 6 = 650 V 7 = 725 V Power Packages 6 0.5 ms 0.5 ms 0.5 ms 0.5 ms 0.5 ms 4.0 ms 4.0 ms 4.0 ms 4.0 ms 4.0 ms 4.0 ms 4.0 ms 4.0 ms 4.0 ms 4.0 ms 650 V 650 V 650 V 650 V 650 V 650 V 650 V 650 V 650 V 650 V 725 V 725 V 725 V 725 V 725 V Device Size eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) eSIP-7C (E), eDIP-12B (V), eSOP-12B (K) LNK6663E/V/K LNK6664E/V/K LNK6665E/V/K LNK6666E/V/K LNK6667E/V/K LNK6763E/V/K LNK6764E/V/K LNK6765E/V/K LNK6766E/V/K LNK6767E/V/K LNK6773E/V/K LNK6774E/V/K LNK6775E/V/K LNK6776E/V/K LNK6777E/V/K Table 2. Device Part Numbers and Options. Notes: 1. Minimum breakdown voltage at TJ = +25 °C. 2. TMCM(OFF) = 0.5 ms for fastest transient response, TMCM(OFF) = 4 ms for <30 mW no-load input power. 2 Rev. C 03/14 www.powerint.com LinkSwitch-HP Pin Functional Description BYPASS (BP) Pin: An external bypass capacitor is connected to this pin for the internally generated 5.75 V supply. Based on the connected capacitance determined at start-up, it will provide either auto-restart or latching shutdown option dependant on the fault condition. Please see Table 3. COMPENSATION (CP) Pin: This pin is the output of transconductance amplifier. An RC compensation network on this pin provides control loop compensation. DRAIN (D) Pin: This pin is the high-voltage power MOSFET drain connection. It also provides internal operating current for start-up until output is in regulation. FEEDBACK (FB) Pin: The FEEDBACK pin is used to sense output and input voltage by sensing the auxiliary winding voltage. During MOSFET on-time, the current out of the FEEDBACK pin is sensed to detect the line voltage. During the secondary rectifier conduction time, the feedback voltage is proportional to the output voltage via the turns ratio between the bias and secondary windings. PROGRAM (PD) Pin: This MULTI-FUNCTIONAL pin sets device current limit and optional shutdown delay time extension. During start-up, the E Package (eSIP-7C) Exposed Pad (Hidden) Internally Connected to SOURCE Pin 12345 7 P F CB S D DBP P Exposed Pad Internally Connected to SOURCE Pin V Package (eDIP-12B) S 12 1 PD S 11 2 FB S 10 3 CP S9 4 BP S8 S7 Exposed Pad (On Bottom) Internally Connected to SOURCE Pin 6D K Package (eSOP-12B) PD 1 12 S FB 2 11 S CP 3 10 S BP 4 9S 8S D6 7S PI-6564-081412 Figure 4. internal circuit decodes the current limit based on resistor loaded on the PROGRAM pin. Please see Table 4. It can also be used for optionally extending shutdown delay time by changing the capacitance on the pin. See Figure 6. SOURCE (S) Pin: This pin is the power MOSFET source connection. It is also the ground reference for the BYPASS, FEEDBACK, PROGRAM and COMPENSATION pins. Functional Description A LinkSwitch-HP device monolithically integrates a controller and high-voltage power MOSFET into one package. It has a newly developed analogue control scheme, which enables continuous conduction mode (CCM), primary side regulated (PSR) power supplies up to 90 W without the efficiency limitation of DCM or audible noise. It uses an enhanced peak current mode PWM control scheme with multi-mode operation. The multi-mode control engine uses the error amplifier output signal voltage at the COMPENSATION pin to set the operating peak current and switching frequency to maintain the output voltage in regulation as shown in Figure 5. For COMPENSATION pin voltages lower than VC(MCM) (typ. 1.25 V) the device enters multi-cycle modulation (MCM) with a fixed peak current of 25% of the programmed current limit. Several innovative improvements have been added to the peak current mode control to allow primary side regulated CCM operation with no instability. The device meets less than 30 mW input power with no-load at high-line (LNK67xx families). It also offers extensive built-in features: • External current limit selection. • Optional programmable shutdown delay time extension. • Optional remote On/Off. • Optional fast AC reset. • Primary-side sensed output overvoltage protection (OVP) . • Lost regulation protection during output overload or short-circuit (auto-restart). • Internal current limit over line compensation for constant overload power over line. • High-voltage bus overvoltage sense (line OV) for extended line surge withstand. • High-voltage bus undervoltage sense (line UV) for brown-in/ out protection. • Accurate over-temperature protection (OTP). • Output OVP/OCP/OTP shutdown type selection (hysteretic/ latching). • Optional external latching shutdown input (current threshold) • Cycle-by-cycle current limit control. Regulator/Shunt Voltage Clamp The internal 5.75 V regulator charges the bypass capacitor connected to the BYPASS pin to 5.75 V by drawing a current from DRAIN whenever the power MOSFET is off. When the power MOSFET is on, the device operates from the energy stored in the bypass capacitor. In addition, there is a shunt regulator clamping the bypass at 6.4 V when supply current is provided by a bias winding through an external resistor. This makes the device insensitive to bias winding voltage variations. Pin Configuration. 