MP3910 The Future of Analog IC Technology Peak Current Mode Boost PWM Controller with Programmable Frequency, External Soft Start, and Light Load Operation DESCRIPTION FEATURES The MP3910 is a Peak Current Mode PWM controller that can drive an external MOSFET capable of handling more than 10A current. It has a typical operational current of 288µA and can accommodate flyback, boost for nonisolated and isolated applications. Current mode control provides inherently simple loop compensation and cycle-by-cycle current limit. Under-voltage lockout, soft-start, internal regulated supply and slope compensation are all provided to minimize the external component count. While designed for Flyback applications, the MP3910 can also be used for other topologies including Boost, Forward and Sepic. The 1A gate driver minimizes the power loss of the external MOSFET while allowing the use of a wide variety of standard threshold devices. Additionally, MP3910 has pulse skipping mode function that improves the efficiency with light load or no load. It also provides hiccup protection for OLP, OVP and SCP condition. The MP3910 is available in MSOP10 package. 5V to 35V Supply Voltage Range(1) 1A 12V MOSFET Gate Driver External Soft-Start Pulse Skipping Operation with Light Load Programmable Switching Frequency (30kHz-to-400kHz) Frequency Synchronizable from 80kHz-to400kHz Cycle-by-Cycle Current Limit Over Voltage Protection Short Circuit Protection Over Temperature Protection Available in an MSOP10 Package APPLICATIONS Telecom Isolated Power Supplies Brick Modules Off-line Controller General Step Up Applications All MPS parts are lead-free and adhere to the RoHS directive. For MPS green status, please visit MPS website under Products, Quality Assurance page. “MPS” and “The Future of Analog IC Technology” are registered trademarks of Monolithic Power Systems, Inc.. Notes: 1) Refer to “Operation/Internal VCC Regulation” section for <7V input voltage application. TYPICAL APPLICATION DOUT VIN CIN 8 9 GATE ISENSE 10 7 MP3910 5 2 EN/SYNC RT 6 RT GND COMP SS RFB Q1 VIN VCC CVCC EN VOUT COUT 3 FB 1 RMODE RSENSE ROVH 4 DFB ROVL CSS MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 1 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER ORDERING INFORMATION Part Number* MP3910GK Package MSOP10 Top Marking M3910 * For Tape & Reel, add suffix –Z (e.g. MP3910GK–Z); PACKAGE REFERENCE TOP VIEW GND 1 RT 2 10 GATE 9 VCC COMP 3 8 VIN FB 4 7 ISENSE EN/SYNC 5 6 SS ABSOLUTE MAXIMUM RATINGS (2) Thermal Resistance VIN to GND .....................................-0.3V to 40V VCC, GATE to GND.......................–0.3V to 15V All Other Pins ...................................–0.3V to 6V EN Pin Sink Current.............................. 0.5mA(6) (3) Continuous Power Dissipation (TA = +25°C) ........................................................... 0.83W Maximum Operating Frequency............. 500kHz Storage Temperature............... -55°C to +150°C Junction Temperature ...............................150°C Lead Temperature ....................................260°C MSOP10 ................................ 150 ..... 65... °C/W Recommended Operating Conditions (4) Supply Voltage VIN ..............................7V to 35V Supply Voltage with VIN and VCC connected ......................................................5V to 13V EN Pin Sink Current.................. 0mA to 0.4mA(5) Operating Junction Temp. (TJ). -40°C to +125°C MP3910 Rev. 1.11 11/6/2014 (5) θJA θJC Notes: 2) Exceeding these ratings may damage the device. 3) The maximum allowable power dissipation is a function of the maximum junction temperature TJ (MAX), the junction-toambient thermal resistance θJA, and the ambient temperature TA. The maximum allowable continuous power dissipation at any ambient temperature is calculated by PD (MAX) = (TJ (MAX)-TA)/θJA. Exceeding the maximum allowable power dissipation will cause excessive die temperature, and the regulator will go into thermal shutdown. Internal thermal shutdown circuitry protects the device from permanent damage. 4) The device is not guaranteed to function outside of its operating conditions. 