VIPer11 Energy saving off-line high voltage converter Datasheet - production data Applications * Low power SMPS for home appliances, home automation, industrial, consumer, lighting * Low power adapters SSOP10 Description Features * 800 V avalanche-rugged power MOSFET allowing ultra wide VAC input range to be covered * Embedded HV startup and sense-FET * Current mode PWM controller * Drain current limit protection - 480 mA (VIPER114) - 590 mA (VIPER115) * Wide supply voltage range: 4.5 V to 30 V * Minimized system input power consumption: - Less than 10 mW at 230 VAC in no-load condition - Less than 400 mW at 230 VAC with 250 mW load The device is a high voltage converter smartly integrating an 800 V avalanche-rugged power MOSFET with PWM current mode control. The power MOSFET with 800 V breakdown voltage allows the extended input voltage range to be applied, as well as the size of the DRAIN snubber circuit to be reduced. This IC meets the most stringent energy-saving standards as it has very low consumption and operates in pulse frequency modulation under light load. The design of flyback, buck and buck boost converters is supported. The integrated HV startup, senseFET, error amplifier and oscillator with jitter allow a complete application to be designed with the minimum number of components. Figure 1. Basic application schematic * Jittered switching frequency reduces the EMI filter cost: - 30 kHz 7% (type X) - 60 kHz 7% (type L) * Embedded E/A with 1.2 V reference * Protections with automatic restart: overload/short-circuit (OLP), line or output OVP, max. duty cycle counter, VCC clamp * Pulse-skip protection to prevent flux- runaway * Embedded thermal shutdown * Built-in soft-start for improved system reliability ". December 2018 This is information on a product in full production. DS11873 Rev 3 1/35 www.st.com Contents VIPer11 Contents 1 Pin setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 2 Electrical and thermal ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 3 Typical electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 4 General description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 5 6 4.1 Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 4.2 Typical power capability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 4.3 Primary MOSFET . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 4.4 High voltage startup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 4.5 Soft-start . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 4.6 Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 4.7 Pulse-skipping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 4.8 Direct feedback . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 4.9 Secondary feedback . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 4.10 Pulse frequency modulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 4.11 Overload protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 4.12 Max. duty cycle counter protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 4.13 VCC clamp protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 4.14 Disable function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 4.15 Auto-restart . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 4.16 Thermal shutdown . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 5.1 Typical schematics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 5.2 Energy saving performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 5.3 Layout guidelines and design recommendations . . . . . . . . . . . . . . . . . . . 30 Package information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 6.1 2/35 SSOP10 package information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 DS11873 Rev 3 VIPer11 Contents 7 Ordering information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 8 Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 DS11873 Rev 3 3/35 35 Pin setting 1 VIPer11 Pin setting Figure 2. Connection diagram Table 1. Pin description SSOP10 1 2 3 4 4/35 Name Function GND Ground and MOSFET source. Connection of source of the internal MOSFET and the return of the bias current of the device. All groundings of bias components must be tied to a trace going to this pin and kept separate from the pulsed current return. VCC Controller supply. An external storage capacitor has to be connected across this pin and GND. The pin, internally connected to the high voltage current source, provides the VCC capacitor charging current at startup. A small