3 www.powerint.com Rev. C 03/14 LinkSwitch-HP current limit in less than time tON(SOA). This prevents excessive drain currents during start-up and output short-circuit conditions by providing additional time for the primary inductance to reset. The SOA protection is disabled when the output voltage is within 7.5% of regulation voltage. Normalized Peak Current Frequency (kHz) 132 fSW(LF) 32 Compensation Voltage (∝ POUT) 100% 50% 25% VC(MIN) VC(MCM) VC(MAX) Compensation Voltage (∝ POUT) PI-6722-111212 Figure 5. Compensation Pin Characteristics (Multi-Mode Operation). Auto-Restart In the event of an open-loop fault (no connection between the feedback winding and the feedback divider network or the FEEDBACK pin to the feedback network), the sensed current out of FEEDBACK pin will be zero during MOSFET on-time, the device enters into line brown-out protection (line UV). In the event of output short-circuit or overload condition, the device enters into auto-restart mode. Auto-restart minimizes the power dissipation under fault conditions, the device will turn on and off at duty cycle of typically 3% as long as the fault condition persists. In auto-restart switching is disabled for t AR(OFF)1 (typ. 150 ms) when the FEEDBACK pin voltage has dropped below the auto-restart threshold VFB(AR) for the shutdown default delay time t AR(ON) (typ. 35 ms). After this period switching is enabled again with the device entering soft-start (typ. 15 ms). For the first auto-restart off-period switching is disabled for a reduced time t AR(OFF)2 (typ. 1500 ms) to reduce the power supply restart time during line cycling. Optionally the default shutdown delay time can be extended by adding a capacitor to the PROGRAM pin. Hysteretic Thermal Shutdown The thermal shutdown circuitry senses the controller die temperature. The threshold is set at 142 °C with a 75 °C hysteresis (both typical). Once the device temperature rises above 142 °C, the power MOSFET is disabled and remains disabled until the die temperature falls by 75 °C, at which point the device is re-enabled. The large hysteresis maintain the average temperature below the temperature rating of low cost CEM type PCB material in most cases. Safe Operating Area (SOA) Protection The device features a safe operating area (SOA) protection mode which disables MOSFET switching for 4 consecutive cycles in the event the peak switching current reaches the Sample and Hold (S/H) The sample and hold block senses the output voltage at auxiliary winding during secondary rectifier on-time. The FEEDBACK pin voltage is sampled after the turn-off of the internal switch to compensate for diode conduction time differences. Sampling time increases monotonically from 1.2 ms at no or light load to 2.5 ms at full load. Sampled voltage is held until the next clock cycle. The output of S/H is fed to the error amplifier, once in regulation the sampled voltage is 2 V. BYPASS (BP) Programming This feature selects either hysteretic or latching OVP/OCP and OTP protection based on capacitor loading on the BYPASS pin. The shutdown type is determined at the device power-up as shown in Table 3. CBP 0.47 mF 4.7 mF 47 mF OVP Lost Regulation (SC, OC) OTP Latching Auto-Restart Latching Auto-Restart Auto-Restart Latching Table 3. Latching Hysteretic Latching Shutdown Type vs. Value of BYPASS Pin Capacitance. Current Limit Setting During power-up the cycle-by-cycle current limit is determined by measuring the resistor value connected to the PROGRAM pin by the measurement is performed by applying 1.25 V (see Figure 10). The current limit can be set between 40% to 100% in steps of 10% as shown in Table 4. After the current limit is set the PROGRAM pin voltage is reduced to ~0 in order to minimize power dissipation. IPD RPD ILIMIT(NORM) IPD RPD ILIMIT(NORM) mA 10 16 24 36 kW 124 78.7 52.3 34.8 % 100 90 80 70 mA 54 83 125 kW 23.2 15.0 10.0 % 60 50 40 Table 4. Current Limit Selection vs. Program Pin Resistor Value. Programmable Shutdown Delay The default auto-restart shutdown delay time tSD(AR) (typ. 35 ms) can optionally be extended by connecting a capacitor to the PROGRAM pin. Once a lost regulation fault is detected the PROGRAM pin voltage is cycled 128 times between VPD(DL) (typ. 0.5 V) and VPD(DU) (typ. 1.2 V) as shown in Figure 10. Figure 6 depicts the relationship between extended shutdown delay time, added PROGRAM pin capacitor and current limit programming resistor. 4 Rev. C 03/14 www.powerint.com LinkSwitch-HP 500 PI-6646-040412 Auto-Restart On-Time Extension (ms) Remote On/Off and Fast AC Reset The PROGRAM pin can be used to turn on/off the device remotely. If the voltage on the pin is set to 1.35 V externally, the device stops switching. After releasing the PROGRAM pin the PROGRAM pin device commences switching when the voltage drops below 0.535 V. PROGRAM Pin Resistor Value 450 124 kΩ 78.7 kΩ 52.3 kΩ 34.8 kΩ 23.2 kΩ 15.0 kΩ 10.0 kΩ 400 350 300 At power-up the current out of the FEEDBACK pin has to exceed the line undervoltage turn-on threshold (brown-in) current IFB(UVREF) = -250 µA (typ.) before switching is enabled. During normal operation switching is disabled if the FEEDBACK pin current falls below the line undervoltage turn-off threshold (brown-out) current IFB(UVOFF) = -100 µA (typ.) for at least 8 consecutive switching cycles. After switching has ended, the device enters auto-restart. The applicable auto-restart offperiod t AR(OFF) 1 = 150 ms (typ.). NS NP 250 D CO VO 200 150 100 D 50 10 T1 U1 100 S PROGRAM Pin Capacitor Value (nF) 100 Figure 8. 