5) Measured on JESD51-7, 4-layer PCB. 6) Refer to “Enable/SYNC Control” section. www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 2 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER ELECTRICAL CHARACTERISTICS VIN = 18V, TJ = -40°C to 125°C (typical value are tested at 25°C), unless otherwise noted. Parameters Input Supply Management VCC UVLO Threshold VCC UVLO Hysteresis Shut Down Current Quiescent Current VCC Regulation Voltage Driving Signal Gate Driver Impedance (Sourcing) Gate Driver Impedance (Sinking) Error Amplifier Error Amplifier Transconductance Maximum Amplifier Output Current Symbol Condition Min Typ Max Units VUVLO VUVLO_HYS IS IQ VCC Rising edge 3.9 4.17 350 4.44 V mV μA μA V GEA COMP High Voltage Current Sense Current Comparator Leading Edge Blanking (9) ISENSE Limit SCP Limit(7) Current Sense Amplifier Gain ISENSE Bias Current PWM Minimum ON Time Maximum Duty Cycle Soft-start (8) Charge Current Over Load Detection Discharge Current Discharge Current During Protection Charged Threshold Voltage Over Load Shutdown Threshold Voltage Protection Reset Threshold Voltage MP3910 Rev. 1.11 11/6/2014 10.8 288 11.8 4.1 Ω IGATE=20mA 2 Ω 0.56 mA/V Sourcing and sinking 75 μA ISENSE=0V, VFB =1V ISENSE=1V, Floating COMP 2.4 V 214 ns VFB is +-50mV from FB threshold 1.26V, VCOMP=1.5V Vlimit VSCP TJ=25°C GSENSE ∆VCOMP/∆VISENSE 2.7 ISENSE TJ=25°C 0.01 FSW TON-MIN DMAX ISS 1 523 12.8 IGATE=-20mA TLEB VCOMP(Skipping Mode) (7) Switching Frequency VEN=0V VFB=1.5V VCC Load=0mA to 10mA 163 Pulse skipping mode operation threshold, V(comp) RT=6.81k RT =80.6k 308 25 RT=6.81k 93 185 350 206 V/V 0.15 0.95 337 30 214 95 mV mV μA V 363 35 400 kHz kHz ns % 54 μA 17.8 μA 1.66 μA 3.65 V 3.27 V 0.2 V www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 3 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER ELECTRICAL CHARACTERISTICS (continued) VIN = 18V, TJ= -40°C to 125°C (typical value are tested at 25°C), unless otherwise noted. Parameters Symbol Voltage Feedback Management Mode Detection Voltage(7) Mode Detection Current(7) Mode Detection Time(7) FB Reference Voltage VFB FB Bias Current OVP Reference Level COMP Pull up Resistor COMP Pull up Voltage(7) Enable Control Enable Rising Threshold Enable Hysteresis Enable Turn-off Delay Enable Input Current Thermal Protection Thermal Shutdown(7) Thermal Hysteresis(7) IFB VOVP VEN-RISING VEN-HYS TTD-OFF IEN Condition TJ=25°C TJ=-40°C to 125°C VFB=1.237V, TJ= 25°C Min 1.222 1.211 1.391 TJ=25°C VEN=3V TSD 1.463 Typ 185 55 50 1.237 1.237 0.01 1.438 14.4 3.6 1.628 540 20 2.5 160 20 Max 1.252 1.258 0.15 1.479 1.793 5 Units mV μA μs V V μA V kΩ V V mV μs μA ºC ºC Notes: 7) Guaranteed by engineering sample characterization. 8) Refer to “soft-start section” for detail function of discharge current and threshold voltage. 9) Same as Minimum On Time. MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 4 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER PIN FUNCTIONS Pin # Name Description 1 GND 2 RT 3 COMP 4 FB 5 EN/SYNC 6 SS 7 ISENSE 8 VIN 9 VCC 10 GATE Power ground pin which is gate driver return. Switching frequency set pin. Connect a resistor from this pin to GND to set the switching frequency (30kHz~400kHz). Feedback pin for isolated solution. Error amplifier output pin for un-isolated solution. Feedback and OVP monitor pin with respective internal reference voltage for unisolated solution. OVP monitor pin for isolated solution. Connected to GND if not used in isolated solution. On/off control Input. Internally connected to GND with 1MΩ resistor. Apply an external clock higher than RT set frequency to the EN pin can synchronize the switching frequency. Soft-start pin. Connect one capacitor between this pin and GND to control the duration of COMP voltage rising. It determines both the soft-start current, and hiccup protection delay. Current Sense and application mode (isolated/un-isolated) setting pin. At start-up, this pin will output one current signal and sense the voltage for mode setting detection. During normal operation, this pin will sense the voltage across sense resistor for current mode control, as well as cycle-by-cycle current limit, over load and short circuit protection. Input supply. Connect a bypass capacitor from this pin to GND Internal 12V regulator output. Connect a capacitor between this pin to GND to bypass the internal regulator. This pin drives the external N-channel power MOSFET device. MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 5 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER TYPICAL CHARACTERISTICS VIN = 18V, TA = 25°C, unless otherwise noted. MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 6 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER TYPICAL CHARACTERISTICS (continued) VIN = 18V, TA = 25°C, unless otherwise noted. MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 7 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER TYPICAL PERFORMANCE CHARACTERISTICS VIN = 48V, VOUT = 12V, FSW=250kHz, TA = 25°C, unless otherwise noted. Efficiency vs. Load Current Efficiency vs. Load Current, Flyback 100 100 95 98 V IN=48V 88 86 70 -0.05 84 65 V IN=36V 82 0.5 1 1.5 2 80 2.5 0 60 IOUT=1A -0.05 IOUT=2.5A 35 40 45 50 