MP8774HGQ-Z

MP8774H 12A, Wide-Input 3V to 18V, 1.4MHz Synchronous Step-Down Converter with PG and External Soft Start in 3mmx3mm QFN Package DESCRIPTION FEATURES The MP8774H is a fully integrated, highfrequency, synchronous, rectified, step-down, switch-mode converter with internal power MOSFETs. The MP8774H offers a very compact solution that achieves 12A of continuous output current with excellent load and line regulation over a wide input range. The MP8774H uses synchronous mode operation for higher efficiency over the output current load range.           Constant-on-time (COT) control operation provides very fast transient response, easy loop design, and very tight output regulation.    Full protection features include short-circuit protection (SCP), over-current protection (OCP), under-voltage protection (UVP), and thermal shutdown. Output Adjustable from 0.6V Wide 3V to 18V Operating Input Range 12A Output Current 16mΩ/5.5mΩ Low RDS(ON) Internal Power MOSFETs 100μA Quiescent Current High-Efficiency Synchronous Mode Operation Pre-Biased Start-Up Fixed 1.4MHz Switching Frequency External Programmable Soft-Start Time Enable (EN) and Power Good (PG) for Power Sequencing Over-Current Protection and Hiccup Mode Thermal Shutdown Available in a QFN-16 (3mmx3mm) Package APPLICATIONS The MP8774H requires a minimal number of readily available, standard external components, and is available in a space-saving QFN-16 (3mmx3mm) package.      Security Cameras AP Routers, XDSL Devices Digital Set-Top Boxes Flat-Panel Television and Monitors General Purpose All MPS parts are lead-free, halogen-free, and adhere to the RoHS directive. For MPS green status, visit the MPS website under Quality Assurance. “MPS”, the MPS logo, and “Simple, Easy Solutions” are registered trademarks of Monolithic Power Systems, Inc. or its subsidiaries. TYPICAL APPLICATION Efficiency vs. Load Current VOUT = 1V, L = 0.33μH, DCR = 1.1mΩ 3V-18V VIN BST C1 22µFx2 C3 0.1µF L1 0.33µH MP8774H PG 100 95 1V/12A VOUT SW PG EN R1 20kΩ ENABLE FB AGND VCC PGND C4 1µF R4 1kΩ SS C5 22nF R2 30kΩ C2 22µFx4 EFFICIENCY (%) VIN 90 85 80 75 VIN=3.3V 70 VIN=5V 65 VIN=12V 60 0 2 4 6 8 10 12 LOAD CURRENT (A) MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 1 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER ORDERING INFORMATION Part Number* MP8774HGQ Package QFN-16 (3mmx3mm) Top Marking See Below * For Tape & Reel, add suffix –Z (e.g. MP8774HGQ–Z). TOP MARKING BJU: Product code of MP8774HGQ Y: Year code LLL: Lot number PACKAGE REFERENCE TOP VIEW SW 16 NC 1 15 NC BST 2 14 VCC EN 3 13 PGND FB 4 12 PGND 5 11 PGND SS 6 10 PGND PG 7 9 PGND AGND 8 VIN QFN-16 (3mmx3mm) MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 2 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER PIN FUNCTIONS Pin # 1, 15 2 3 4 5 6 7 8 9, 10, 11, 12, 13 14 16 Name NC Description No connection. NC must be left floating. Bootstrap. Connect a capacitor between SW and BST to form a floating supply across the BST high-side switch driver. A BST resistor less than 4.7Ω is recommended. Enable. Pull EN high to enable the MP8774H. When floating, EN is pulled down to GND EN and disabled by an internal 3.3MΩ resistor. Feedback. FB sets the output voltage when connected to the tap of an external resistor FB divider between output and GND. Signal ground. AGND is not connected to the system ground internally. Ensure that AGND AGND is connected to the system ground in the PCB layout. Soft start. Connect a capacitor across SS and GND to set the soft-start time and avoid SS inrush current at start-up. Power good output. The output of PG is an open drain. PG changes state if UVP, OCP, PG OTP, or OV