bypass capacitor (0.1 F typ.) in parallel, placed as close as possible to the IC, is also recommended, for noise filtering purpose. DIS Disable. If its voltage exceeds the internal threshold VDIS_th (1.2 V typ.) for more than tDEB time (1 ms, typ.), the PWM is disabled. An input overvoltage protection can be built by connecting a voltage divider between DIS pin and the rectified mains. In case of non-isolated topologies, with the same principle an output overvoltage protection can be implemented. If the disable function is not required, DIS pin must be soldered to GND, which excludes the function. FB Direct feedback. It is the inverting input of the internal transconductance E/A, which is internally referenced to 1.2 V with respect to GND. In case of nonisolated converter, the output voltage information is directly fed into the pin through a voltage divider. In case of primary regulation, the FB voltage divider is connected to the VCC. The E/A is disabled soldering FB to GND. 5 Compensation. It is the output of the internal E/A. A compensation network is placed between this pin and GND to achieve stability and good dynamic COMP performance of the control loop. In case of secondary feedback, the internal E/A must be disabled and the COMP directly driven by the optocoupler to control the DRAIN peak current setpoint. 6 to 10 MOSFET drain. The internal high voltage current source sinks current from this pin to charge the VCC capacitor at startup and during steady-state operation. These pins are mechanically connected to the internal metal PAD of the DRAIN MOSFET in order to facilitate heat dissipation. On the PCB a copper area must be placed under these pins in order to decrease the total junction-to-ambient thermal resistance thus facilitating the power dissipation. DS11873 Rev 3 VIPer11 2 Electrical and thermal ratings Electrical and thermal ratings Table 2. Absolute maximum ratings Parameter(1), (2) Symbol Pin VDS 6 to 10 Drain-to-source (ground) voltage IDRAIN 6 to 10 Pulsed drain current (pulse-width limited by SOA) VCC 2 VCC voltage ICC 2 VCC internal Zener current (pulsed) VDIS 3 DIS voltage VFB VCOMP 4 5 FB voltage COMP voltage Min. Max. Unit -0.3 800 V - 2 A -0.3 Internally limited V - 45(3) mA -0.3 5(4) V -0.3 5(4) V -0.3 5((4) V - 1(5) W PTOT - Power dissipation at Tamb < 50 C TJ - Junction temperature operating range -40 150 C TSTG - Storage temperature -55 150 C 1. Stresses beyond those listed absolute maximum ratings may cause permanent damage to the device. 2. Exposure to absolute-maximum-rated conditions for extended periods may affect the device reliability. 3. Pulse-width limited by maximum power dissipation, PTOT. 4. The AMR value is intended when VCC 5 V, otherwise the value VCC + 0.3 V has to be considered. 5. When mounted on a standard single side FR4 board with 100 mm (0.1552 inch) of Cu (35 m thick). Table 3. Thermal data Max. value Symbol Parameter Unit SSOP10 RthJP RthJA(1) Thermal resistance junction-pin 35 Thermal resistance junction-ambient (dissipated power 1 W) Thermal resistance junction-ambient (dissipated power 1 W)(2) 145 C/W 90 1. Derived by characterization. 2. When mounted on a standard single side FR4 board with 100 mm (0.1552 inch) of Cu (35 m thick). DS11873 Rev 3 5/35 35 Electrical and thermal ratings VIPer11 Figure 3. RthJA / (RthJA at A = 100 mm) Table 4. Avalanche characteristics Symbol Parameter Test conditions Min. Typ. Max. Unit IAR Avalanche current Repetitive and non-repetitive. Pulse-width limited by TJmax - - 0.8 A EAS Single pulse avalanche energy(1) IAS = IAR VDS = 100 V Starting TJ = 25 C - - 1 mJ Min. Typ. Max. Unit IDRAIN = 1 mA VCOMP = GND TJ = 25 C 800 - - V Drain-source leakage current VDS = 400 V VCOMP = GND TJ = 25 C - - 1 OFF-state drain current VDRAIN = max. rating VCOMP = GND TJ = 25 C - 1. Parameter derived by characterization. Electrical characteristics Tj = -40 to 125 C, VCC = 9 V (unless otherwise specified). Table 5. Power section Symbol Parameter Test conditions VBVDSS Breakdown voltage IDSS IOFF 6/35 DS11873 Rev 3 A - 45 VIPer11 Electrical and thermal ratings Table 5. Power section (continued) Symbol Parameter Test conditions RDS(on) Static drain-source ON-resistance COSS EQ Equivalent output capacitance Min. Typ. Max. IDRAIN = 295 mA TJ = 25 C - - 17 IDRAIN = 295 mA TJ = 125 C - - 34 VGS = 0 VDS = 0 to 640 V TJ = 25 C - 10 - Unit pF Table 6. Supply section Symbol Parameter Test conditions Min. Typ. Max. Unit 800 - - V - - 26 V M High voltage start-up current source VBVDSS_SU Breakdown