55 60 65 70 75 INPUT VOLTAGE(V) MP3910 Rev. 1.11 11/6/2014 GAIN MARGIN (dB) 0.00 1.5 2 -0.10 2.5 0 0.5 1 1.5 2 2.5 LOAD CURRENT(A) Gain and Phase vs. Frequency 0.10 IOUT=0A 1 LOAD CURRENT(A) Line Regulation vs. Input Voltage 0.05 0.5 IOUT=2.5A 180 140 40 100 20 60 20 0 -20 -20 -60 -100 -40 -60 1000 PHASE MARGIN (deg) 0 LOAD CURRENT(A) -0.10 V IN=72V 0.00 90 V IN=72V 75 0.05 V IN=12V 92 V IN=48V 80 0.10 V IN=20V 94 85 60 VOUT=24V, FS=300kHz, Boost 96 V IN=36V 90 Load Regulation vs. Load Current -140 10000 -180 100000 FREQUENCY (Hz) www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 8 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 48V, VOUT = 12V, FSW=250kHz, TA = 25°C, unless otherwise noted. MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 9 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 48V, VOUT = 12V, FSW=250kHz, TA = 25°C, unless otherwise noted. MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 10 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER FUNCTION BLOCK DIAGRAM VIN VIN VIN Enable Control EN/SYNC VCC Regulator UVLO VOUT Clock Oscillator and Slope Compensation RT Slope Comp Burst mode 3.6V MODE PWM Logic + PWM Comparator R 0.7V COMP OCP GATE Driver Rsense OL/OV/SC Protection GND 3R MODE Detection 7R 3.65V Current Sense Amplifier ISENSE + Gain 54 A Soft-start - SS OCP Protection 1.66 A VOUT + 50us OLP Timer timer - 17.8 A EA Out 1.237V FB 0.185V SCP + EA + - 0.35V R Q - Error Amplifier 3.27V + OLP - + OL/OV/SC Protection OVP OVP 1.438V - 0.2V + Restart S - Figure 1: Functional Block Diagram MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 11 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER OPERATION The MP3910 uses a programmable frequency, peak current mode architecture to regulate the feedback voltage. The operation of the MP3910 can be understood with the block diagram of Figure 1. PWM Operation At the beginning of each cycle the external Nchannel MOSFET is turned on, forcing the current in the inductor to increase. The current through the FET can be sensed and when the sum voltage of amplified ISENSE signal and slope signal rises above the voltage set by the COMP pin, the external FET is turned off. The inductor current then flows to the output capacitor through the schottky diode. The inductor current is controlled by the COMP voltage, which itself is controlled by the output voltage. Thus the output voltage controls the inductor current to satisfy the load. This current mode architecture improves transient response and control loop stability over voltage mode architecture. Pulse Skipping Mode At light load condition, the MP3910 goes into pulse skipping mode to improve light load efficiency. Pulse skipping decision is based on its internal COMP voltage. If COMP is lower than the internal sleep threshold with typical 0.95V, a PAUSE command is generated to block the turn-on clock pulse so the power MOSFET is turned off immediately, saving gate driving and switching losses. This PAUSE command also puts the whole chip into sleep mode, consuming very low quiescent current to further improve the light load efficiency. The gate driver output remains low until COMP voltage is higher than the sleep threshold, then PAUSE signal is reset so the chip is back into normal PWM operation. Internal VCC Regulator MP3910 operates with supply voltage from 7V to 35V. An internal regulator is applied to regulate the power at VCC pin for supplying the internal circuitry of the controller, including the gate driver. The regulator has a nominal output voltage of 12V at VCC pin and must be bypassed with no less than 1μF capacitor. MP3910 Rev. 1.11 11/6/2014 When the Enable is high, the capacitor at VCC pin is charged through the VIN pin. VCC has its own UVLO protection. This UVLO’s rising threshold is 4.17V with a hysteresis of 350mV. When the voltage at VCC pin crosses the VCC UVLO, the controller is enabled and all the internal circuitry is powered by VCC source. As the capacitor is charged, VCC voltage increases until reaching 12V regulated voltage if the VIN voltage is high enough. When input voltage is lower than 12V, VCC voltage will be lower than Vin and 12V due to LDO drop. For normal startup, the input voltage should be higher than 7V. If Vcc and Vin is connected together, MP3910 can start-up from 5V but the max input voltage shouldn’t be higher than 13 V. Vcc voltage can not be higher than Vin voltage if both Vin and Vcc are powered by external source because there is one diode from Vcc to Vin. Feedback Loop Setting To be coincident for different design in isolated and un-isolated application, MP3910 can feedback the output signal through either of