occurs. Supply voltage. The MP8774H operates from a 3V to 18V input rail. A capacitor (C1) is VIN needed to decouple the input rail. Use a wide PCB trace to make the connection. System ground. PGND is the reference ground of the regulated output voltage. PGND PGND requires careful consideration during the PCB layout. PGND is recommended to be connected to GND with coppers and vias. Internal bias supply output. Decouple VCC with a 1µF capacitor. Place the VCC capacitor VCC close to VCC and GND. SW Switch output. Connect SW with a wide PCB trace. θJA θJC ABSOLUTE MAXIMUM RATINGS (1) Thermal Resistance VIN .................................................-0.3V to +20V VSW ........................................ -0.3V (-5V < 10ns) to VIN + 0.7V (23V < 10ns) VBST ...................................................... VSW + 4V VEN ................................................................. VIN All other pins .................................. -0.3V to +4V Continuous power dissipation (TA = 25°C) (2) (4) ................................................................... 3.2W Junction temperature ................................150°C Lead temperature .....................................260°C Storage temperature ............... -65°C to +125°C QFN-16 (3mmx3mm) EV8774H-Q-00A (4) ................ 38 ...... 10 .... °C/W JESD51-7 (5) .......................... 50 ...... 12 .... °C/W Recommended Operating Conditions (3) Supply voltage (VIN) ............................ 3V to 18V Output voltage (VOUT) ............. 0.6V to VIN * DMAX or 12V max Operating junction temp (TJ) .... -40°C to +125°C 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 produces an excessive die temperature, causing the regulator to 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 EV8774H-Q-00A, 4-layer PCB. 5) The value of θJA given in this table is only valid for comparison with other packages and cannot be used for design purposes. These values were calculated in accordance with JESD51-7, and simulated on a specified JEDEC board. They do not represent the performance obtained in an actual application. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 3 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER ELECTRICAL CHARACTERISTICS (6) VIN = 12V, TJ = -40°C to +125°C, typical value is tested at TJ = 25°C, unless otherwise noted. Parameter Symbol Condition Input voltage range VIN Supply Current Supply current (shutdown) IIN VEN = 0V Supply current (quiescent) IQ VEN = 2V, VFB = 0.65V MOSFET HS switch on resistance HSRDS(ON) VBST-SW = 3.3V LS switch on resistance LSRDS(ON) VCC = 3.3V Switch leakage SWLKG VEN = 0V, VSW = 17V, TJ = 25°C Current Limit and ZCD Valley current limit ILIMIT_VY (7) Short hiccup duty cycle DHICCUP ZCD IZCD Switching Frequency and Minimum On/Off Timer Switching frequency fSW (7) Minimum on time tON_MIN (7) Minimum off time tOFF_MIN Reference and Soft Start TJ = 25°C Feedback voltage VFB TJ = -40°C to +125°C Feedback current IFB VFB = 700mV Soft-start current ISS_START Enable and UVLO EN rising threshold VEN RISING EN falling threshold VEN FALLING EN pull-down resistor REN_PD VCC VCC under-voltage lockout VCCVth threshold rising VCC under-voltage lockout VCCHYS threshold VCC regulator VCC VCC load regulation RegVCC ICC = 5mA Min Typ 3 100 Max Units 18 V 5 150 µA µA 1 mΩ mΩ µA 16 5.5 12 14 10 200 1200 1400 50 100 1600 594 591 600 600 10 6 606 609 50 8 1.1 0.9 1.25 1 1.2 1.4 1.1 V V MΩ 2.6 2.8 3 V 4 A % mA kHz ns ns mV nA µA 350 mV 3.4 3 V % MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 4 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER ELECTRICAL CHARACTERISTICS (continued) (6) VIN = 12V, TJ = -40°C