voltage of start-up MOSFET VHV_START Drain-source start-up voltage TJ = 25 C - RG Start-up resistor VFB > VFB_REF VDRAIN = 400 V VDRAIN = 600 V 28 34 40 ICH1 VCC charging current at startup VDRAIN = 100 V VCC = 0 V 0.7 1 1.3 VCC charging current at startup VFB > VFFB_REF VDRAIN = 100 V VCC = 6 V 2 3 4 Max. VCC charging current in self-supply VFB > VFB_REF VDRAIN = 100 V VCC = 6 V 6.5 7.5 8.5 Operating voltage range VGND = 0 V 4.5 - 30 V VCCclamp Clamp voltage ICC = Iclamp_max 30 32.5 35 V Iclamp max Clamp shutdown current (2) 30 35 40 mA tclamp max Clamp time before shutdown - 400 500 600 s VCCon VCC start-up threshold VFB = 1.2 V VDRAIN = 400 V 15 16 17 V VCSon HV current source turn-on threshold VCC falling 4 4.25 4.5 V VCCoff UVLO VFB = 1.2 V VDRAIN = 400 V 3.75 4 4.25 V Quiescent current Not switching VFB > VFB_REF - 0.3 0.45 mA ICH2 ICH3(1) mA IC supply and consumptions VCC Iq DS11873 Rev 3 7/35 35 Electrical and thermal ratings VIPer11 Table 6. Supply section (continued) Symbol ICC Parameter Test conditions Operating supply current, switching Min. Typ. VDS = 150 V VCOMP = 1.2 V FOSC = 30 kHz - 1 VDS = 150 V VCOMP = 1.2 V FOSC = 60 kHz - Max. Unit 1.2 mA 1.25 1.5 1. Current supplied during the main MOSFET OFF time only. 2. Parameter assured by design and characterization. Table 7. Controller section Symbol Parameter Test conditions Min. Typ. Max. Unit E/A VFB_REF Reference voltage - 1.175 1.2 1.225 V VFB_DIS E/A disable voltage - 150 180 210 mV Pull-up current - 0.9 1 1.1 A Transconductance VCOMP = 1.5 V VFB > VFB_REF 350 500 650 A/V ICOMP1 Max. source current VCOMP = 1.5 V VFB = 0.5 V 75 100 125 A ICOMP2 Max. sink current VFB = 2 V VCOMP = 1.5 V 75 100 125 A Dynamic resistance VCOMP = 2.7 V VFB = GND 55 65 75 k VCOMPH Current limitation threshold - - 3 - V VCOMPL PFM threshold - - 0.8 - V TJ = 25 C VIPER114* 456 480 504 TJ = 25 C VIPER115* 560 IFB PULL UP GM RCOMP(DYN) OLP and timing IDLIM I2f IDLIM_PFM 8/35 Drain current limitation mA IDLIM_TYP2 x FOSC_TYPP 0.9 *I2f Power coefficient Drain current limitation at light load TJ = 25 C VCOMP = VCOMPL(1) VIPER114* 90 TJ = 25 C VCOMP = VCOMPL(1) VIPER115* 105 DS11873 Rev 3 590 I2f 115 620 1.1 *I2f A2*kHz 140 mA 130 155 VIPer11 Electrical and thermal ratings Table 7. Controller section (continued) Symbol Parameter Test conditions Min. Typ. Max. Unit Disable threshold voltage VCC = 9 V VCOMP = 1 V VFB = VFB_REF 1.15 1.2 1.25 V tDIS Debounce time before DIS protection tripping - 0.8 1 1.2 ms tDIS_RESTART Restart time after DIS protection tripping - 400 500 600 ms Overload delay time - 45 50 55 ms VIPER11*X FOSC = FOSC MIN 90 100 110 VIPER11*L FOSC = FOSC MIN 180 200 220 VIPER11*H FOSC = FOSC MIN 360 400 440 6 8 10 ms VDISth tOVL tOVL_MAX tSS Max. overload delay time ms Soft-start time - tON_MIN Minimum turn-on time VCC = 9 V VCOMP = 1 V VFB = VFB_REF 250 300 350 ns tRESTART Restart time after fault - 0.8 1 1.2 s TJ = 25 C VIPER11*X 27 30 33 TJ = 25 C VIPER11*L 54 60 66 13.5 15 16.5 kHz Oscillator FOSC Switching frequency kHz Minimum switching frequency TJ = 25 C(2) FD Modulation depth (3) - 7 FOSC - % FM Modulation frequency (3) - 260 - Hz Max. duty cycle (3) 70 80 % (3) 150 FOSC_MIN DMAX Thermal shutdown TSD Thermal shutdown temperature 160 C 1. See Section 4.10: Pulse frequency modulation on page 19. 2. See Section 4.7: Pulse-skipping on page 18. 3. Parameter assured by design and characterization. DS11873 Rev 3 9/35 35 Typical electrical characteristics 3 10/35 VIPer11 Typical electrical characteristics Figure 4. IDLIM vs TJ Figure 5. IFOSC vs TJ Figure 6. VHV_START vs TJ Figure 7. VFB_REF vs TJ Figure 8. Quiescent current Iq vs TJ Figure 9. Operating current ICC vs TJ DS11873 Rev 3 VIPer11 Typical electrical characteristics Figure 10. ICH1 vs TJ Figure 11. ICH1 vs VDRAIN Figure 12. ICH2 vs TJ Figure 13. ICH2 vs VDRAIN Figure 14. ICH3 vs TJ Figure 15. ICH3 vs VDRAIN DS11873 Rev 3 11/35 35 Typical electrical characteristics 12/35 VIPer11 Figure 16. GM vs TJ Figure 17. ICOMP vs TJ Figure 18. RDS(on) vs TJ Figure 19. Static drain-source on-resistance Figure 20. VBVDSS vs TJ Figure 21. Output characteristic DS11873 Rev 3 VIPer11 Typical electrical characteristics Figure 22. SOA SSOP10 package Figure 23. Maximum avalanche energy vs TJ DS11873 Rev 3 13/35 35 General description VIPer11 4 General description 4.1 Block diagram Figure 24. Block diagram 4.2 Typical power capability Table 8. Typical power Vin: 230 VAC Vin: 85-265 VAC Adapter(1) Open frame(2) Adapter Open frame 10 W 12 W 6W 7W 1. Typical continuous power in non-ventilated enclosed adapter measured at 50 C ambient. 