90 80 -300 -450 -600 -750 -900 CP -1050 RFB2 PI-6837-120312 PI-6721-040412 110 70 -150 PD RFB1 FB VFB Optional Shutdown Time Extension Programming. The PROGRAM pin can also be used to reset the device latch after a latching OVP or OTP event. If the voltage on the pin is set to 3.4 V externally, the device latch is reset. Once the voltage drops below 0.535 V, device will start switching. -1200 FEEDBACK Pin Current During MOSFET On-Time Figure 7. BP CONTROL 0 Figure 6. VAUX NA 1 Normalized Set Current Limit (%) VSEC VBUS Current Limit Compensation Over Line. High-Voltage Bus Sensing LinkSwitch-HP senses indirectly the HV voltage bus VBUS during the power MOSFET on-time by monitoring the current flowing out of the FEEDBACK pin. During the MOSFET on-time the voltage across the auxiliary winding is proportional to the voltage across the input winding. The current flowing through resistor RFB1 (see Figure 8) is therefore representing VBUS. Indirect line sensing minimizes power dissipation and is used for line UV or line OV protection and current limit compensation over line. Indirect High-Voltage Bus Sensing. Switching is also stopped if the FEEDBACK pin current exceeds the line overvoltage threshold current IFB(OV) = -1.15 mA (typ.) for at least 2 consecutive switching cycles. Current Limit Compensation Over Line The high-voltage bus is sensed by means of measuring the current out of the FEEDBACK pin during the MOSFET on-time. To limit available overload power over line the set current limit is compensated as shown in Figure 7. The compensation is disabled at peak currents below 50% of the set current limit, and is re-enabled at 62.5% of the set current limit. Soft-Start A digital soft-start is implemented to reduce component stress at power supply start-up. The internal reference voltage will ramp up to 2 V during tSOFT (typ. 15 ms) at start-up. The loop will typically close (output reaches regulation) during this time to ensure smooth output voltage rise. Fault Filter This is the digital filter to handle all the fault conditions including line overvoltage, line undervoltage, output overvoltage, and output undervoltage, thermal shutdown as well as package level fault (pin open-circuit or pin to pin short-circuit). Transconductance Amplifier The controller uses a high gain (typ. 70 dB) transconductance amplifier to ensure exceptional output regulation. 5 www.powerint.com Rev. C 03/14 LinkSwitch-HP 1. Startup 26. Pause 150 ms (Auto-Restart Off Period (tAR(OFF)) No 2. Latching Shutdown? (CBF = 47 µF) Yes 3. AC Present? (IFB > -250 µA) Yes 4. Start Switching (With 15 ms Soft-Start) 5. Line OV? (IFB > -1.15 mA for 2 Cycles) No Yes No Yes 11. AC Present? (IFB > -250 µA) 6. Brown-Out? (IFB < -100 µA for 8 Cycles) No No 27. Pause 150 ms (Auto-Restart Off Period tAR(OFF)1) 7. Regulation Lost? (VFB < 1.85 V for 35 ms) Yes 14. Line OV? (IFB > -1.15 mA for 2 Cycles) 12. Start Switching (With 15 ms Soft-Start) No No Yes Yes 20. Start Switching (With 15 ms Soft-Start) 8. Stop Switching 15. Brown-Out? (IFB < -100 µA for 8 Cycles) No No Yes 16. Regulation Lost? (VFB < 1.85 V for 35 ms) 21. Line OV? (IFB > 1.15 mA for 2 Cycles) 9. Latch Reset? (VPD > 3.4 V) No Yes Yes No 10. Reset Latch Yes 22. Brown-Out? (IFB < -100 µA for 8 Cycles) PI-6838-101812 17. Stop Switching No 23. Regulation Lost? (VFB < 1.85 V for 35 ms) No 18. Pause 150 ms (Auto-Restart Off Period tAR(OFF)1) Yes 24. Stop Switching 19. AC Present? (IFB > -250 µA) No Yes 25. Pause 1500 ms (Auto-Restart Off Period tAR(OFF)2) Figure 9. Line Sensing and Auto-Restart Flow Chart. 6 Rev. C 03/14 www.powerint.com LinkSwitch-HP SW VFB Fast AC Reset VPDTHACR 3.40 V VPDI VPDTHRM 1.35 V VPDTHPDH 1.25 V tPD Programmable Shutdown Delay ID ILIMIT Remote On/Off tPDST VPDTHPDL 0.535 V t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 PI-6692-101713 Figure 10. PROGRAM (PD) Pin Timing Diagram. OSC This is an adjustable frequency oscillator. Based on error voltage, the frequency will adjust from 32 kHz at light load to 132 kHz at heavy load. The oscillator employes ±5 kHz frequency jitter to reduce EMI levels. Current Limit Comparator This is a high-speed current limit comparator. It compares the current from the power MOSFET to the internal current reference. Once the current reaches the threshold the MOSFET on-cycle is terminated. Multi-Cycle Modulation (MCM) When voltage on COMPENSATION pin reaches VC(MCM) (about 1.25 V) the peak drain current is reduced to 25% of programmed value and the switching frequency approaches fMCM = 32 kHz (typical). During MCM operation the controller intelligently maintains a relatively high output sampling rate while reducing the average switching frequency to keep the output voltage in regulation. Switching at 25% of the set current limit reduces the transformer core flux density significantly. This and the intelligent MCM operation reduce audible noise well below acceptable levels. LNK666x has a maximum MCM off-time TMCM(OFF) = 0.5 ms (typ.). The high minimum output sampling rate provides excellent transient load response from 0% to 50% or 100% of nominal load while offering typically below 100 mW no-load input power. LNK67xx has a maximum MCM off-time TMCM(OFF) = 4 ms (typ.). The lower minimum output sampling rate enables designs below 30 mW no-load input power while providing fair transient load performance for load steps from 0% to 50% or 100% of nominal load. 7 www.powerint.com Rev. C 03/14 LinkSwitch-HP Applications Example the FEEDBACK pin. This sensing is accomplished by periodically turning on the power MOSFET to sense input voltage condition with very short low frequency sampling pulses. During the forward pulse sampling time the FEEDBACK pin is held to zero volts by an internal clamp. When negative forward pulse current exceeds 250 mA, LinkSwitch-HP for two consecutive switching cycles will initiate start-up with a soft-start sequence that reduces component stress and allows the output to rise in a smooth monotonic manner. The desired input voltage for start-up is determined by the turns ratio of primary winding to feedback winding and the value of R19. 