FB pin or COMP pin by different setting on ISENSE pin. For un-isolated application such as boost mode, MP3910 integrates one error amplifier which can amplify the output error signal from FB pin, COMP pin needs one RC network for compensation. For isolated application such as fly-back mode, the feedback signal from optocoupler has been amplified by secondary circuitry, directly connect the signal to COMP pin will make loop compensation much easier by eliminating the primary side amplifier. The different feedback loop can be set by different ISENSE pin connection. At the beginning of part enabled, ISENSE pin will output 50us current pulse with typical value of 55uA, as showed in Figure2, if the reflected voltage on ISENSE pin is higher than 185mV, MP3910 will disable the internal error amplifier between FB and COMP pins and pull up COMP www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 12 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER pin to 3.6V source with 14.4kΩ resistor, the feedback signal can be connected to COMP pin directly. If the detection voltage is lower than 185mV, MP3910 will enable the internal error amplifier but turn off the pull up resistor. Then COMP pin is just one output pin of error amplifier and the feedback signal should be connected to FB pin. VIN 55µA 50µs Start up GATE + High / Low I SENSE - 0.185V R MODE R SENSE V SENSE = 55µA x(R MODE+R SENSE) Figure 2: Feedback Mode Setting Generally, it is recommended to place one resistor with 5Kohm~10Kohm between ISENSE pin and current sense resistor for the feedback mode through directly COMP pin, and connect ISENSE pin to current sense resistor directly for feedback mode through FB pin. Soft-Start MP3910 uses one external capacitor on SS pin to control COMP voltage rising for soft-start. When the chip starts, the capacitor on SS pin is charged by one 54uA current source at a slow pace set by the capacitance. When the SS voltage is lower than the external COMP voltage, SS overrides the COMP signal so the PWM comparator uses SS instead of COMP as the PWM turn off reference. When SS is higher than COMP voltage, COMP gains the control back and the soft start finishes. The soft-start can reduce voltage stresses and surge currents during start up, also prevent the converter output voltage from overshooting during startup. Soft start occurs during the start up time and protection recovery time after OLP, SCP and OVP. During normal condition, the SS voltage is clamped at 3.65V. Programmable Oscillator The MP3910 oscillating frequency is set by an MP3910 Rev. 1.11 11/6/2014 external resistor from the RT pin to ground. The value of RT can be estimated from: RT 2.35 103 fSW RT is in kΩ and fSW is in kHz. The frequency setting resistor value shouldn’t be too large for noise immunity consideration. It is recommended to set the frequency within 30kHz to 400kHz. Enable/SYNC Control EN/SYNC is a digital control pin that turns MP3910 on and off. Drive EN high to turn on the controller; drive it low to turn it off. An internal 1MΩ resistor from EN/SYNC to GND allows EN/SYNC to be floated to shut down the chip. For external clock synchronization, connect a clock with a frequency higher than RT set frequency and between 80kHz to 400kHz, the internal clock rising edge will synchronize with the external clock rising edge. Select an external clock pulse signal with low level width less than 10μs, or else MP3910 may treat it as EN power off. EN/SYNC pin can not be connected to voltage higher than 6V, when voltage source is higher than 6V, a pull up resistor is recommend. For resistor pull up condition, an internal zener diode clamps the voltage at EN/SYNC pin. The maximum pull-up current for the internal clamp zener (assuming clamped at 6V) should be less than 0.4mA. Typically 100k pull up resistor is recommended. There is no problem if the clamp voltage is distributed at higher than 6V if pull up current is less than 0.4mA. Current Sense and Over Current Protection The MP3910 is peak current mode controller. The current through the external FET can be sensed through a sensing resistor used in series with the source terminal of FET. The sensed voltage on ISENSE pin is then amplified and fed to the high speed current comparator for the current mode control purpose. The current comparator takes this sensed voltage (plus slope compensation) as one of its inputs, then compares the power switch current with the COMP voltage. When the amplified current www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 13 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER signal is higher than the COMP voltage, the comparator output is low, turning