2. Maximum practical continuous power in an open frame design at 50 C ambient, with adequate heat-sinking. 14/35 DS11873 Rev 3 VIPer11 4.3 General description Primary MOSFET The primary switch is implemented with an avalanche-rugged N-channel MOSFET with minimum breakdown voltage 800 V, VBVDSS, and maximum on-resistance of 20 , RDS(on). The sense-FET is embedded and it allows a virtually lossless current sensing. The MOSFET is embedded and it allows the HV voltage start-up operation. The MOSFET gate driver controls the gate current during both turn-on and turn-off in order to minimize EMI. Under UVLO conditions the embedded pull-down circuit holds the gate low in order to ensure that the MOSFET cannot be turned on accidentally. 4.4 High voltage startup The embedded high voltage startup includes both the 800 V start-up FET, whose gate is biased through the resistor RG, and the switchable HV current source, delivering the current IHV. The major portion of IHV, (ICH), charges the capacitor connected to VCC. A minor portion is sunk by the controller block. At startup, as the voltage across the DRAIN pin exceeds the VHV_START threshold, the HV current source is turned on, charging linearly the CS capacitor. At the very beginning of the startup, when Cs is fully discharged, the charging current is low, ICH1, in order to avoid IC damaging in case VCC is accidentally shorted to GND. As VCC exceeds 1 V, ICH is increased to ICH2 in order to speed up the charging of CS. As VCC reaches the start-up threshold VCCon the chip starts operating, the primary MOSFET is enabled to switch, the HV current source is disabled and the device is powered by the energy stored in the CS capacitor. In steady-state the IC can be supplied from the output (in case of non-isolated topologies) or through an auxiliary winding (in case of isolated topologies), as shown in Figure 25. Figure 25. IC supply modes DS11873 Rev 3 15/35 35 General description VIPer11 In external supply the HV current source is always kept off by maintaining the VCC above VCSon. In this case the residual consumption is given by the power dissipated on RG, calculated as follows: Equation 1 2 V IINDC P = -----------------RG At the nominal input voltage, 230 VAC, the typical consumption (RG = 34 M) is 3.2 mW and the worst-case consumption (RG = 28 M) is 3.9 mW. When the IC is disconnected from the mains, or there is a mains interruption, for some time the converter keeps on working, powered by the energy stored in the input bulk capacitor. When it is discharged below a critical value, the converter is no longer able to keep the output voltage regulated. During the power down, when the DRAIN voltage becomes too low, the HV current source (IHV) remains off and the IC is stopped as soon as the VCC drops below the UVLO threshold, VCCoff. Figure 26. Power-ON and power-OFF 16/35 DS11873 Rev 3 VIPer11 4.5 General description Soft-start The internal soft-start function of the device progressively increases the cycle-by-cycle current limitation set point from zero up to IDLIM in 8 steps. The soft-start time, tSS, is internally set at 8 ms. This function is activated at any attempt of converter startup and at any restart after a fault event. The feature protects the system at the startup when the output load occurs like a short-circuit and the converter works at its maximum drain current limitation. Figure 27. Soft startup 4.6 Oscillator The IC embeds a fixed frequency oscillator with jittering feature. The switching frequency is modulated by approximately 7% kHz FOSC at 260 Hz rate. The purpose of the jittering is to get a spread-spectrum action that distributes the energy of each harmonic of the switching frequency over a number of frequency bands, having the same energy on the whole but smaller amplitudes. This helps to reduce the conducted emissions, especially when measured with the average detection method or, which is the same, to pass the EMI tests with an input filter of smaller size than that needed in absence of jittering feature. Two options with different switching frequencies, FOSC, are available: 30 (X type) and 60 kHz (L type). DS11873 Rev 3 17/35 35 General description 4.7 VIPer11 Pulse-skipping The IC embeds a pulse-skip circuit that operates in the following ways: * Each time the DRAIN peak current exceeds IDLIM level within tON_MIN, the switching cycle is skipped. The cycles can be skipped until the minimum switching frequency is