30 W, 12 V Universal Adapter The circuit shown in Figure 11 is a high efficiency universal input 30 W, 12 V output adapter using the LNK6766E. The supply uses primary winding coupled sensing for the following features: output regulation, line undervoltage lockout, input and output OVP. With primary winding sense there is no need for an external secondary referenced error amplifier such as a TL431 and optocoupler. The winding sense of bus voltage also eliminates the need for direct input voltage sensing which requires more components and is more dissipative than winding sense method. Regulation is accomplished by sampling the feedback winding during flyback period through the resistor divider R19 and R20 through FEEDBACK pin. This sampled voltage is compared to an internal error amplifier threshold of 2 V. The value of R19 is already determined by the line undervoltage function so the output regulation point is determined by setting the proper value for R20. Output regulation is ±5%, active-on efficiency is 86% and no-load input power is less than 30 mW. The rectified and filtered input voltage is applied to the primary winding of T1. The other side of the primary is driven by the integrated power MOSFET in U1. Diode D1, C3, R2, R3 and VR1 comprise the clamp circuit, limiting the leakage inductance turn-off voltage spike to safe value. Zener diode VR1 also helps to reduce input power consumption during no-load conditions. The loop compensation is provided by the network from COMPENSATION pin to ground. In the case above, a low frequency to mid frequency gain of 20 dB for the error amplifier is established by R7 and C7. Capacitor C8 functions essentially as a noise filter and is typically 100 pF. There is also an internal 16 kHz filter within the device. It is advised to limit R7 to no greater than 260 kW to avoid stability and noise sensitivity. Start-up of the power supply is initiated by sensing the forward negative pulse current from feedback winding through R19 into C18 2.2 nF 250 VAC 9 C12 1000 µF 16 V VR1 BZG03C130 130 V R29 R30 3.3 MΩ 3.3 MΩ F1 2A J1 90 - 265 VAC D 6 RTN D2 BAV21WS7-F 8 C6 22 µF 16 V R9 4.3 kΩ 1% 1/8 W T1 RM8 R19 41.2 kΩ 1% BP CONTROL S J2 C22 10 µF 16 V J4 D1 DL4937 LinkSwitch-HP U1 LNK6766E R28 27 kΩ FL2 7 C2 68 µF 400 V C14 150 nF 275 VAC 12 V, 2.5 A J3 C3 10 nF 630 V R2 100 Ω 1/2 W L4 10 mH L5 100 µH FL1 D8 STPS30100ST R3 3 kΩ BR2 DF206ST-G 600 V C13 R13 680 pF 20 Ω 100 V 1/8 W PD C20 4.7 nF 50 V R8 23.2 kΩ 1% 1/8 W FB CP R7 100 kΩ 1/8 W C7 100 nF 25 V C23 10 pF 50 V C8 100 pF 50 V R20 10.2 kΩ 1% C5 470 nF 50 V PI-6844-120312 Figure 11. Schematic of a Universal Input 30 W, 12 V, 2.5 A Adapter. 8 Rev. C 03/14 www.powerint.com LinkSwitch-HP The transient load response is dependent on the loop gain and minimum switching frequency. The values of R7 and C7 shown here typically give good transient response for most designs. When the supply is at no-load, the minimum switching frequency at no-load will create a delay to respond to any step load event during the off-time. In the case above, the minimum frequency is 250 Hz so there is a potential 4 ms delay to response. If a faster response is desired from no-load initial condition there is the option to use the LNK666x which has a minimum frequency of 2 kHz. There is a trade-off in using this family as no-load input power will be slightly higher and a smaller pre-load resistor will be required. BYPASS pin to provide external bias. The external bias current should set via R9 to be at least 500 mA to guarantee the internal current source of LinkSwitch-HP is turned off as this will allow the supply to operate more efficiently, especially at light load. For best no-load performance the external supply voltage across C6 should be minimized (typically 8-9 V) and the current into the BYPASS pin set by R9 should be as low as possible. Input overvoltage protection is done through sensing the negative forward pulse of feedback winding. When the negative forward voltage is sufficiently high to produce more than 1.15 mA current into the FEEDBACK pin, for 2 consecutive on-cycles the device will stop switching for auto-restart delay period. In order to have good efficiency, regulation performance and stability, the transformer leakage inductance should be minimized. Low leakage will minimize ringing on the sense winding which can create an error in the feedback sampling. The example above uses split primary winding technique to lower leakage inductance. Leakage inductance should not be greater than 2% of nominal primary inductance and 1% is typically the desirable target value. Output overvoltage protection is achieved by sensing the flyback pulse through the FEEDBACK pin. When the FEEDBACK pin sees 2.5 V or greater for 16 consecutive cycles, the supply will latch off. If non-latching OVP is desired then changing C5 from 0.47 mF to 4.7 mF will change fault mode accordingly (see Table 3 for details). Resistor R28 serves as a pre-load resistor to minimize output voltage rising in no-load condition. The pre-load resistor should be no smaller than is necessary to maintain output within specification limits to minimize added dissipation. In this example, the added pre-load dissipation is only 4.8 mW. LinkSwitch-HP provides an internal current source to bias the BYPASS pin which is necessary for start-up. When the supply is operating and in regulation an external bias is provided from the rectified flyback voltage from the bias winding (D2 and C6). Resistor R9 is sourced from the bias voltage across C6 into the OCP protection is accomplished by sensing when the output drops below 0.925 of nominal regulation value for a duration greater than specified delay time. In the example above, the total delay time is about 50 ms. Capacitor C20 extends the default internal delay time of 35 ms (see Figure 6 for details). The latching shut-off option is used in the design above. The primary current limit of LinkSwitch-HP can be adjusted by selecting the value for R8 (see Table 4 for details). For this design 60% of maximum current limit was chosen. A lower current limit setting is typical for an adapter where lower RDS(ON) is desirable for higher efficiency