MP2354DS-LF

MP28257 EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 The Future of Analog IC Technology 4A, Fast Transient, 4.2V-to-20V Input Synchronous Step-Down Converter 2mmx3mm QFN12 DESCRIPTION FEATURES    The MP28257 is a fully-integrated, synchronous, step-down, switch-mode converter with a programmable frequency. It offers a very compact solution that can provide up to 4A of continuous output current over a wide input supply range with excellent load and line regulation, and can operate at high efficiency over a wide output current load range.       Constant-on-time control mode provides fast transient response and eases loop stabilization. Protections include short-circuit protection, over-current protection, over-voltage protection, under-voltage protection, and thermal shut down. The MP28257 requires a minimal number of readily-available standard external components. The device is available in a space saving 2mmx3mm QFN12 package that complies with ROHS.   Wide 4.2V-to-20V Operating Input Range 4A Continuous Output Current Internal 120mΩ High-Side, 50mΩ LowSide Power MOSFETs Stable with Ceramic Output Capacitors Proprietary Switching Loss-Reduction Technology Power-Good Indicator Soft Startup/Shutdown Programmable Switching Frequency SCP, OCP, OVP, UVP Protection and Thermal Shutdown Output Adjustable from 0.815V to 13V Available in a 2mmx3mm QFN12 Package APPLICATIONS   Networking Systems Distributed Power Systems All MPS parts are lead-free and adhere to the RoHS directive. For MPS green status, please visit MPS website under Quality Assurance. “MPS” and “The Future of Analog IC Technology” are Registered Trademarks of Monolithic Power Systems, Inc. N O T R TYPICAL APPLICATION MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 1 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER ORDERING INFORMATION OCP Protection MP28257DD* Latch-off Mode Package QFN12 (2x3mm) Top Marking Free Air Temperature (TA) ABF -40°C to +85°C EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 Part Number * For Tape & Reel, add suffix –Z (e.g. MP28257DD–Z). For RoHS Compliant Packaging, add suffix –LF (e.g. MP28257DD–LF–Z) PACKAGE REFERENCE TOP VIEW GND 12 11 GND 10 SW GND 1 SW 2 BST 3 9 IN VCC 4 8 FREQ EN 5 7 FB SW 6 PG QFN12 (2x3mm) ABSOLUTE MAXIMUM RATINGS (1) T R Supply Voltage VIN ........................................ 22V VSW ...................................... -0.3V to (VIN + 0.3V) VBST.......................................................... VSW+6V All other pins ................................... -0.3V to +6V Continuous Power Dissipation (TA = 25°C) (2) QFN12 (2x3mm) ......................................... 1.8W Junction Temperature .............................. 150°C Lead Temperature .................................... 260°C Storage Temperature ................-65°C to +150°C N O Recommended Operating Conditions (3) Supply Voltage VIN ........................... 4.2V to 20V Output Voltage VOUT ..................... 0.815V to 13V Maximum Junction Temp. (TJ) .................. 125°C Thermal Resistance (4) θJA θJC QFN12 (2x3mm) ..................... 70 ....... 15 ... °C/W Notes: 1) Exceeding these ratings may damage the device. 2) 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. 3) The device is not guaranteed to function outside of its operating conditions. 4) Measured on JESD51-7, 4-layer PCB. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 2 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER ELECTRICAL CHARACTERISTICS VIN = 12V, TA = 25°C, unless otherwise noted. Switch leakage SWLKG Current limit One-shot on time Minimum off time Fold-back off time (5) OCP hold-off time (5) ILIMIT tON tOFF tFB tOC Feedback voltage VFB Feedback current Soft start time EN rising threshold EN threshold hysteresis EN input current EN Input Current T R Power-good rising threshold Power-good falling threshold Power-good delay Power-good sink current Power-good leakage current VIN under-voltage lockout threshold rising VIN under-voltage lockout threshold hysteresis Thermal shutdown (5) Thermal shutdown hysteresis (5) O N Symbol IIN IIN HSRDS-ON LSRDS-ON Condition VEN = 0V VEN = 2V, VFB = 0.9V Min Typ 1 360 120 50 Max Units μA μA mΩ mΩ 0 10 μA EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 Parameters Supply current (shutdown) Supply current (quiescent) HS switch-on resistance (5) LS Switch-on resistance (5) IFB tSS ENVth-Hi ENVth-Hys IEN IEN PGVth-Hi PGVth-Lo PGTd IPG IPG_LEAK VEN = 0V, VSW = 0V or 12V After Soft-Start Time-out R7 = 300kΩ, VOUT = 1.2V ILIM = 1 ILIM = 1 TA = 25°C TA = -40°C to 85°C VFB = 800mV 5.5 807 803 1.05 VEN = 2V VEN = 0V VEN=2V VEN=0V Power-good Fault condition PG = 0.4V VPG = 3.3V 7 250 130 4.5 50 815 10 1 1.35 500 2 0 2 0 90 85 500 4 INUVVth 150 823 827 50 1.6 A ns ns μs μs mV mV nA ms V mV μA μA 10 % % μs mA nA 3.1 V INUVHYS 300 mV TSD TSD-HYS 150 25 °C °C Note: 5) Guaranteed by design. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 3 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER PIN FUNCTIONS Name 9 IN EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 QFN12 (2x3mm) Pin # 1, 11, 12 GND 2, 10, Exposed Pad SW 3 BST 4 5 7 8 EN FB FREQ PG Supply Voltage. The MP28257 operates from a 4.2V to 20V input rail. C1 decouples the input rail. Use wide PCB traces and multiple vias to make the connection. System Ground. Reference ground for the regulated output voltage. These pins require special consideration during PCB layout. Switch Output. Connect with wide PCB traces. Bootstrap. Requires a capacitor connected between SW and BST pins to form a floating supply across the high-side switch driver. Internal Bias Supply. Decouple with a 1µF ceramic capacitor as close to the pin as possible. EN = 1 to enable the MP28257. For automatic start-up, connect EN pin to VIN with a pull-up resistor. Feedback. Sets the output voltage when connected to the tap of an external resistor divider, connected between output and GND. Frequency. Set during CCM operation. Connect a resistor R7 to IN to set the switching frequency. Decouple with a 1nF capacitor. Power-Good Output. The output of this pin is an open drain that goes high if the output voltage is higher than 90% of the nominal voltage. There is a 0.5ms delay between when the feedback exceeds 90% to when the PG pin goes high. N O T R 6 VCC Description MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 4 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS N O T R EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 VIN = 12V, VOUT = 1.2V, L = 2μH, TA = 25°C, unless otherwise noted. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 5 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 12V, VOUT = 1.2V, L = 2μH, TA = 25°C, unless otherwise noted. VOUT/AC 10mV/div. Start up through VIN Start up through VIN IOUT = 4A IOUT = 0A IOUT = 4A EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 VIN/AC 100mV/div. Input/Output Voltage Ripple VIN 10V/div. VIN 10V/div. VOUT 1V/div. VSW 5V/div. IL 5A/div. VIN 10V/div. VOUT 1V/div. VSW 2V/div. VSW 10V/div. VSW 10V/div. IL 1A/div. IL 5A/div. Shutdown through VIN Shutdown through VIN Start up through EN IOUT = 0A IOUT = 4A IOUT = 0A VIN 5V/div. VOUT 1V/div. VSW 10V/div. IL 5A/div. VOUT 1V/div. VSW 5V/div. VSW 10V/div. IL 5A/div. IL 1A/div. Start up through EN Shutdown through EN Shutdown through EN IOUT = 4A IOUT = 0A IOUT = 4A T O N VEN 5V/div. VEN 5V/div. VOUT 1V/div. R IL 1A/div. VOUT 1V/div. VEN 5V/div. VOUT 1V/div. VSW 10V/div. IL 1A/div. VEN 5V/div. VOUT 1V/div. VSW 10V/div. IL 5A/div. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 6 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS (continued) EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 VIN = 12V, VOUT = 1.2V, L = 2μH, TA = 25°C, unless otherwise noted. VOUT/AC 50mV/div. VOUT/AC 50mV/div. VOUT/AC 50mV/div. VSW 10V/div. IL 5A/div. IL 5A/div. N O T R IL 2A/div. VSW 10V/div. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 7 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER BLOCK DIAGRAM EN Current Sense Amplifer 5V LDO Over-Current Timer + - REFERENCE ILIM RSEN OC BST OFF Timer HS IIimit Comparator VCC xS Q 0.4V 1MEG + VCC EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 IN FREQ PWM HS Driver HS_FET 1.0V xR 0.8V LOGIC SW SOFT START/STOP PG PGOOD Comparator + FB + + - START VCC ON Timer LS Driver Loop Comparator LS_FET Current Modulator + - UV UV Detect Comparator GND 0 0 + - OV OV Detect Comparator N O T R Figure 1: Functional Block Diagram MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 8 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER OPERATION EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 PWM Operation The MP28257 is a fully-integrated, synchronous, rectified, step-down switch converter. The device uses constant-on-time (COT) control to provide fast transient response and easy loop stabilization. At the beginning of each cycle, the high-side MOSFET (HS-FET) turns ON whenever the feedback voltage (VFB) is lower than the reference voltage (VREF)—a low VFB indicates insufficient output voltage. The input voltage and the frequency-set resistor determine the ON period as follows: 9.3  R7 (k ) (1) t ON (ns)   40ns VIN (V)  0.4 After the ON period elapses, the HS-FET enters the OFF state. By cycling the HS-FET between the ON and OFF states, the converter regulates the output voltage. The integrated low-side MOSFET (LS-FET) turns on when the HS-FET is in its OFF state to minimize the conduction loss. R Shoot-through occurs when there is both the HSFET and LS-FET are turned on at the same time, causing a dead short between input and GND. Shoot-through dramatically reduces efficiency, and the MP28257 avoids this by internally generating a dead-time (DT) between when the HS-FET is off and the LS-FET is on, and when the LS-FET is off and the HS-FET is on. The device enters either heavy-load operation or light-load operation depending on the amplitude of the output current. O T Heavy-Load Operation N LS-FET repeat the on/off operation described for PWM operation, the inductor current never goes to zero, and the switching frequency (fSW) is fairly constant. Figure 2 shows the timing diagram during this operation. Light-Load Operation During light-load operation—when the output current is low—the MP28257 automatically reduces the switching frequency to maintain high efficiency, and the inductor current drops near zero.. When the inductor current reaches zero, the LS-FET driver goes into tri-state (high Z). The current modulator controls the LS-FET and limits the inductor current to around -1mA as shown in Figure 3. Hence, the output capacitors discharge slowly to GND through LS-FET, R1, and R2. This operation greatly improves device efficiency when the output current is low. Figure 3: Light-Load Operation Light-load operation is also called skip mode because the HS-FET does not turn on as frequently as during heavy-load conditions. The frequency at which the HS-FET turns on is a function of the output current—as the output current increases, the time period that the current modulator regulates becomes shorter, and the HS-FET turns on more frequently. The switching frequency increases in turn. The output current reaches the critical level when the current modulator time is zero, and can be determined using the following equation: (VIN  VOUT )  VOUT (2) 2  L  fSW  VIN The device reverts to PWM mode once the output current exceeds the critical level. After that, the switching frequency stays fairly constant over the output current range. IOUT  Figure 2: Heavy-Load Operation During heavy-load operation—when the output current is high—the MP28257 enters continuousconduction mode (CCM) where the HS-FET and MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 9 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER Jitter can affect system stability, with noise immunity proportional to the steepness of VFB’s downward slope. However, VFB ripple does not directly affect noise immunity. EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 BST LSG N1 VNOISE V S L O PE1 C3 VFB VCC VREF C5 SW HS D river L J itter COUT Figure 4: Floating Driver and Bootstrap Charging The floating power MOSFET driver is powered by an external bootstrap capacitor. This floating driver has its own UVLO protection with a rising threshold of 2.2V and a hysteresis of 150mV. The bootstrap capacitor is charges from VCC through N1 (Figure 4): N1 turns on when the LSFET turns on, and turns off when the LS-FET turns off. T R Switching Frequency The MP28257 uses COT control because there is no dedicated oscillator in the IC. The input voltage is feed-forwarded to the on-time one-shot timer through the resistor R7. The duty ratio is kept as VOUT/VIN, and the switching frequency is fairly constant over the input voltage range. The switching frequency can be determined with the following equation: 106 (3) f (kHz)  N O SW Figure 5—Jitter in PWM Mode VNOISE VS LOPE 2 V FB V REF HS D river Jitter Figure 6—Jitter in Skip Mode Ramp with Large ESR Cap In the case of POSCAP or other types of capacitor with larger ESR is applied as output capacitor. The ESR ripple dominates the output ripple, and the slope on the FB is quite ESR related. Figure 7 shows an equivalent circuit in PWM mode with the HS-FET off and without an external ramp circuit. Turn to application information section for design steps with large ESR caps. 9.3  R7 (k ) VIN (V)   tDELAY (ns) VIN (V)  0.4 VOUT (V) Where TDELAY is the comparator delay, and equals approximately 40ns. The MP28257 is optimized to operate at a high switching frequency a high efficiency. The high switching frequency makes it possible to use small-sized LC filter components to save system PCB space. Figure 7—Simplified Circuit in PWM Mode without External Ramp Compensation Jitter and FB Ramp Slope Jitter occurs in both PWM and skip modes when noise in the VFB ripple propagates a delay to the HS-FET driver, as shown in Figures 5 and 6. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 10 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER RESR TSW T  ON 2  0.7   COUT (4) TSW T + ON -RESRCOUT Io  10-3 0.7  π 2 (9) -Vslope1  VOUT + 2  L  COUT TSW -Ton TSW is the switching period. Ramp with small ESR Cap When the output capacitors are ceramic ones, the ESR ripple is not high enough to stabilize the system, and external ramp compensation is needed. Skip to application information section for design steps with small ESR caps . As can be seen from equation 8, if there is instability in PWM mode, we can reduce either R4 or C4. If C4 can not be reduced further due to limitation from equation 5, then we can only reduce R4. For a stable PWM operation, the Vslope1 should be design follow equation 9. EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 To realize the stability when no external ramp is used, usually the ESR value should be chosen as follow: Io is the load current. In skip mode, the downward slope of the VFB ripple is the same whether the external ramp is used or not. Figure9 shows the simplified circuit of the skip mode when both the HS-FET and LSFET are off. Figure 9—Simplified Circuit in skip Mode Figure 8—Simplified Circuit in PWM Mode with External Ramp Compensation R Figure 8 shows a simplified external ramp compensation (R4 and C4) for PWM mode, with HS-FET off. Chose R1, R2, R9 and C4 of the external ramp to meet the following condition: (5) T  1 1  R  R2   1  R9  2  FSW  C 4 5  R1  R 2  N O where: IR4  IC4  IFB  IC4 (6) And the Vramp on the VFB can then be estimated as: VRAMP  VIN  VOUT R1 // R2  TON  R 4  C4 R1 // R2  R9 (7) The downward slope of the VFB ripple then follows VSLOPE1   VOUT  VRAMP  Toff R 4  C4 (8) The downward slope of the VFB ripple in skip mode can