reached, FOSC_MIN (15 kHz). * Each time the DRAIN peak current does not exceed IDLIM within tON_MIN, a switching cycle is restored. The cycles can be restored until the nominal switching frequency is reached, FOSC (30 or 60 kHz). If the converter is operated at FOSC_MIN, the IC is turned off after the time tOVL_MAX (100 ms or 200 ms or 400 ms typ., depending on FOSC) and then automatically restarted with softstart phase, after the time tRESTART (1 s, typ.). The protection is intended to avoid the so called "flux-runaway" condition often present at converter startup and due to the fact that the primary MOSFET, which is turned on by the internal oscillator, cannot be turned off before than the minimum on-time. During the on-time, the inductor is charged by the input voltage and if it cannot be discharged by the same amount during the off-time, in every switching cycle there is an increase of the average inductor current, that can reach dangerously high values until the output capacitor is not charged enough to ensure the inductor discharge rate needed for the volt-second balance. This condition may happen at converter startup, because of the low output voltage. In Figure 28 the effect of pulse-skipping feature on the DRAIN peak current shape is shown (solid line), compared with the DRAIN peak current shape when pulse-skipping feature is not implemented (dashed line). Providing more time for cycle-by-cycle inductor discharge when needed, this feature is effective by keeping low the maximum DRAIN peak current avoiding the flux-runaway condition. Figure 28. Pulse-skipping during startup 18/35 DS11873 Rev 3 VIPer11 4.8 General description Direct feedback The IC embeds a transconductance type error amplifier (E/A) whose inverting input, ground reference and output are FB and COMP, respectively. The internal reference voltage of the E/A is VFB_REF (1.2 V typical value referred to GND). In non-isolated topologies this tightly regulates positive output voltages through a simple voltage divider applied to the output voltage terminal, FB and GND. The E/A output is scaled down and fed into the PWM comparator, where it is compared to the voltage across the sense resistor in series to the sense-FET, thus setting the cycle-bycycle drain current limitation. An R-C network connected on the output of the E/A (COMP) is usually used to stabilize the overall control loop. The FB is provided with an internal pull-up to prevent a wrong IC behavior when the pin is accidentally left floating. The E/A is disabled if the FB voltage is lower than VFB_DIS (200 mV, typ.). 4.9 Secondary feedback When a secondary feedback is required, the internal E/A has to be disabled shorting FB to GND (VFB < VFB_DIS). With this setting, COMP is internally connected to a pre-regulated voltage through the pull-up resistor RCOMP(DYN) and the voltage across COMP is set by the current sunk. This allows the output voltage value to be set through an external error amplifier (TL431 or similar) placed on the secondary side, whose error signal is used to set the DRAIN peak current setpoint corresponding to the output power demand. If isolation is required, the error signal must be transferred through an optocoupler, with the phototransistor collector connected across COMP and GND. 4.10 Pulse frequency modulation If the output load is decreased, the feedback loop reacts lowering the VCOMP voltage, which reduces the DRAIN peak current setpoint, down to the minimum value of IDLIM_PFM when the VCOMPL threshold is reached. If the load is furtherly decreased, the DRAIN peak current value is maintained at IDLIM_PFM and some PWM cycles are skipped. This kind of operation is referred to as "pulse frequency modulation" (PFM), the number of the skipped cycles depends on the balance between the output power demand and the power transferred from the input. The result is an equivalent switching frequency which can go down to some hundreds Hz, thus reducing all the frequency-related losses. This kind of operation, together with the extremely low IC quiescent current, allows very low input power consumption in no-load and light load, while the low DRAIN peak current value, IDLIM_PFM, prevents any audible noise which could arise from low switching frequency values. When the load is increased, VCOMP increases and PFM is exited. VCOMP reaches its maximum at VCOMPH and corresponding to that value, the DRAIN current limitation (IDLIM) is reached. DS11873 Rev 3 19/35 35 General description 4.11 VIPer11 Overload protection To