and also lower thermal rise of LinkSwitch-HP. 9 www.powerint.com Rev. C 03/14 LinkSwitch-HP Layout Considerations for eSIP-7C Package Figure 12 is the layout for a 30 W adapter shown in the schematic Figure 11. An eSIP-7C package is used as indicated by the suffix in LNK6766E which allows the use of a stand-up heat sink. The mounting pin for the heat sink should be electrically isolated. It can be seen that the primary return trace wraps around the LinkSwitch-HP device which acts as a shield around the critical external control related components of LinkSwitch-HP. These components include R7, R8, R19, R20 and C5, C8, C20. Of particular importance is placing the bypass capacitor C5 and COMPENSATION pin noise filter capacitor C8 as close as possible to SOURCE pin with very short trace lengths to COMPENSATION and BYPASS pins as shown. If an electrolytic capacitor is selected as the bypass capacitor (C5) then an additional 100 nF (C5) ceramic must also be fitted. The ground trace wrap, tight layout and single point grounding to SOURCE pin of these components avoids having noise related issues during peak loads or during line transient such as surge or ESD events. Another consideration for ESD and line surge is the primaryside termination of the Y capacitor. The Y capacitor C18 should be tied to the positive terminal of the bulk capacitor C2 in order to route the potential of high currents away from the more sensitive primary return traces. Because of the tight layout common to adapter applications, this design uses triple insulated wire and flying leads for output winding termination to avoid secondary arcing to core during ESD events. The trace connecting the drain to transformer should be very short and the primary clamp circuitry should be grouped together and away from the more sensitive components. The bias winding return and return of bias capacitor C6 should be routed separately to the negative terminal of the input capacitor C2 away from SOURCE pin. The secondary rectifying loop that includes the secondary winding, the output diode D8, and the first output capacitor C13 should be as tight as possible to minimize adding series inductance which can reduce high load efficiency and degrade the quality of regulation. Figure 12. Layout for 30 W Adapter Using a eSIP-7C Package (View From Bottom Copper Layer). 10 Rev. C 03/14 www.powerint.com LinkSwitch-HP Layout Considerations for eDIP-12B package Quick Design Checklist The schematic extract in Figure 13 is an example of LinkSwitch-HP used in a dual output LCD monitor supply using eDIP-12B package. In this design the exposed metal tab on the topside of package is left open (no heat sink). The SOURCE pins of LinkSwitch-HP provide heat sinking through connection to the source copper pad of PCB. This technique is adequate for device dissipation up to 0.85 W (1/2 square inch of copper area required). The layout guidelines described for eSIP-7C are the same for eDIP-12B with an added consideration about sensitive component layout. The return referenced components C4, C8, C16, R9, R7 must be placed directly under the LinkSwitch-HP BR1 DF06M package as shown in Figure 14. This requires that these 600 V particular components be SMD type as this allows an ideal noise-immune layout. All LinkSwitch-HP designs should be verified on the bench particularly for specified worst-case stress conditions. The following set of tests are strongly recommended: R10 Output Power Table Assumptions • • • • • • • L1 10 mH 12 V output. C1 Schottky rectification. 100 nF 310 VAC 82% efficiency. VOR = 135 V. RT1 F1 for 195-265 KP = 0.4 for 85-265 VAC input and KP = 0.6 tVAC 5Ω 2A input. 90 - 265 VMIN = 100 V for 85-265 VAC input and VMIN = 250 V for VAC J1-3 J1-1 195-265 VAC input. 0.85 W device dissipation for open frame designs with PCB heat sink. C9 1 nF 250 VAC 10 Ω C10 1% 470 pF 1/8 W 200 V 1. Maximum drain voltage – Verify that VDS does not exceed 675 V for LNK677X series6 and12600 V for LNK6X6X series. D3 This gives a 50 V margin for design variations. 30BQ100PBF R2 R3 R1 2. Under all conditions, the maximum Drain current should be 100 Ω 100 Ω R12 3 kΩ C15 1% 1% 10 Ω below the specified absolute maximum ratings. 1% 470 pF L2 1/8 W 200 V Ferrite Bead 3. Thermal check – At rated maximum output power, minimum VR1 (3.5 × 4.45 mm) C3 P6KE130A 7,8 input voltage 10 and nF maximum ambient temperature, verify that 130 V 630 V D4 the maximum allowed temperature is not exceeded for any C13 B340LB-13-F 820 µF component in the design. Of particular importance is 6.3 V R4 9,10 checking the 20 temperature rise of the major power conversion Ω 1% 3 components such as transformer, outputD2diodes, input BAV21WS- C6 bridge, primaryD1clamp circuit and LinkSwitch-HP. 7-F 22 µF Under the R5 25 V DL4937 stated conditions above, LinkSwitch-HP tab temperature 6.98 kΩ C2 1% 5 1 47 µF 1/8 W should not exceed 110 °C. T1 450 V EF25 D O LinkSwitch-HP U1 LNK6774V C4* BP CONTROL S R6 23.2 kΩ 1% 1/16 W R8 46.4 kΩ 1% 1/16 W PD FB C5 4.7 µF 10 V CP R7 100 kΩ 1% 1/16 W C7 100 nF 25 V C16 10 pF 50 V C8 100 pF 50 V R9 10.5 kΩ 1% 1/16 W PI-6860-120312 *Optional PI-6860-120312 Figure 13. 17 W LCD Monitor Supply (+18 V, +5 V). Figure 14. Layout for LCD Monitor Supply Using eDIP-12B Package. 11 www.powerint.com Rev. C 03/14 C11 220 µ 35 V C14 820 µ 6.3 V LinkSwitch-HP Absolute Maximum Ratings(3) DRAIN Pin Voltage.................................... -0.3 V to 725 V (677x) DRAIN Pin Voltage...........................-0.3 V to 650 V (666x/676x) DRAIN Pin Peak Current: ……………………........... 1.6 x ILIMIT(TYP)(1) BYPASS Pin Voltage .............................................. -0.3 V to 9 V BYPASS Pin Current ..................................................... 