to +125°C, typical value is tested at TJ = 25°C, unless otherwise noted. Parameter Power Good Power good UV rising threshold Power good UV falling threshold Power good OV rising threshold Power good OV falling threshold Power good delay Power good sink current capability Power good leakage current Thermal Protection Thermal shutdown (7) Thermal hysteresis (7) Symbol Condition Min Typ Max Units PGUVvth_Hi 0.85 0.9 0.95 VFB PGUVvth_Lo 0.75 0.80 0.85 VFB PGOVvth_Hi 1.15 1.2 1.25 VFB PGOVvth_Lo 1.05 1.1 1.15 VFB PGTd Both edges VPG Sink 4mA 0.4 V IPG_LEAK VPG = 5V 10 μA TSD TSD-HYS 50 150 20 µs °C °C Notes: 6) 7) Guaranteed by over-temperature correlation, not tested in production. Guaranteed by design and characterization test. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 5 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS Efficiency vs. Load Current Efficiency vs. Load Current VOUT = 1V, L = 0.33μH, DCR = 1.1mΩ VOUT = 1.2V, L = 0.33μH, DCR = 1.1mΩ 100 100 95 95 90 90 EFFICIENCY (%) EFFICIENCY (%) VIN = 12V, VOUT = 1V, L = 0.33µH, TA = 25°C, unless otherwise noted. 85 80 75 VIN=5V 70 VIN=12V 65 85 80 75 VIN=5V 70 VIN=12V 65 VIN=18V VIN=18V 60 60 0 2 4 6 8 10 0 12 2 8 10 Efficiency vs. Load Current Efficiency vs. Load Current VOUT = 1.5V, L = 0.33μH, DCR = 1.1mΩ VOUT = 1.8V, L = 0.47μH, DCR = 0.9mΩ 100 100 95 95 90 90 EFFICIENCY (%) EFFICIENCY (%) 6 85 80 75 VIN=5V 70 VIN=12V 65 12 LOAD CURRENT (A) LOAD CURRENT (A) 85 80 75 VIN=5V 70 VIN=12V 65 VIN=18V 60 VIN=18V 60 0 2 4 6 8 10 12 0 2 LOAD CURRENT (A) 95 95 90 90 EFFICIENCY (%) 100 85 80 VIN=5V VIN=12V 65 8 80 75 VIN=5V 70 VIN=12V VIN=18V 60 60 2 4 6 8 LOAD CURRENT (A) 12 85 65 VIN=18V 0 10 VOUT = 3.3V, L = 0.56μH, DCR = 1.61mΩ 100 70 6 Efficiency vs. Load Current VOUT = 2.5V, L = 0.47μH, DCR = 0.9mΩ 75 4 LOAD CURRENT (A) Efficiency vs. Load Current EFFICIENCY (%) 4 10 12 0 2 4 6 8 10 12 LOAD CURRENT (A) MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 6 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 12V, VOUT = 1V, L = 0.33µH, TA = 25°C, unless otherwise noted. Efficiency vs. Load Current Efficiency vs. Load Current VIN = 5V, L = 0.33µH, DCR = 1.1mΩ 100 100 95 95 90 90 EFFICIENCY (%) EFFICIENCY (%) VIN = 5V, L = 0.68µH, DCR = 1.58mΩ 85 80 75 VIN=7V 70 VIN=12V 65 85 80 75 Vout=1.2V 65 VIN=18V Vout=1.5V 60 60 0 2 4 6 8 10 0 12 2 6 8 10 12 LOAD CURRENT (A) Load Regulation vs. Load Current Load Regulation vs. Load Current VOUT = 1.2V 0.5 0.5 0.4 0.4 LOAD REGULATION (%) 0.3 0.2 0.1 0 -0.1 -0.2 VIN=5V -0.3 VIN=12V -0.4 VIN=18V 0.3 0.2 0.1 0 -0.1 -0.2 VIN=5V -0.3 VIN=12V -0.4 VIN=18V -0.5 -0.5 0 2 4 6 8 10 0 12 2 LOAD CURRENT (A) 4 6 8 10 12 LOAD CURRENT (A) Load Regulation vs. Load Current Load Regulation vs. Load Current VOUT = 1.5V VOUT = 1.8V 0.5 0.5 0.4 0.4 0.3 0.3 LOAD REGULATION (%) LOAD REGULATION (%) 4 LOAD CURRENT (A) VOUT = 1V LOAD REGULATION (%) Vout=1V 70 0.2 0.1 0 -0.1 -0.2 VIN=5V -0.3 VIN=12V -0.4 VIN=18V -0.5 0.2 0.1 0 -0.1 -0.2 VIN=5V -0.3 VIN=12V -0.4 VIN=18V -0.5 0 2 4 6 8 LOAD CURRENT (A) 10 12 0 2 4 6 8 10 12 LOAD CURRENT (A) MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 7 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 12V, VOUT = 1V, L = 0.33µH, TA = 25°C, unless otherwise noted. Load Regulation vs. Load Current Load Regulation vs. Load Current VOUT = 3.3V 0.5 0.5 0.4 0.4 LOAD REGULATION (%) LOAD REGULATION (%) VOUT = 2.5V 0.3 0.2 0.1 0 -0.1 -0.2 VIN=5V -0.3 VIN=12V -0.4 VIN=18V 0.3 0.2 0.1 0 -0.1 -0.2 VIN=5V -0.3 VIN=12V -0.4 VIN=18V -0.5 -0.5 0 2 4 6 8 10 0 12 2 4 6 8 10 12 LOAD CURRENT (A) LOAD CURRENT (A) Load Regulation vs. Load Current Line Regulation vs. Input Voltage 0.5 0.5 0.4 0.4 LINE REGULATION (%) LOAD REGULATION (%) VOUT = 5V 0.3 0.2 0.1 0 -0.1 -0.2 VIN=7V -0.3 VIN=12V -0.4 VIN=18V 0.3 0.2 0.1 0 -0.1 -0.2 Io=0.01A -0.3 Io=6A -0.4 Io=12A -0.5 -0.5 0 2 4 6 8 10 3 12 Case Temperature Rise vs. Output Current 50 40 V FB (V) CASE TEMPERATURE RISE (℃) 60 30 20 10 0 2 3 4 5 6 Io (A) 7 8 12 15 18 VFB vs. Temperature 70 1 9 INPUT VOLTAGE (V) LOAD CURRENT (A) 0 6 9 10 11 12 0.605 0.604 0.603 0.602 0.601 0.6 0.599 0.598 0.597 0.596 0.595 -25 25 75 125 TEMPERATURE (℃) MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 8 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 12V, VOUT = 1V, L = 0.33µH, TA = 25°C, unless otherwise noted. EN Rising and Falling vs. Temperature Enabled Supply Current vs. Input Voltage 120 ENABLED SUPPLY CURRENT (μA) EN RISING AND FALLING (V) 1.3 110 1.2 100 1.1 1 RISING FALLING 0.9 -25 25 75 125 TEMPERATURE (℃) 90 80 70 60 50 40 3 6 9 12 15 INPUT VOLTAGE (V) 18 Disabled Supply Current vs. Input Voltage ENABLED SUPPLY CURRENT (μA) 5 4 3 2 1 0 3 6 9 12 15 INPUT VOLTAGE (V) 18 MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 9 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 12V, VOUT = 1V, L = 0.33µH, TA = 25°C, unless otherwise noted. Input/Output Ripple Input/Output Ripple IOUT = 0A IOUT = 0A CH1: VOUT/AC 20mV/div. CH2: VIN/AC 50mV/div. CH1: VOUT/AC 50mV/div. CH2: VIN/AC 50mV/div. CH3: VSW 10V/div. CH3: VSW 10V/div. CH4: IL 10A/div. CH4: IL 2A/div. 40ms/div. 2µs/div. Input/Output Ripple Start-Up through Input Voltage IOUT = 12A IOUT = 0A CH1: VOUT/AC 10mV/div. CH2: VIN/AC 200mV/div. CH1: VOUT 1V/div. CHR1: VPG 5V/div. CH2: VIN 10V/div. CH3: VSW 10V/div. CH3: VSW 10V/div. CH4: IL 2A/div. CH4: IL 10A/div. 1µs/div. 1ms/div. Start-Up through Input Voltage Shutdown through Input Voltage IOUT = 12A IOUT = 0A CH1: VOUT 1V/div. CHR1: VPG 5V/div. CH1: VOUT 1V/div. CHR1: VPG 5V/div. CH2: VIN 10V/div. CH3: VSW 10V/div. CH2: VIN 10V/div. CH3: VSW 10V/div. CH4: IL 10A/div. CH4: IL 10A/div. 1ms/div. 40ms/div. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 10 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 12V, VOUT = 1V, L = 0.33µH, TA = 25°C, unless otherwise noted. Shutdown through Input Voltage Start-Up through EN IOUT = 12A IOUT = 0A CH1: VOUT 1V/div. CHR1: VPG 5V/div. CH1: VOUT 1V/div. CHR1: VPG 5V/div. CH2: VEN 5V/div. CH2: VIN 10V/div. CH3: VSW 10V/div. CH3: VSW 10V/div. CH4: IL 2A/div. CH4: IL 10A/div. 4ms/div. 2ms/div. Start-Up through EN Shutdown through EN IOUT = 12A IOUT = 0A CH1: VOUT 1V/div. CHR1: VPG 5V/div. CH1: VOUT 1V/div. CHR1: VPG 5V/div. CH2: VEN 5V/div. CH3: VSW 10V/div. CH2: VEN 5V/div. CH3: VSW 5V/div. CH4: IL 2A/div. CH4: IL 10A/div. 2ms/div. 400ms/div. Shutdown through EN Short-Circuit Protection Entry IOUT = 12A IOUT = 0A CH1: VOUT 1V/div. CHR1: VPG 5V/div. CH1: VOUT 1V/div. CH2: VPG 5V/div. CH2: VEN 5V/div. CH3: VSW 10V/div. CH3: VSW 10V/div. CH4: IL 10A/div. CH4: IL 10A/div. 200µs/div. 20ms/div. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 11 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN = 12V, VOUT = 1V, L = 0.33µH, TA = 25°C, unless otherwise noted. Short-Circuit Protection Steady State Short-Circuit Protection Recovery IOUT = 0A Short output to GND CH1: VOUT 1V/div. CH1: VOUT 1V/div. CH2: VPG 5V/div. CH2: VPG 5V/div. CH3: VSW 10V/div. CH3: VSW 10V/div. CH4: IL 10A/div. CH4: IL 10A/div. 20ms/div. 20ms/div. Load Transient IOUT = 6A to 12A CH1: VOUT/AC 50mV/div. CH4: IL 5A/div. 200µs/div. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 12 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER FUNCTIONAL BLOCK DIAGRAM VIN Bias & Voltage Reference EN 3.3MΩ Bootstrap Regulator BST 3.3V LDO HS Driver Main Switch (NCH) ISS SS SW EA On Timer Logic Control VCC COMP FB BUF LS Driver Ramp PWM Current Modulator 90% VREF Rising 80% VREF Falling Synchronous Rectifier (NCH) Current Sense Amplifier PG 120% VREF Rising 110% VREF Falling GND Figure 1: Functional Block Diagram MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 13 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER OPERATION The MP8774H is a fully integrated, synchronous, rectified, step-down, switch-mode converter. Constant-on-time (COT) control is employed to provide fast transient response and ease loop stabilization. Figure 2 shows the simplified ramp compensation block in the MP8774H. At the beginning of each cycle, the high-side MOSFET (HS-FET) turns on when the feedback voltage (VFB) is below the reference voltage (VREF), which indicates an insufficient output voltage. The on period is determined by both the output voltage and input voltage to make the switching frequency fairly constant over the input voltage range. After the on period elapses, the HS-FET turns off. The HS-FET turns on again when VFB drops below VREF. By repeating operation in this way, the converter regulates the output voltage. The integrated low-side MOSFET (LS-FET) turns on when the HS-FET is off to minimize conduction loss. There is a dead short, called shootthrough, between the input and GND if both the HS-FET and LS-FET are turned on at the same time. To avoid shoot-through, a dead time (DT) is generated internally between the HS-FET off and LS-FET on period, or vice versa. Internal compensation is applied for COT control to provide a more stable operation, even when ceramic capacitors are used as output capacitors. This internal compensation improves jitter performance without affecting the line or load regulation. voltage (VEAO), the HS-FET turns on for a fixed interval, determined by the one-shot on-timer. When the HS-FET turns off, the LS-FET turns on until the next period. Figure 3: Heavy-Load Operation In CCM operation, the switching frequency is fairly constant. This is called pulse-width modulation (PWM) mode. Light-Load Operation When the MP8774H works in pulse-frequency modulation (PFM) during light-load operation, the MP8774H reduces the switching frequency automatically to maintain high efficiency, and the inductor current drops almost to zero. When the inductor current reaches zero, the LS-FET driver goes into tri-state (Hi-Z) (see Figure 4). Therefore, the output capacitors discharge slowly to GND through the LS-FET, R1, and R2. This operation improves device efficiency greatly when the output current is low. tON is constant VIN REF FB On Timer BUF RAMP Logic Control L VOUT VSW SW RESR R1 VOUT COUT RAMP GENERATOR IL IOUT R2 PWM VRAMP Figure 2: Simplified Ramp Compensation Block Heavy-Load Operation Continuous conduction mode (CCM) is when the output current is high and the inductor current is always above 0A (see Figure 3). When VFB is below the error amplifier output VEAO Figure 4: Light-Load Operation MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 14 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER Light-load operation is also called skip mode because the HS-FET does not turn on as frequently as it does during heavy-load conditions. The HS-FET turn-on frequency is a function of the output current. As the output current increases, the current modulator regulation time period 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 with Equation (1): IOUT  (VIN  VOUT )  VOUT 2  L  fSW  VIN (1) The device reverts to PWM mode once the output current exceeds the critical level. Afterward, the switching frequency remains fairly constant over the output current range. VCC