off the power MOSFET. If the voltage on the ISENSE pin exceeds the current-limit threshold voltage with typical value of 185mV, MP3910 will turn off the GATE output for that cycle, until the internal oscillator starts the next cycle, and sense current again. MP3910 limits the current of MOSFET cycle-bycycle. Over Load Protection (OLP) The peak current is limited cycle-by-cycle, if the load continues increasing after triggering OCP protection, the output voltage will decrease and the peak current will trigger OCP every cycle. MP3910 set the over load detection by continue monitoring the ISENSE pin voltage. Once the SS voltage is charged to 3.65V after start up, the OLP protection is enabled. If an OCP signal is detected, the soft-start charging current is disabled and one over current discharge source is enabled, the SS voltage drops with the rate of 17.8uA current. At the same time, one 50us one-shot timer is activated and it remains active for 50µs after the OCP condition stops. The 17.8uA discharge source cannot be turn off until the one-shot timer becomes inactive. If the OCP disappears before at least 50us prior than the SS capacitor discharging to 3.27V, MP3910 will run back to normal work condition and the SS capacitor will be re-charged to 3.65V with 54uA rate. If the SS capacitor is discharged to 3.27V, MP3910 will register it as over load condition and turn off the gate output until next re-start cycle. At the same time, 17.8uA discharge current is disabled and the 1.66uA over load discharge source is enabled. After the SS voltage is discharged to 0.2V, MP3910 will re-start up with new soft-start cycle. This is hiccup mode protection. The OLP detection function is disabled after the SS voltage is discharged to be lower than 3.27V and it will be re-enabled after SS voltage is re-charged to 3.65V. So the OLP only occurs after the soft-start is completed. When the output is shorted to the ground, the part works in OCP mode and current is limited cycle-by-cycle, the part may run into OLP protection. But if the peak current cannot be limited by 185mV ISENSE voltage in every cycle due to leading edge blanking (LEB) time, the current may run out of control and transformer may run into saturation. If the monitored ISENSE voltage reaches 0.35V, the part will turn off the GATE out and run into hiccup mode by discharge SS capacitor with 1.66uA current. It will also restart up if SS voltage is discharged to 0.2V. In case the short circuit is removed, the output voltage will recover only after the next new restart cycle. For boost converter, it has no method to limit current from the input to the output in the condition of output short circuit. If protection from this type condition is desired, it is necessary to add some secondary protection circuit. Over Voltage Protection For isolated-flyback application, the positive plateau of auxiliary winding voltage is proportional to the output voltage, MP3910 features the over voltage protection by using the auxiliary winding voltage instead of directly monitoring the output voltage. The auxiliary voltage can be monitored by FB pin through resistor divider, once the voltage is higher than OVP reference voltage, MP3910 turns off the GATE output and discharge SS voltage with 1.66uA current until SS voltage is lower than 0.2V, then the part will initial one new re-start cycle. To avoid the mis-trigger due to the oscillation of the leakage inductance and the parasitic capacitance, the OVP sampling has a TOVPS blanking with 500ns typical value. For some oscillation condition, one external filter is necessary to work together with the 500ns LEB time. For un-isolated solution, the DC output voltage is applied to FB pin and it can easily detect the OVP condition. Short Circuit Protection MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 14 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER Thermal Shutdown Thermal shutdown is implemented to prevent the chip from thermally running away. When the silicon die temperature is higher than its upper threshold, it shuts down the whole chip. When the temperature is lower than its lower threshold, thermal shutdown is gone so the chip is enabled again with a new start-cycle. MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 15 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER APPLICATION INFORMATION COMPONENT SELECTION MP3910 can be used for topologies including Flyback, Boost and Sepic. Refer to figure 5 and below introduction for typical external component selection of boost converter. Setting the Output Voltage Set the output voltage by selecting the resistive voltage divider ratio. If we use 10kΩ for the