100 mA FEEDBACK Pin Voltage ........................................ -0.3 V to 9 V(2) COMPENSATION Pin Voltage ................................ -0.3 V to 9 V PROGRAM/DELAY Pin Voltage............................... -0.3 V to 9 V Storage Temperature....................................... -65 °C to 150 °C Operating Junction Temperature ................... -40 °C to 150 °C(4) Notes: 1. Peak DRAIN current is allowed while the DRAIN voltage is simultaneously less than 400 V. 2. -1 V for current pulses ≤5 mA out of the pin and a duration of ≤500 ns. 3. Maximum ratings specified may be applied one at a time without causing permanent damage to the product. Exposure to Absolute Maximum Rating conditions for extended periods of time may affect product reliability. 4. Normally limited by internal circuitry. Thermal Resistance Thermal Resistance: E Package (qJA)........................................... 105 °C/W(1) (qJC)............................................... 2 °C/W(2) K Package (qJA) ...........................45 °C/W(3), 38 °C/W(4) (qJC)............................................... 2 °C/W(2) V Package (qJA) ............................74 °C/W(3), 63 °C/W(4) (qJC)............................................... 2 °C/W(2) Notes: 1. Free standing with no heat sink. 2. Measured at the back surface of tab. 3. Soldered (including exposed pad for K package) to typical application PCB with a heat sinking area of 0.36 sq. in. (232 mm2), 2 oz. (610 g/m2) copper clad. 4. Soldered (including exposed pad for K package) to typical application PCB with a heat sinking area of 1 sq. in. (645 mm2), 2 oz. (610 g/m2) copper clad. Symbol Conditions SOURCE = 0 V; TJ = -40 to 125 °C (Unless Otherwise Specified) Min Typ Max Units Switching Frequency fOSC Average value, TJ = +25 °C, 120 132 136 kHz Switching Frequency Temperature Variation ΔfOSC 0 °C ≤ TJ ≤ +100 °C, See Note A ±10 % Frequency Jitter Deviation Δf fOSC = 128 kHz Frequency Jitter Modulation Rate fM Parameter Control Functions Maximum Duty Cycle DCMAX Maximum Duty Cycle Temperature Variation ∆DCMAX VFB < VFB(REF) VFB(REF) = 2 V TJ = +25 °C 62 ±5 kHz 250 Hz 64 See Note A 0 °C ≤ TJ ≤ +100 °C 66 % +2% % Minimum Peak Current to Set Current Limit Ratio kPS TJ = +25 °C di/dt(KPS) = di/dt(ILIMIT) 22.5 25 % Multi-Cycle Modulation Switching Frequency fMCM TJ = +25 °C 25 32 kHz Multi-Cycle Modulation Max Off-Time TMCM(OFF) Soft-Start Time tSOFT TJ = +25 °C 15 ms Auto-Restart ShutDown Default Delay tSD(AR) TJ = +25 °C 35 ms tAR(ON) TJ = +25 °C, tSOFT + tSD(AR) 50 TAR(OFF)1 First switch off-period 150 TAR(OFF)2 Subsequent switch off-periods 1500 Auto-Restart TJ = +25 °C LNK666x 0.5 LNK67xx 4 ms ms 12 Rev. C 03/14 www.powerint.com LinkSwitch-HP Symbol Conditions SOURCE = 0 V; TJ = -40 to 125 °C (Unless Otherwise Specified) Min Typ Max Units gM TJ = +25 °C 95 115 125 μA/V Transconductance Amplifier Gain Temperature Variation ΔgM 0 °C ≤ TJ ≤ +100 °C See Note A ±20 % Transconductance Amplifier Max Output Current IGM TJ = +25 °C 10.0 15.0 μA COMPENSATION Pin Input Impedance ZCP See Note A 30 OVP/UVP/OTP Programming Capacitor Value CBP TJ = +25 °C See Table 3 for programming BYPASS Pin Voltage VBP 5.46 5.75 6.04 V BYPASS Pin Voltage Hysteresis VBPH 0.85 0.95 1.1 V LNK6xx3 -6.8 -4.8 -2.0 LNK6xx4-5 -9.2 -6.6 -2.8 LNK6xx6-7 -12.0 -8.3 -4.3 LNK6xx3 -4.7 -2.7 -1.5 LNK6xx4-5 -7.0 -4.0 -2.2 LNK6xx6-7 -8.8 -5.2 -2.9 5.7 8.2 10.7 Parameter Control Functions (cont.) Transconductance Amplifier Gain 12.5 MW Bypass (BP) Input 0.47 47 ICH1 BYPASS Pin Charge Current ICH2 BYPASS Pin Shutdown Threshold Current IBPSD BYPASS Pin Shutdown Delay BYPASS Pin Source Current BYPASS Pin Charge Current Temperature Variation BYPASS Pin Shunt Voltage BYPASS Pin Supply Current mF 4.7 VBP = 0 V TJ = +25 °C VDS ≥ 50 V VBP = 5 V TJ = +25 °C VDS ≥ 50 V TJ = +25 °C TJ = +25 °C VBP = 6 V TJ = +25 °C ΔIBPSC See Note A VBP(SHUNT) IBP = 2 mA IBPS1 TJ = +25 °C, See Note B IBPS2 MOSFET switching at fOSC -0.5 0.5 6.1 6.4 mA mA Switching Cycles 8 IBPSC mA mA %/°C 6.7 V 525 mA LNKxxx3 0.9 1.2 LNKxxx4 1.0 1.3 LNKxxx5 1.1 1.4 LNKxxx6 1.3 1.6 LNKxxx7 1.4 1.7 mA 13 www.powerint.com Rev. C 03/14 LinkSwitch-HP Symbol Conditions SOURCE = 0 V; TJ = -40 to 125 °C (Unless Otherwise Specified) Min Typ Max Units VFBth TJ = +25 °C 1.974 2.000 2.026 V FEEDBACK Pin Reference Voltage Temperature Variation ΔVFB(th) 0 °C ≤ TJ ≤ +100 °C See Note A -0.01 %/°C Line Undervoltage Turn-On Threshold Current IFB(UV,REF) TON = 220 ns, TJ = +25 °C -250 mA FEEDBACK Pin Bus Voltage Reference Current Temperature Variation ΔIFB(REF) TON = 220 ns, 0 °C ≤ TJ ≤ +100 °C See Note A Line Undervoltage Turn-Off Threshold Current IFB(UVOFF) TON = 220 ns, TJ = +25 °C Parameter Voltage Sense (FB) Input FEEDBACK Pin Reference Voltage Line Undervoltage Turn-Off Delay Line Overvoltage Turn-Off Threshold Current TJ = 25 °C IFB(OV) Line Overvoltage Turn-Off Delay Output Overvoltage Detection Threshold Voltage -115 Output Overvoltage Detection Delay TON = 220 ns, TJ = +25 °C TJ = +25 °C TJ = +25 °C Current Limit Reduction Onset Threshold Current IFB(LIM) TON = 220 ns, TJ = +25 °C Current Limit Reduction Slope ILIM(LINE) Missing Feedback Voltage Protection Delay TSAMP1 TSAMP2 TMFVP 0 °C ≤ TJ ≤ +100 °C mA Switching Cycles -1150 -1100 2.5 1.794 1.85 2.625 V Switching Cycles 1.906 V mA -210 -463 mA < IFB ≤ IFB(LIM) -0.032 IFB < -463 mA -0.008 IPK = ISET 2.5 2.65 IPK = 0.25 × ISET 1.2 1.3 TJ = +25 °C mA Switching Cycles 16 VFB(AR) Missing Feedback Voltage Protection Sense Delay Time -1200 2.375 FEEDBACK Pin Auto-Restart Threshold Voltage FEEDBACK Pin Sampling Delay Time -85 2 TJ = +25 °C 0 °C ≤ TJ ≤ +100 °C % 8 TJ = +25 °C VFB(OVP) -100 ±10 %/mA ms 0.8 ms 4 Switching Cycles 14 Rev. C 03/14 www.powerint.com