manage the overload condition, the IC embeds the following main blocks: the OCP comparator to turn off the power MOSFET when the drain current reaches its limit (IDLIM) , the up and down OCP counter to define the turn-off delay time in case of continuous overload (tOVL = 50 ms typ.) and the timer to define the restart time after protection tripping (tRESTART = 1 s typ.). In case of short-circuit or overload, the control level on the inverting input of the PWM comparator is greater than the reference level fed into the inverting input of the OCP comparator. As a result, the cycle-by-cycle turn-off of the power switch is triggered by the OCP comparator instead of PWM comparator. Every cycle where this condition is met, the OCP counter is incremented and if the fault condition lasts longer than tOVL (corresponding to the counter end-of-count), the protection is tripped, the PWM is disabled for tRESTART, then it resumes switching with soft-start and, if the fault is still present, it is disabled again after tOVL. The OLP management prevents IC from operating indefinitely at IDLIM and the low repetition rate of the restart attempts of the converter avoids IC overheating in case of repeated fault events. After the fault removal, the IC resumes working normally. If the fault is removed earlier than the protection tripping (before tOVL), the tOVL-counter is decremented on a cycle-by-cycle basis down to zero and the protection is not tripped. If the fault is removed during tRESTART, the IC waits for the tRESTART period has elapsed before resuming switching. In fault condition the VCC ranges between VCSon and VCCon levels, due to the periodical activation of the HV current source recharging the VCC capacitor. Figure 29. Short-circuit condition 20/35 DS11873 Rev 3 VIPer11 4.12 General description Max. duty cycle counter protection The IC embeds a max. duty cycle counter, which disables the PWM if the MOSFET is turned off by max. duty cycle (70% min., 80% max.) for ten consecutive switching cycles. After protection tripping, the PWM is stopped for tRESTART and then activated again with soft- start phase until the fault condition is removed. In some cases (i.e. breaking of the loop) even if VCOMP is saturated high, the OLP cannot be triggered because at every switching cycle the PWM is turned off by maximum duty cycle before than DRAIN peak current reaches the IDLIM setpoint. As a result, the output voltage VOUT can increase without control by keeping a value much higher than the nominal one with the risk for the output capacitor, the output diode and the IC itself. The max. duty cycle counter protection avoids this kind of failures. 4.13 VCC clamp protection This protection can occur when the IC is supplied by auxiliary winding or diode from the output voltage, when an output overvoltage produces an increase of VCC. If VCC reaches the clamp level VCCclamp (30 V, min. referred to GND) the current injected into the pin is monitored and if it exceeds the internal threshold Iclamp_max (30 mA, typ.) for more than tclamp_max (500 s, typ.), the PWM is disabled for tRESTART (1 s, typ.) and then activated again in soft-start phase. The protection is disabled during the soft-start time. DS11873 Rev 3 21/35 35 General description 4.14 VIPer11 Disable function When the voltage across the pin is externally pulled above VDIS_th (1.2 V typ.) for more than tDEB (for instance by a voltage divider connected to some higher voltages), the PWM is disabled. If the voltage divider on the DIS pin is connected to the rectified mains, as shown in Figure 30, an input overvoltage protection can be built. Figure 30. Connection for input overvoltage protection (isolated or non-isolated topologies) In case of non-isolated topologies, by following the same principle an output overvoltage protection can be built, as shown in Figure 31. 