lowside resistor (RFBL) of the voltage divider, we can determine the high-side resistor (RFBH) by the equation: RFBH R (VOUT VREF ) FBL VREF Where VOUT is the output voltage For RFBL=10kΩ, VOUT=24V and VREF=1.237V, then RFBH=182kΩ. Selecting the Soft-start Capacitor MP3910 ramps external capacitor voltage on SS pin to control COMP voltage, which determines inductor peak current. The SS pin voltage can be calculated by blew equation: Vss 54A Tss Css When OLP, SCP, OVP occurs, the SS acts as a timer. Once the protection occurs, the 1.66uA current discharges SS cap for hiccup protection. Selecting the Input Capacitor An input capacitor is required to supply the AC ripple current to the inductor, while limiting noise at the input source. A low ESR capacitor is required to keep the noise to the IC at a minimum. Ceramic capacitors are preferred, but tantalum or low-ESR electrolytic capacitors may also suffice. When using tantalum or electrolytic capacitors, a small high quality ceramic capacitor, i.e. 0.1uF, should be place close to IC. The capacitance for boost input can be calculated as: CIN I 8 VIN FSW Where ΔI is the peak-to-peak inductor ripple current and ΔVIN is the input voltage ripple. Selecting the Output Capacitor The output capacitor maintains the DC output voltage. For best results, use low-ESR capacitors to minimize the output voltage ripple. MP3910 Rev. 1.11 11/6/2014 The output capacitor’s characteristics also affect system stability. For best results, use ceramic, tantalum, or low-ESR electrolytic capacitors. For ceramic capacitors, the capacitance dominates the impedance at the switching frequency, and so the output voltage ripple is mostly independent of the ESR. The output voltage ripple is estimated as: VIN VOUT ILOAD COUT FSW 1 VOUT Where ∆VOUT is the output ripple voltage, VIN and VOUT are the DC input and output voltage, respectively, ILOAD is the load current, FSW is the switching frequency, and COUT is the value of the output capacitor. For tantalum or low-ESR electrolytic capacitors, the ESR dominates the impedance at the switching frequency, so the output ripple is estimated as: VIN VOUT I RESR VOUT ILOAD LOAD COUT FSW VIN 1 VOUT Where RESR is the equivalent series resistance of the output capacitors. Choose an output capacitor that satisfies the output ripple and load transient requirements of the design. Selecting the Inductor and Current Sensing Resistor The inductor is required to transfer the energy between the input source and the output capacitors. A larger value inductor results in less ripple current that results in lower peak inductor current, and therefore reduces the stress on the power MOSFET. However, the larger value inductor has a larger physical size, higher series resistance, and lower saturation current. A good rule of thumb is to allow the peak-topeak ripple current to be approximately 30-50% of the maximum input current. Make sure that the peak inductor current is below 80% of the IC’s maximum current limit at the operating duty cycle to prevent loss of regulation. Make sure that the inductor does not saturate under the worst-case load transient and startup conditions. The required inductance value can be calculated by: www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 16 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER L VIN (VOUT VIN ) VOUT FSW I IIN VOUT ILOAD VIN I (30% 50%) IIN Where ILOAD is the load current, ΔI is the peakto-peak inductor ripple current and η is the efficiency. For a typical design, boost converter efficiency can reach 85%~95%. The switch current is usually used for the peak current mode control. In order to avoid hitting the current limit, the voltage across the sensing resistor RSENSE should be less than 80% of the worst case current limit voltage, 185mV. 0.8 0.185 R SENSE IL(PEAK ) Where IL(PEAK) is the peak value of the inductor current. Selecting the Power MOSFET The MP3910 is capable of driving a wide variety of N-Channel power MOSFETS. The critical parameters of selecting a MOSFET are: 1. Maximum drain to source voltage, VDS(MAX) 2. Maximum current, ID(MAX) 3. On-resistance, RDS(ON) 4. Gate source charge QGS and gate drain charge QGD 5. Total gate charge, QG 6. Turn on threshold VTH Ideally, the off-state voltage across the MOSFET is equal to boost output voltage. Considering the voltage spike when it turns off, VDS(MAX) should be greater than 1.5 times of the output voltage. The maximum current through the power MOSFET happens when the input voltage is minimum and the output power is maximum. The maximum RMS current through the MOSFET is given by: IRMS IIN VOUT VIN VOUT The current rating of the MOSFET should