LinkSwitch-HP Symbol Conditions SOURCE = 0 V; TJ = -40 to 125 °C (Unless Otherwise Specified) Min Typ Max Units PROGRAM/DELAY Pin Voltage VPD TJ = +25 °C 1.20 1.25 1.30 V PROGRAM/DELAY Pin Time Lower Voltage Threshold VPD(DL) TJ = +25 °C 0.50 0.535 0.57 V PROGRAM/DELAY Pin Time Upper Voltage Threshold VPD(DU) TJ = +25 °C 1.20 1.25 1.30 V 3.06 3.4 3.74 V 1.25 1.35 1.45 Parameter Multi-Function (PD) Input Fast AC Reset Threshold VPDTHACR Remote On/Off Threshold VPDTHRM TJ = +25 °C Remote On/Off Delay Threshold Hysteresis 0.8 TJ = +25 °C V Switching Cycles 8 Circuit Protection Self Protection Current Limit ILIMIT LNK6xx3 di/dt = 180 mA/ms TJ = +25 °C 0.716 0.77 0.824 LNK6xx4 di/dt = 245 mA/ms TJ = +25 °C 0.967 1.04 1.113 LNK6xx5 di/dt = 305 mA/ms TJ = +25 °C 1.209 1.30 1.391 LNK6xx6 di/dt = 460 mA/ms TJ = +25 °C 1.814 1.95 2.087 LNK6xx7 di/dt = 610 mA/ms TJ = +25 °C 2.418 2.60 2.782 A Programmed Current Limit Variation ΔILIMIT See Table 3 for programming 0 °C ≤ TJ ≤ +100 °C, See Note A ±7 % Operational Peak Current Variation ΔIPK(OP) IPK(OP) = 25 -100% × ILIMIT, 0 °C ≤ TJ ≤ +100 °C, See Note A ±7 % 150 °C Thermal Shutdown Temperature TSD Thermal Shutdown Hysteresis TSDH CBP = 0.47 μF or CBP = 4.7 μF Leading Edge Blanking Time tLEB TJ = +25 °C See Note A Current Limit Delay Time tILD TJ = +25 °C TON(MIN) tLEB(MAX) + tILD(MAX) TJ = +25 °C Minimum Switch ON-Time 135 175 325 142 75 °C 220 ns 100 ns 400 500 ns 15 www.powerint.com Rev. C 03/14 LinkSwitch-HP Parameter Symbol Conditions SOURCE = 0 V; TJ = -40 to 125 °C (Unless Otherwise Specified) Min Typ Max TJ = +25 °C 6.9 7.97 TJ = +100 °C 10.5 12.08 TJ = +25 °C 4.6 5.30 TJ = +100 °C 7.0 8.09 TJ = +25 °C 3.5 4.03 TJ = +100 °C 5.4 6.21 TJ = +25 °C 2.3 2.65 TJ = +100 °C 3.6 4.14 TJ = +25 °C 1.8 2.07 TJ = +100 °C 2.7 3.11 Units Output LNK6xx3 ID = 100 mA LNK6xx4 ID = 150 mA ON-State Resistance RDS(ON) LNK6xx5 ID = 200 mA LNK6xx6 ID = 300 mA LNK6xx7 ID = 400 mA OFF-State Drain Leakage Current Breakdown Voltage IDSS BVDSS VPD = Floating VDS = 560 V, TJ = 125 °C 470 mA VDS = 325 V, TJ = 100 °C 10 LNK677x, VPD = Floating, TJ = +25 °C 725 LNK666x/LNK676x, VPD = Floating, TJ = +25 °C 650 DRAIN Supply Voltage V 50 Rise Time tR Fall Time TF W Measured in a typical flyback Converter application V 100 50 ns NOTES: A. Parameter not tested over specified temperature range. Guaranteed by design and characterization. B. Average device switching frequency below 1 kHz. 16 Rev. C 03/14 www.powerint.com LinkSwitch-HP Figure 15. Duty Cycle Measurement. 17 www.powerint.com Rev. C 03/14 LinkSwitch-HP Typical Performance Characteristics 1.0 0 25 50 PI-6787-053112 1.00 95 90 85 80 75 100 125 150 -40 -20 0 Junction Temperature (° C) Drain Current (mA) PI-6850-071912 1200 Scaling Factors: LNK6xx3 1 LNK6xx4 1.5 LNK6xx5 2 LNK6xx6 3 LNK6xx7 4 800 600 400 TCASE=25 °C TCASE=100 °C 200 60 80 100 120 1000 Scaling Factors: LNK6xx3 1 LNK6xx4 1.5 LNK6xx5 2 LNK6xx6 3 LNK6xx7 4 100 10 1 0 0 2 4 6 8 0 10 100 DRAIN Voltage (V) 400 500 40 600 PI-6853-071812 1.2 Output Frequency (Normalized to 25 °C) PI-6852-071912 Scaling Factors: LNK6xx3 1 LNK6xx4 1.5 LNK6xx5 2 LNK6xx6 3 LNK6xx7 4 80 300 Figure 19. COSS vs. Drain Voltage. 160 120 200 Drain Voltage (V) Figure 18. Output Characteristic. Power (mW) 40 Figure 17. Standard Current Limit vs. Temperature. Drain Capacitance (pF) Figure 16. Breakdown vs. Temperature. 1000 20 Temperature (C) PI-6851-071912 0.9 -50 -25 1.05 Standard Current Limit (Normalized to 25 °C) PI-2213-012301 Breakdown Voltage (Normalized to 25 ° C) 1.1 1.0 0.8 0.6 0.4 0.2 0 0 0 100 200 300 400 Drain Voltage (V) Figure 20. Drain Capacitance Power. 500 600 -50 -25 0 25 50 75 100 125 150 Junction Temperature (°C) Figure 21. Frequency vs. Temperature. 18 Rev. C 03/14 www.powerint.com LinkSwitch-HP Typical Performance Characteristics 0.8 0.6 0.4 0.2 1.0 0.8 0.6 0.4 0.2 0 0 25 50 1.0 0.8 0.6 0.4 0.2 0 0 25 50 0.8 0.6 0.4 0.2 0 -50 -25 0.4 0.2 0 100 200 300 400 500 600 700 800 50 75 100 125 150 1.2 PI-6731-040212 DRAIN Current (Normalized to Absolute Maximum Rating) PI-6010-060410 DRAIN Current (Normalized to Absolute Maximum Rating) 0.6 Figure 26. Maximum Allowable Drain Current vs. Drain Voltage (LNK6773-6777). 25 Figure 25. Undervoltage Threshold vs. Temperature. 0.8 DRAIN Voltage (V) 0 Junction Temperature (°C) Figure 24. Overvoltage Threshold vs. Temperature. 0 75 100 125 150 1.0 Junction Temperature (°C) 1 50 1.2 75 100 125 150 1.2 25 Figure 23. Undervoltage Threshold vs. Temperature. PI-6855-071812 1.2 0 Junction Temperature (°C) Junction Temperature (°C) Figure 22. Overvoltage Threshold vs. Temperature. -50 -25 -50 -25 75 100 125 150 PI-6856-071812 0 Undervoltage Turn-Off Threshold (Normalized to 25 °C) -50 -25 Undervoltage Turn-On Threshold (Normalized to 25 °C) PI-6854-071812 1.0 1.2 Undervoltage Threshold (Normalized to 25 °C) PI-4761-061407 Overvoltage Threshold (Normalized to 25 °C) 1.2 1 0.8 0.6 0.4 0.2 0 0 100 200 300 400 500 600 700 DRAIN Voltage (V) Figure 27. Maximum Allowable Drain Current vs. Drain Voltage (LNK6763-6767/LNK6663-6667). 19 www.powerint.com Rev. C 03/14 LinkSwitch-HP eSIP-7C (E Package) C 2 A 0.403 (10.24) 0.397 (10.08) 0.264 (6.70) Ref. 0.081 (2.06) 0.077 (1.96) B Detail A 2 0.290 (7.37) Ref. 0.519 (13.18) Ref. 0.325 (8.25) 0.320 (8.13) Pin #1 I.D. 0.140 (3.56) 0.120 (3.05) 3 0.207 (5.26) 0.187 (4.75) 0.016 (0.41) Ref. 3 0.047 (1.19) 0.070 (1.78) Ref. 0.050 (1.27) 0.198 (5.04) Ref. 0.016 (0.41) 6× 0.011 (0.28) 0.020 M 0.51 M C FRONT VIEW 0.118 (3.00) SIDE VIEW 4 0.033 (0.84) 6× 0.028 (0.71) 0.010 M 0.25 M C A B 0.100 (2.54) BACK VIEW 0.100 (2.54) 10° Ref. All Around 0.021 (0.53) 0.019 (0.48) 0.050 (1.27) 0.020 (0.50) 0.060 (1.52) Ref. 0.050 (1.27) PIN 1 0.378 (9.60) Ref. 0.048 (1.22) 0.046 (1.17) 0.019 (0.48) Ref. 0.059 (1.50) 0.155 (3.93) 0.023 (0.58) END VIEW PIN 7 0.027 (0.70) 0.059 (1.50) Notes: 1. Dimensioning and tolerancing per ASME Y14.5M-1994. 