22/35 DS11873 Rev 3 VIPer11 General description Figure 31. Connection for output overvoltage protection (non-isolated topologies) If VOVP is the desired input/output overvoltage threshold, the resistors RH and RL of the voltage divider are to be selected according to the following formula: Equation 2 The power dissipation associated to the DIS network is: Equation 3 in case of connection for the input overvoltage detection and Equation 4 in case of connection for the output overvoltage detection. DS11873 Rev 3 23/35 35 General description 4.15 VIPer11 Auto-restart When a fault occurs and a protection trips the PWM is disabled for tRESTART (1 s typ). During this time interval, the HV generator is activated periodically, maintaining the VCC pin voltage between VCSon and VCCon. The PWM is enabled at the first VCC recycle to VCCon after TRESTART, as shown in Figure 32. If the fault is still present, the protection is tripped in the same way, otherwise normal operation is restored. Figure 32. Protection timing diagram with auto-restart option 24/35 DS11873 Rev 3 VIPer11 4.16 General description Thermal shutdown If the junction temperature becomes higher than the internal threshold TSD (160 C, typ.), the PWM is disabled. After tRESTART time, a single switching cycle is performed, during which the temperature sensor embedded in the power MOSFET section is checked. If a junction temperature above TSD is still measured, the PWM is maintained disabled for tRESTART time, otherwise it resumes switching with soft-start phase. During tRESTART VCC is maintained between VCSon and VCCon levels by the HV current source periodical activation. Such a behavior is summarized in below figure: Figure 33. Thermal shutdown timing diagram DS11873 Rev 3 25/35 35 Application information VIPer11 5 Application information 5.1 Typical schematics Figure 34. Flyback converter (non-isolated) Figure 35. Flyback converter with line OVP (non-isolated) 26/35 DS11873 Rev 3 VIPer11 Application information Figure 36. Flyback converter (isolated) Figure 37. Primary side regulation isolated flyback converter DS11873 Rev 3 27/35 35 Application information VIPer11 Figure 38. Buck converter (positive output) Figure 39. Buck-boost converter (negative output) 28/35 DS11873 Rev 3 VIPer11 5.2 Application information Energy saving performance The device allows designing applications to be compliant with the most stringent energy saving regulations. In order to show the typical performance is achievable, the active mode average efficiency and the efficiency at 10% of the rated output power of a 5 V/1.6 A non isolated flyback and 5 V/360 mA buck converters adopting VIPer11, have been measured and are reported in Table 9. In addition, no-load and light load consumptions are shown from Figure 40 to Figure 43. Table 9. Power supply efficiency, VOUT = 5 V Parameter Flyback non iso. 5 V/1.6 A Buck 5 V/360 mA(1) VIN 10 % output load Active mode average efficiency [%] efficiency [%] Pin at no-load [mW] 115 VAC 78.3 78.5 3.9 230 VAC 71.4 79.4 8.2 115 VAC 73.9 71.6 12.1 230 VAC 69.1 69.8 16.2 1. 5 mW bleeder connected at the output. Figure 40. PIN versus VIN in no-load non isolated flyback converter (5 V/1.6 A) Figure 41. PIN versus VIN in light load non isolated flyback converter (5 V/1.6 A) Figure 42. PIN versus VIN in no-load non isolated buck converter (5 V/360 mA) Figure 43. PIN versus VIN in light load non isolated buck converter (5 V/360 mA) DS11873 Rev 3 29/35 35 Application information 5.3 VIPer11 Layout guidelines and design recommendations A proper printed circuit board layout ensures the correct operation of any switch-mode converter and this is true for the VIPer as well. The main reasons to have a proper PCB layout are: * Providing clean signals to the IC, ensuring good immunity against external and switching noises. * Reducing the electromagnetic interferences, both radiated and conducted, to pass the EMC tests more easily. If the VIPer is used to design a SMPS, the following basic rules should be considered: 30/35 * Separating signal from power tracks. Generally, traces carrying signal currents should run far from others carrying pulsed currents or with fast swinging voltages. Signal ground traces should be connected to the IC signal ground, GND, using a single "star point", placed close to the IC. Power ground traces should be connected to the IC power ground, GND. The compensation network should be connected to the COMP, maintaining the trace to GND as short as possible. In case of two-layer PCB, it is a good practice to route signal traces on one PCB side and power traces on the other side. * Filtering sensitive pins. Some crucial points of the circuit need or may need filtering. A small high-frequency bypass capacitor to GND might be useful to get a clean bias voltage for the signal part of the IC and protect the IC itself during EFT/ESD tests. A low ESL ceramic capacitor (a few hundreds pF up to 0.1 F) should be connected across VCC and GND, placed as close as possible to the IC. With flyback topologies, when the auxiliary winding is used, it is suggested to connect the VCC capacitor on the auxiliary return and then to the main GND using a single