be greater than 1.5 times IRMS, The on resistance of the MOSFET determines the conduction loss, which is given by: 2 PLOSS IRMS RDS(ON) K MP3910 Rev. 1.11 11/6/2014 Where K is the on-resistance temperature coefficient of the MOSFET. So it is smaller, it is better. The switching loss is related to QGD and QGS1 which determine the commutation time. QGS1 is the charge between the threshold voltage and the plateau voltage when a driver charges the gate, which can be read in the chart of VGS vs. QG of the MOSFET datasheet. QGD is the charge during the plateau voltage. These two parameters are needed to estimate the turn on and turn off loss. PSW QGS1 RG Q RG VDS IIN FSW GD VDS IIN FSW VDR VTH VDR VPLT Where VTH is the threshold voltage, VPLT is the plateau voltage, RG is the gate resistance, VDS is the drain-source voltage. Please note that the switching loss is the most difficult part in the loss estimation. The formula above provides a simple physical expression. On the other hand, small QG will cause fast turn on/off speed which determines the spike and kick. The turn on threshold voltage VTH is also important. GATE pin is powered by VCC power, so the VTH must be lower than VCC voltage. For worst case, VCC voltage is at the 3.55V falling UVLO, so the MOSFET VTH should be much lower than this voltage to get enough driving capability. Selecting the Diode The boost output rectifier diode supplies current to the inductor when the MOSFET is off. Use a Schottky diode to reduce losses due to the diode forward voltage and recovery time. The diode should be rated for a reverse voltage greater than the expected output voltage. The average current rating must exceed the maximum expected load current, and the peak current rating must exceed the peak inductor current. Boost Converter Compensation Design The output of the transconductance error amplifier (COMP) is used to compensate the regulation control system. The system uses two poles and one zero to stabilize the control loop. The poles are FP1, which is set by the output capacitor (COUT) and load resistance, and FP2 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 17 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER which starts from origin. The zero (FZ1) is set by the compensation capacitor (CCOMP) and the compensation resistor (RCOMP). These parameters are determined by the equations: FP1 FZ1 1 CPOLE 2 COUT RLOAD 1 2 CCOMP RCOMP Where RLOAD is the load resistance. The DC mid-band loop gain is: A VDC should be added between COMP pin and GND. Then a pole, formed by CPOLE and RCOMP, should be placed at the ESR zero to cancel the adverse effect. 0.5 GEA VIN RLOAD VREF RCOMP 2 VOUT RSENSE GSENSE Where VREF is the voltage reference, 1.237V. GSENSE is the current sense amplifier gain and GEA is the error amplifier transconductance. 1 2 RCOMP FESRZ PCB Layout Guide High frequency switching regulators require very careful layout for stable operation and low noise. For boost topology layout: 1. Keep the high current path as short as possible between the MOSFET drain, output diode, output capacitor and current sense resistor for minimal noise and ringing. 2. The VCC capacitor must be placed close to the VCC pin for best decoupling. The ESR zero in this example locates at very high frequency. Therefore, it is not taken into design consideration. 3. All feedback components must be kept close to the FB pin to prevent noise injection on the FB pin trace. There is also a right-half-plane zero (FRHPZ) that exists in continuous conduction mode (inductor current does not drop to zero on each cycle) step-up converters. The frequency of the right half plane zero is: 4. The ground return of the input and output capacitors should be tied to the GND pin with single point connection. FRHPZ VIN2 RLOAD 2 2 L VOUT The right-half-plane zero increases the gain and reduces the phase simultaneously, which results in smaller phase margin and gain margin. The worst case happens at the condition of minimum input voltage and maximum output power. Refer to Figure 3 for boost layout, which is referenced to schematic in Figure 5 L1 2 COUT RLOAD RCOMP 2 OUT V Q1 GND RSENSE 2 COUT FC RSENSE GSENSE GEA VREF VIN Based on these equations, RCOMP and CCOMP can be solved. CVCC CSS CIN REN CIN2 1 2 CCOMP RCOMP Vo COUT In order to achieve system stability, Fz1 is placed close to FP1 to cancel the pole. RCOMP is adjusted to change the voltage gain. Make sure the bandwidth FC is about 1/10 of the lower one of the ESR zero and the right-half-plane zero. 1 D1 SW MP3910 RT Vin GND RFBH CCOMP RCOMP RFBL Top Layer In cases where the ESR zero is in a relatively low frequency region and results in insufficient gain margin, an optional capacitor (CPOLE) MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 18 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER For flyback topology PCB layout: 1. Keep the input loop as short as possible between input cap, transformer, MOSFET, current sense resistor and GND plane for minimal noise and ringing. 