be determined as follow: VSLOPE2   VREF (R1  R2  // Ro)  COUT (10) where Ro is the equivalent load resistor. As described in Figure 6, VSLOPE2 in the skip mode is lower than that is in the PWM mode, so it is reasonable that the jitter in the skip mode is larger. If one wants a system with less jitter during light load condition, the values of the VFB resistors should not be too big, however, that will decrease the light load efficiency. When using a large-ESR capacitor on, the output, add a ceramic capacitor with a value of 10uF or less to in parallel to minimize the effect of ESL. Soft Start/Stop MP28257 employs a soft-start/stop (SS) mechanism to ensure a smooth output during power up and power shut-down. When the EN pin goes high, the internal SS voltage slowly ramps up. The output voltage smoothly ramps up with the SS voltage. Once SS voltage rises MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 11 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER UVP accompanies a drop in the current limit and this results in SCP. UVLO Protection MP28257 has under-voltage lock-out (UVLO) protection. The MP28257 powers up when the input voltage exceeds the UVLO rising threshold voltage. It shuts off when the input voltage falls below the UVLO falling threshold voltage. This is non-latch protection. EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 above the VREF, it continues to ramp up while the PWM comparator only compares the VREF and the FB voltage. At this point, the soft-start finishes and it enters steady state operation. The SS time is set about 1ms internally. When the EN pin goes low, an internal current source discharges the internal SS voltage. Once the SS voltage falls below the VREF, the PWM comparator will only compare the VREF to the SS voltage. The output voltage then decreases smoothly with the SS voltage until the voltage level zeros out. Power-Good (PG) The PG pin is the open drain of a MOSFET that connects to VCC or some other voltage source through a resistor (e.g.. 100kΩ). The MOSFET turns on with the application of an input voltage so that the PG pin is pulled to GND before SS is ready. After FB voltage reaches 90% of VREF, the PG pin is pulled high after a 0.5ms delay. Thermal Shutdown The MP28257 employs thermal shutdown by internally monitoring the junction temperature of the IC. If the junction temperature exceeds the threshold value (typically 150°C), the converter shuts off. This is non-latch protection. There is about 25°C hysteresis. Once the junction temperature drops around 125°C, it initiates a soft start. When the FB voltage drops to 70% of VREF, the PG pin will be pulled low. Over-Current Protection (OCP) and ShortCircuit Protection (SCP) R MP28257 has cycle-by cycle over-current limit control. It monitors the inductor current during the ON state. Once the inductor current exceeds the current limit, the HS-FET turns off and the OCP timer—set at 50μs—starts. The OCP triggers. If the inductor current reaches or exceeds the current limit every cycle if in those the 50μs, the device enters latch-off mode N O T The MP28257 SCP triggers when dead shorts occur—when the inductor current exceeds the current limit and the FB voltage is lower than 50% of the VREF—and will trigger the OCP. The MP28257 needs power cycle to restart after it triggers OCP or SCP. Over/Under-Voltage Protection (OVP/UVP) MP28257 monitors the output voltage through a resistor-divided FB voltage to detect over- and under-voltage on the output. When the FB voltage is higher than 125% of the VREF, it triggers the OVP. Once it triggers the OVP, the LS-FET is always on while the HS-FET is off. It needs to power cycle to turn on again. Conversely, the UVP triggers when the FB voltage falls below 50% of VREF (0.815V). Usually MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 12 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER APPLICATION INFORMATION EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 Setting the Output Voltage-Large ESR Caps in equation 7. R2 should be chosen reasonably, a small R2 will lead to considerable quiescent current loss while too large R2 makes the FB noise sensitive. It is recommended to choose a value within 5kΩ-50kΩ for R2, using a comparatively larger R2 when Vo is low, etc.,1.05V, and a smaller R2 when Vo is high. And the value of R1 then is determined as follow: R2 (12) R= For applications that electrolytic capacitor or POS capacitor with a controlled output of ESR is set as output capacitors. The output voltage is set by feedback resistors R1 and R2. As Figure 10 shows. 1 Figure10—Simplified Circuit of POS Capacitor R First, choose a value for R2. R2 should be chosen reasonably, a small R2 will lead to considerable quiescent current loss while too large R2 makes the FB noise sensitive. It is recommended to choose a value within 5kΩ50kΩ for R2, using a comparatively larger R2 when Vo is low, etc.,1.05V, and a smaller R2 when Vo is high. Then R1 is determined as follow with the output ripple considered: 1 VOUT  VOUT  VREF 2 (11) R1   R2 VREF VOUT is the output ripple determined by equation 20. N O T Setting the Output Voltage-Small ESR Caps Figure11—Simplified Circuit of Ceramic Capacitor When low ESR ceramic capacitor is used in the output, an external voltage ramp should be added to FB through resistor R4 and capacitor C4.The output voltage is influenced by ramp voltage VRAMP besides R divider as shown in Figure 11. The VRAMP can be calculated as shown VFB(AVG) R2 (VOUT -VFB(AVG) ) R4 +R9 The VFB(AVG) is the average value on the FB, VFB(AVG) varies with the Vin, Vo, and load condition, etc., its value on the skip mode would be lower than that of the PWM mode, which means the load regulation is strictly related to the VFB(AVG). Also the line regulation is related to the VFB(AVG) ,If one wants to gets a better load or line regulation, a lower Vramp is suggested once it meets equation 9. For PWM operation, VFB(AVG) value can be deduced from equation 13. R1 //R2 1 VFB(AVG)  VREF  VRAMP  2 R1 //R2  R9 (13) Usually, R9 is set to 0Ω, and it can also be set following equation 14 for a better noise immunity. It should also set to be 5 timers smaller than R1//R2 to minimize its influence on Vramp. R9  1 2 C4  2FSW (14) Using equation 12 to calculate the output voltage can be complicated. To simplify the calculation of R1 in equation 12, a DC-blocking capacitor Cdc can be added to filter the DC influence from R4 and R9. Figure 12 shows a simplified circuit with external ramp compensation and a DC-blocking capacitor. With this capacitor, R1 can easily be obtained by using equation 15 for PWM mode operation. 1 (VOUT  VREF  VRAMP ) 2 R1  R2 1 VREF  VRAMP 2 (15) Cdc is suggested to be at least 10 times larger than C4 for better DC blocking performance, and should also not larger than 0.47uF considering start up performance. In case one wants to use MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 13 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER VIN  IOUT V V  OUT  (1  OUT ) fSW  CIN VIN VIN (18) EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 larger Cdc for a better FB noise immunity, combined with reduced R1 and R2 to limit the Cdc in a reasonable value without affecting the system start up. Be noted that even when the Cdc is applied, the load and line regulation are still Vramp related. Under worst-case conditions where VIN = 2VOUT: VIN  I 1  OUT 4 fSW  CIN (19) Output Capacitor The output capacitor is required to maintain the DC output voltage. Ceramic or POSCAP capacitors are recommended. The output voltage ripple can be estimated as: VOUT  Figure12—Simplified Circuit of Ceramic Capacitor with DC blocking capacitor Input Capacitor The input current to the step-down converter is discontinuous and therefore requires a capacitor to supply the AC current to the step-down converter while maintaining the DC input