2. Dimensions noted are determined at the outermost extremes of the plastic body exclusive of mold flash, tie bar burrs, gate burrs, and interlead flash, but including any mismatch between the top and bottom of the plastic body. Maximum mold protrusion is 0.007 [0.18] per side. DETAIL A 0.100 (2.54) 0.100 (2.54) MOUNTING HOLE PATTERN (not to scale) 3. Dimensions noted are inclusive of plating thickness. 4. Does not include inter-lead flash or protrusions. 5. Controlling dimensions in inches (mm). PI-4917-061510 20 Rev. C 03/14 www.powerint.com LinkSwitch-HP eSOP-12B (K Package) 0.356 [9.04] Ref. 0.004 [0.10] C A 2X 2 0.400 [10.16] Pin #1 I.D. (Laser Marked) 0.325 [8.26] Max. 7 2X 7 0.004 [0.10] C B 0.059 [1.50] Ref, Typ 0.460 [11.68] 0.059 [1.50] Ref, Typ 0.008 [0.20] C 1 2X, 5/6 Lead Tips 2 3 4 6 H 4 0.010 [0.25] 12 Gauge Plane 2 Seating Plane 0°- 8° 0.225 [5.72] Max. 7 6 1 0.120 [3.05] Ref BOTTOM VIEW 0.020 [0.51] Ref. 0.092 [2.34] 0.086 [2.18] 0.032 [0.80] 0.029 [0.72] 0.006 [0.15] 0.000 [0.00] Seating plane to package bottom standoff 0.004 [0.10] C C Seating Plane Detail A 0.217 [5.51] 0.022 [0.56] Ref. 0.016 [0.41] 0.011 [0.28] 11× END VIEW Land Pattern Dimensions 1 12 2 11 3 10 0.028 [0.71] 0.321 [8.15] 9 4 3 0.019 [0.48] Ref. 0.306 [7.77] Ref. SIDE VIEW 0.067 [1.70] 0.049 [1.23] 0.046 [1.16] 0.028 [0.71] Ref. 0.070 [1.78] TOP VIEW 0.098 [2.49] 0.086 [2.18] C 0.034 [0.85] 0.026 [0.65] DETAIL A (Scale = 9X) B 3 0.055 [1.40] Ref. 0.350 [8.89] 0.023 [0.58] 11× 0.018 [0.46] 0.010 (0.25) M C A B 0.010 [0.25] Ref. Notes: 1. Dimensioning and tolerancing per ASME Y14.5M-1994. 2. Dimensions noted are determined at the outermost extremes of the plastic body exclusive of mold flash, tie bar burrs, gate burrs, and interlead flash, but including any mismatch between the top and bottom of the plastic body. Maximum mold protrusion is 0.007 [0.18] per side. 3. Dimensions noted are inclusive of plating thickness. 4. Does not include interlead flash or protrusions. 5. Controlling dimensions in inches [mm]. 6 0.429 [10.90] 8 6. Datums A and B to be determined at Datum H. 7 7. Exposed pad is nominally located at the centerline of Datums A and B. “Max” dimensions noted include both size and positional tolerances. PI-5748a-100311 21 www.powerint.com Rev. C 03/14 LinkSwitch-HP eDIP-12B (V Package) 0.004 [0.10] C A Seating Plane 0.325 [8.26] Max. Pin #1 I.D. (Laser Marked) 10 2X 0.004 [0.10] C B 1 2 3 4 0.010 [0.25] Ref. 0.120 [3.05] Ref. 6 0.412 [10.46] Ref. 0.306 [7.77] Ref. 10 2 0.225 [5.72] Max. 0.350 [8.89] B 2 C 12 11 10 9 8 0.016 [0.41] 11× 0.011 [0.28] 6 TOP VIEW 0.104 [2.65] Ref. 5 °± 4° 0.059 [1.50] Ref, typ. 12 3 4 0.023 [0.58] 11× 0.018 [0.46] BOTTOM VIEW 0.092 [2.34] 0.086 [2.18] 0.049 [1.23] 0.046 [1.16] 0.022 [0.56] Ref. 0.020 [0.51] Ref. 0.070 [1.78] SIDE VIEW 0.07 [1.78] 8 0.192 [4.87] Ref. H 0.031 [0.80] 0.028 [0.72] 0.059 [1.50] Ref, typ. 0.010 [0.25] M C A B END VIEW 0.019 [0.48] Ref. 1 0.436 [11.08] 0.406 [10.32] 7 Detail A A 7 0.400 [10.16] 7 0.356 [9.04] Ref. 0.400 [10.16] 0.03 [0.76] 0.028 [0.71] Ref. DETAIL A (Scale = 9X) Mounting Hole Pattern Dimensions 0.400 [10.16] Drill Hole 0.03 [0.76] Round Pad 0.05 [1.27] Solder Mask 0.056 [1.42] Notes: 1. Dimensioning and tolerancing per ASME Y14.5M-1994. 2. Dimensions noted are determined at the outermost extremes of the plastic body exclusive of mold flash, tie bar burrs, gate burrs, and interlead flash, but including any mismatch between the top and bottom of the plastic body. Maximum mold protrusion is 0.007 [0.18] per side. 3. Dimensions noted are inclusive of plating thickness. 4. Does not include inter-lead flash or protrusions. 5. Controlling dimensions in inches [mm]. 6. Datums A and B to be determined at Datum H. 7. Measured with the leads constrained to be perpendicular to Datum C. 8. Measured with the leads unconstrained. 9. Lead numbering per JEDEC SPP-012. 10. Exposed pad is nominally located at the centerline of Datums A and B. “Max” dimensions noted include both size and positional tolerances. PI-5556a-100311 22 Rev. C 03/14 www.powerint.com LinkSwitch-HP Part Ordering Information • LinkSwitch Product Family • HP Series Number • Package Identifier E eSIP-7C K eSOP-12B V eDIP-12B • Tape & Reel and Other Options Blank LNK 6xx7 E TL TL Standard Configurations Tape & Reel 23 www.powerint.com Rev. C 03/14 Revision A A A B B C Notes Date Initial Release. Updated Table 2. Updated page 5. Formatting changes. KPS Min value updated. Fixed Table references. Released K package parts. Updated ΔVFB(th) Typ value on page 14. 08/12 08/23/12 10/24/12 12/04/12 02/26/13 03/14 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. Life Support Policy POWER INTEGRATIONS PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF POWER INTEGRATIONS. As used herein: 1. A Life support device or system is one which, (i) is intended for surgical implant into the body, or (ii) supports or sustains life, and (iii) whose failure to perform, when properly used in accordance with instructions for use, can be reasonably expected to result in significant injury or death to the user. 2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness. The PI logo, TOPSwitch, TinySwitch, LinkSwitch, LYTSwitch, DPA-Switch, PeakSwitch, CAPZero, SENZero, LinkZero, HiperPFS, HiperTFS, HiperLCS, Qspeed, EcoSmart, Clampless, E-Shield, Filterfuse, StakFET, PI Expert and PI FACTS are trademarks of Power Integrations, Inc. Other trademarks are property of their respective companies. ©2014, Power Integrations, Inc. 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