2. Keep the output loop between rectifier diode, output cap and transformer as short as possible. 3. The clamp loop circuit between DSN, CSN and transformer should be as small as possible 4. The VCC capacitor must be placed close to the VCC pin for best decoupling. 5. The feedback trace should be far away from noise source such as drain of power FET. Bottom Layer 6. Use single point connection between power GND and signal GND. Figure 3: Boost PCB Layout Vin CIN RSN T1 CSN DOUT DSN GND RSENSE GND C COUT Design Example Q1 CVCC RT 10 2 9 3 8 4 7 5 6 ROVL ROVH Below is a design example following the application guidelines for the specifications: U1 1 RMODE DFB CSS CIN2 Vout Refer to figure 4 for flyback layout, which is referenced to schematic on page 1. For more detail information, refer to flyback EVB datasheet. Table 1: Boost Design Example U2 VIN VOUT fSW RFB Top Layer Input GND 10-20V 24V 300kHz The detailed application schematic is shown in Figure 8. And there is another design example for fly-back application in Figure 6. Output GND Table 2: Fly-back Design Example VIN VOUT fSW 36-72V 12V 250kHz The typical performance and circuit waveforms of flyback have been shown in the Typical Performance Characteristics section. For more device applications, please refer to the related Evaluation Board Datasheets. Bottom Layer Figure 4: Fly-back PCB Layout MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 19 9 VCC FB 4 3 COMP VIN 8 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER Figure 5: Boost Design and Layout Reference Schematic MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 20 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER VCC FB 4 3 COMP VIN 9 8 TYPICAL APPLICATION CIRCUITS 9 VCC FB 4 3 COMP VIN 8 Figure 6: Typical Fly-back Converter Application Schematic Figure 7: Typical Sepic Converter Application Schematic MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 21 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER TYPICAL APPLICATION CIRCUITS (continued) L1 10-20V 10uH Vin C1 SS5P4 C8 10uF 10uF C4 1uF 1 5 EN/SYNC R2 100k EN Vout C9 10uF GND C10 10uF GND GND 1 GND GND U1 6 MP3910 SS 10 GATE C2 0.22uF 1 Q1 SIR462 D1 GND GND GND R8 4.7R ISENSE COMP RT R3 8.06k GND 7 FB 2 R9 0.025 4 3 GND 1 C7 4.7uF VCC VIN GND 9 R1 453k 8 GND 24V@2A L2 0.47uH D2 1 R5 R4 7.5K 180K R6 10k C5 15nF GND GND GND Figure 8: Typical Boost Converter Application Schematic-High Input Voltage Condition L1 5-10V 1 10uH Vin C1 1 EN 5 R2 100k GND 1 GND U1 6 MP3910 SS GATE 10 GND C2 0.22uF Q1 SIR462 D1 1 GND GND R8 4.7R GND 7 FB R3 8.06k ISENSE R9 0.02 4 RT COMP 2 3 GND GND C7 4.7uF VCC EN/SYNC C10 10uF GND 9 8 1uF VIN GND Vout C9 10uF C4 R1 160k 1 SS5P4 10uF GND 24V@1A L2 0.47uH D2 R5 R4 4.99K R6 10k C5 22nF GND GND 180K GND Figure 9: Typical Boost Converter Application Schematic-Low Input Voltage Condition MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 22 MP3910 –PEAK CURRENT MODE BOOST CONTROLLER PACKAGE INFORMATION MSOP10 0.114(2.90) 0.122(3.10) 6 10 0.114(2.90) 0.122(3.10) PIN 1 ID (NOTE 5) 0.007(0.18) 0.011(0.28) 0.187(4.75) 0.199(5.05) 5 1 0.0197(0.50)BSC BOTTOM VIEW TOP VIEW GAUGE PLANE 0.010(0.25) 0.030(0.75) 0.037(0.95) 0.043(1.10)MAX SEATING PLANE 0.002(0.05) 0.006(0.15) FRONT VIEW 0o-6o 0.016(0.40) 0.026(0.65) 0.004(0.10) 0.008(0.20) SIDE VIEW NOTE: 0.181(4.60) 0.040(1.00) 0.012(0.30) 1) CONTROL DIMENSION IS IN INCHES. DIMENSION IN BRACKET IS IN MILLIMETERS. 2) PACKAGE LENGTH DOES NOT INCLUDE MOLD FLASH, PROTRUSION OR GATE BURR. 3) PACKAGE WIDTH DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSION. 4) LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE 0.004" INCHES MAX. 5) PIN 1 IDENTIFICATION HAS THE HALF OR FULL CIRCLE OPTION. 6) DRAWING MEETS JEDEC MO-817, VARIATION BA. 7) DRAWING IS NOT TO SCALE. 0.0197(0.50)BSC RECOMMENDED LAND PATTERN NOTICE: The information in this document is subject to change without notice. Please contact MPS for current specifications. Users should warrant and guarantee that third party Intellectual Property rights are not infringed upon when integrating MPS products into any application. MPS will not assume any legal responsibility for any said applications. MP3910 Rev. 1.11 11/6/2014 www.MonolithicPower.com MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2014 MPS. All Rights Reserved. 23