voltage. Ceramic capacitors are recommended for best performance and should be placed as close to the VIN pin as possible. Use capacitors with X5R and X7R ceramic dielectrics because they are fairly stable with temperature fluctuations. R The capacitors must also have a ripple current rating greater than the maximum input ripple current of the converter. The input ripple current can be estimated as follows: VOUT V (16) ICIN  IOUT   (1  OUT ) VIN VIN N O T The worst-case condition occurs at VIN = 2VOUT, where: ICIN  IOUT 2 (17) For simplification, choose the input capacitor with an RMS current rating greater than half of the maximum load current. The input capacitance value determines the input voltage ripple of the converter. If there is an input voltage ripple requirement in the system, choose the input capacitor that meets the specification. The input voltage ripple can be estimated as follows: VOUT V 1  (1  OUT )  (RESR  ) (20) FSW  L VIN 8  FSW  COUT In the case of ceramic capacitors, the impedance at the switching frequency is dominated by the capacitance. The output voltage ripple is mainly caused by the capacitance. For simplification, the output voltage ripple can be estimated as: VOUT  VOUT V  (1  OUT ) 8  FSW 2  L  COUT VIN (21) The output voltage ripple caused by ESR is very small. Therefore, an external ramp is needed to stabilize the system. The external ramp can be generated through resistor R4 and capacitor C4 following equation 5, 8 and 9. In the case of POSCAP capacitors, the ESR dominates the impedance at the switching frequency. The ramp voltage generated from the ESR is high enough to stabilize the system. Therefore, an external ramp is not needed. A minimum ESR value around 12mΩ is required to ensure stable operation of the converter. For simplification, the output ripple can be approximated as: VOUT  VOUT V  (1  OUT )  RESR FSW  L VIN (22) Maximum output capacitor limitation should be also considered in design application. MP28258 has an around 1ms soft-start time period. If the output capacitor value is too high, the output voltage can’t reach the design value during the soft-start time, and then it will fail to regulate. The maximum output capacitor value Co_max can be limited approximately by: CO _ MAX  (ILIM _ AVG  IOUT )  Tss / VOUT MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. (23) 14 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER Where, ILIM_AVG is the average start-up current during soft-start period. Tss is the soft-start time. EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 Inductor The inductor is necessary to supply constant current to the output load while being driven by the switched input voltage. A larger-value inductor will result in less ripple current that will result in lower output ripple voltage. However, a larger-value inductor will have a larger physical footprint, higher series resistance, and/or lower saturation current. A good rule for determining the inductance value is to design the peak-topeak ripple current in the inductor to be in the range of 30% to 40% of the maximum output current, and that the peak inductor current is below the maximum switch current limit. The inductance value can be calculated by: L VOUT V  (1  OUT ) fSW  IL VIN (24) Where ∆IL is the peak-to-peak inductor ripple current. O T R The inductor should not saturate under the maximum inductor peak current, where the peak inductor current can be calculated by: VOUT V (25) ILP  IOUT   (1  OUT ) 2fSW  L VIN N Recommend Design Example Some design examples and recommended maximum output capacitor value with typical outputs are provided below when the ceramic capacitors is applied with R9=0ohm: Table 1: 1.2V VOUT (L = 2μH) VIN VOUT (V) (V) C1 R7 (Ω) R4 (Ω) C4 (F) R1 (Ω) R2 (Ω) FSW (Hz) 12 1.2 10μF*1 300k 499k 220p 12.1k 24.3k 450k 5 1.2 10μF*1 300k 390k 220p 12.1k 24.3k 440k 3.3 1.2 10μF*1 300k 243k 220p 12.1k 24.3k 435k Table 2: 1.8V VOUT (L = 2μH) VIN VOUT (V) (V) C1 R7 (Ω) R4 (Ω) C4 (F) R1 (Ω) R2 (Ω) FSW (Hz) 12 1.8 10μF*1 402k 499k 220p 30.1k 24.3k 480k 5 1.8 10μF*1 402k 390k 220p 30.1k 24.3k 460k 3.3 1.8 10μF*2 402k 280k 220p 30.1k 24.3k 450k Note: For 1.8V VOUT from 3.3V VIN, a larger C1 is recommended to sustain maximum 4A load. Table 3: 2.5V VOUT (L = 4.2μH) VIN VOUT (V) (V) C1 R7 (Ω) R4 (Ω) C4 (F) R1 (Ω) R2 (Ω) FSW (Hz) 12 2.5 10μF*1 500k 453k 390p 21.5k 10k 500k 5 2.5 10μF*1 500k 453k 390p 21.5k 10k 500k Table 4: 3.3V VOUT (L = 6.5μH) VIN VOUT (V) (V) C1 R7 (Ω) R4 (Ω) C4 (F) R1 (Ω) R2 (Ω) FSW (Hz) 12 3.3 10μF*1 680k 470k 330p 31.6k 10k 500k 5 3.3 10μF*1 680k 470k 330p 31.6k 10k 500k Table 5: 5V VOUT (L = 8.8μH) VIN VOUT (V) (V) 12 5 C1 R7 (Ω) 10μF*1 1M R4 (Ω) C4 (F) 750k 330p R1 (Ω) R2 (Ω) FSW (Hz) 53.6k 10k 500k The detailed application schematic is shown in Figure 13 when large ESR caps are used, and Figure14 and Figure 15 when low ESR caps are applied. The typical performance and circuit waveforms have been shown in the Typical Performance Characteristics section. For more possible applications of this device, please refer to related Evaluation Board Data Sheets. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 15 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER Typical Application Schematic R3 0 EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 9 C1A TBD 25V IN BST R7 TBD MP28257 C7 1nF 8 4 R10 100k L1 TBD SW 2 10 SW FREQ VOUT VCC GND R1 TBD R5 499k GND PG 1 7 GND FB 5 EN 6 PG EN GND VIN 3 R2 TBD 11 12 Figure 13—Typical Application Schematic with No External Ramp 9 C1A TBD 25V R3 0 8 L1 TBD SW 2 10 SW FREQ R1 TBD R9 0 1 7 GND FB VOUT GND TBD R5 499k 5 EN 6 PG C2E NS C4 TBD R4 VCC GND PG 3 MP28257 4 EN BST R7 TBD C7 1nF R10 100k IN GND VIN R2 TBD 11 12 R Figure 14—Typical Application Schematic with Low ESR Ceramic Capacitor C1A TBD 25V BST 3 R3 0 MP28257 8 4 SW 2 10 SW FREQ VCC L1 TBD R4 TBD C4 FB 1 VOUT GND R1 TBD 7 GND 5 EN 6 PG C2E NS TBD Cdc TBD R5 499k GND PG IN R7 TBD C7 1nF R10 100k EN 9 GND N O T VIN R2 TBD 11 12 Figure 15—Typical Application Schematic with Low ESR Ceramic Capacitor\ and DC Blocking Capacitor. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 16 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 Layout Recommendation 1) The high current paths (GND, IN, and SW) should be placed very close to the device with short, wide, and direct traces. Put the input capacitors as close to the IN and GND pins as possible. 3) Put the decoupling capacitor as close to the VCC and GND pins as possible. 4) Keep the switching node SW short and away from the feedback network. 5) The external feedback resistors should be placed next to the FB pin. Make sure that there is no via on the FB trace. 6) Keep the BST voltage path (BST, C3, and SW) as short as possible. 7) Four-layer layout is recommended to achieve better thermal performance. N O T R 2) MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 17 MP28257 –4A, 4.2V-TO-20V, FAST TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTER PACKAGE INFORMATION EC R NE O EF W M M ER D E E N TO SI D ED G M N P2 S FO 38 R 4 QFN12 (2x3mm) 1.90 2.10 PIN 1 ID MARKING 12 0.35 0.45 2.90 3.10 PIN 1 ID INDEX AREA 0.45 0.55 0.20 0.30 11 1 0.35 0.45 1.10 0.40 0.00 0.20 0.30 0.50 BSC 0.35 0.45 TOP VIEW 5 7 0.35 0.45 6 BOTTOM VIEW 0.80 1.00 0.20 REF 0.00 0.05 SIDE VIEW 1.90 0.60 1.80 R 0.25 1.30 0.90 N O T 0.60 0.20 0.00 NOTE: 1) 2) 3) 4) 5) ALL DIMENSIONS ARE IN MILLIMETERS. EXPOSED PADDLE SIZE DOES NOT INCLUDE MOLD FLASH. LEAD COPLANARITY SHALL BE0.10 MILLIMETER MAX. JEDEC REFERENCE DRAWING IS JEDEC MO-220 DRAWING IS NOT TO SCALE. 0.25 0.50 0.70 1.45 0.70 0.25 RECOMMENDED LAND PATTERN NOTICE: The information in this document is subject to change without notice. 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. MP28257 Rev 1.01 www.MonolithicPower.com 4/13/2020 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2020 MPS. All Rights Reserved. 18