track. * Keeping power loops as confined as possible. The area circumscribed by current loops where high pulsed current flow should be minimized to reduce its parasitic selfinductance and the radiated electromagnetic field. As a consequence, the electromagnetic interferences produced by the power supply during the switching are highly reduced. In a flyback converter the most critical loops are: the one including the input bulk capacitor, the power switch, the power transformer, the one including the snubber, the one including the secondary winding, the output rectifier and the output capacitor. In a buck converter the most critical loop is the one including the input bulk capacitor, the power switch, the power inductor, the output capacitor and the freewheeling diode. * Reducing line lengths. Any wire acts as an antenna. With the very short rise times exhibited by EFT pulses, any antenna can receive high voltage spikes. By reducing line lengths, the level of received radiated energy is reduced, and the resulting spikes from electrostatic discharges are lower. This also keeps both resistive and inductive effects to a minimum. In particular, all traces carrying high currents, especially if pulsed (tracks of the power loops) should be as short and wide as possible. * Optimizing track routing. As levels of pickup from static discharges are likely greater near the edges of the board, it is wise to keep any sensitive lines away from these areas. Input and output lines often need to reach the PCB edge at some stage, but they can be routed away from the edge as soon as possible where applicable. Since vias are to be considered inductive elements, it is recommended to minimize their number in the signal path and avoid them in the power path. * Improving thermal dissipation. An adequate copper area has to be provided under the DRAIN pins as heatsink, while it is not recommended to place large copper areas on the GND. DS11873 Rev 3 VIPer11 Application information Figure 44. Recommended routing for flyback converter Figure 45. Recommended routing for buck converter DS11873 Rev 3 31/35 35 Package information 6 VIPer11 Package information In order to meet environmental requirements, ST offers these devices in different grades of ECOPACK(R) packages, depending on their level of environmental compliance. ECOPACK(R) specifications, grade definitions and product status are available at: www.st.com. ECOPACK(R) is an ST trademark. 6.1 SSOP10 package information Figure 46. SSOP10 package outline 32/35 DS11873 Rev 3 VIPer11 Package information Table 10. SSOP10 package mechanical data Dimensions (mm) Symbol Min. Typ. Max. A - - 1.75 A1 0.10 - 0.25 A2 1.25 - - b 0.31 - 0.51 c 0.17 - 0.25 D 4.80 4.90 5 E 5.80 6 6.20 E1 3.80 3.90 4 e - 1 - h 0.25 - 0.50 L 0.40 - 0.90 K 0 - 8 Figure 47. SSOP10 recommended footprint DS11873 Rev 3 33/35 35 Ordering information 7 VIPer11 Ordering information Table 11. Order code 8 Order code IDLIM (OCP) FOSC jitter VIPER115XSTR 590 mA 30 kHz 7% VIPER114LSTR 480 mA VIPER115LSTR 590 mA 60 kHz 7% Package SSOP10 tape and reel Revision history Table 12. Document revision history 34/35 Date Revision Changes 11-Apr-2018 1 Initial release. 19-Apr-2018 2 Document status changed from preliminary to production data. 14-Dec-2018 3 Updated Table 7, amended Section 4.15. DS11873 Rev 3 VIPer11 IMPORTANT NOTICE - PLEASE READ CAREFULLY STMicroelectronics NV and its subsidiaries ("ST") reserve the right to make changes, corrections, enhancements, modifications, and improvements to ST products and/or to this document at any time without notice. Purchasers should obtain the latest relevant information on ST products before placing orders. ST products are sold pursuant to ST's terms and conditions of sale in place at the time of order acknowledgement. Purchasers are solely responsible for the choice, selection, and use of ST products and ST assumes no liability for application assistance or the design of Purchasers' products. No license, express or implied, to any intellectual property right is granted by ST herein. Resale of ST products with provisions different from the information set forth herein shall void any warranty granted by ST for such product. ST and the ST logo are trademarks of ST. All other product or service names are the property of their respective owners. Information in this document supersedes and replaces information previously supplied in any prior versions of this document. (c) 2018 STMicroelectronics - All rights reserved DS11873 Rev 3 35/35 35