Regulator The 3.4V internal regulator powers most of the internal circuitries. This regulator takes VIN and operates in the full VIN range. When VIN exceeds 3.4V, the output of the regulator is in full regulation. When VIN falls below 3.4V, the output of the regulator decreases following VIN. A 1μF decoupling ceramic capacitor is needed at VCC. Enable (EN) EN is a digital control pin that turns the regulator on and off. Drive EN above 1.25V to turn on the regulator. Drive EN below 1V to turn off the regulator. When floating, EN is pulled down to GND by an internal 3.3MΩ resistor. EN can be connected directly to VIN, and supports a 18V input range. Under-Voltage Lockout (UVLO) Under-voltage lockout (UVLO) protects the chip from operating at an insufficient supply voltage. The MP8774H UVLO comparator monitors the output voltage of the internal regulator (VCC). The VCC UVLO rising threshold is about 2.8V, while its falling threshold is 2.45V. When the input voltage is higher than the UVLO rising threshold voltage, the MP8774H powers up. The MP8774H shuts off when the input voltage is lower than the UVLO falling threshold voltage. This is a non-latch protection. Soft Start (SS) The MP8774H employs a soft start (SS) mechanism to ensure smooth output ramping during power-up. When EN goes high, an internal current source (6μA) charges up the SS capacitor. The SS capacitor voltage takes over VREF to the PWM comparator. The output voltage ramps up smoothly with the SS voltage (VSS). Once VSS rises above VREF, it continues to ramp up until VREF takes over. At this point, the soft start finishes, and the device enters steadystate operation. The SS capacitor value can be determined with Equation (2): Css (nF)  0.83  t ss (ms)  Iss (A) VREF (V) (2) If the output capacitance is large, it is not recommended to set the SS time too short. Otherwise, the current limit can be reached easily during SS. An SS capacitor of less than 4.7nF should be avoided. Power Good (PG) Indicator PG is the open drain of a MOSFET that connects to VCC or another voltage source through a resistor (e.g. 100kΩ). The MOSFET turns on with the application of an input voltage, so PG is pulled to GND before SS is ready. After VFB reaches 90% of VREF, there is a 50μs delay, and then PG is pulled high. When VFB drops to 80% of VREF, PG is pulled low. When UVLO or over-temperature protection (OTP) occurs, PG is pulled low immediately. When an over-current (OC) condition occurs, PG is pulled low when VFB drops below 80% of VREF following a 0.05ms delay. When an overvoltage (OV) condition occurs, PG is pulled low when VFB rises above 120% of VREF following a 0.05ms delay. If VFB falls below 110% of VREF, PG is pulled high following a 0.05ms delay. If the input supply fails to power the MP8774H, PG is clamped low, even though PG is tied to an external DC source through a pull-up resistor. Figure 5 shows the relationship between the PG voltage and the pull-up current. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 15 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER Thermal Shutdown Thermal shutdown prevents the chip from operating at exceedingly high temperatures. When the silicon die temperature exceeds 150°C, the entire chip shuts down. When the temperature falls below its lower threshold (typically 130°C), the chip is enabled again. PG Clamped Voltage vs. Pull-Up Current PG CLAMPED VOLTAGE (V) 1.2 1 0.8 0.6 0.4 0.2 0 0 1 2 3 PULL-UP CURRENT (mA) 4 5 Figure 5: PG Clamped Voltage vs. Pull-Up Current Over-Current Protection (OCP) and ShortCircuit Protection (SCP) The MP8774H has a valley-limit control. The LS-FET monitors the current flowing through the LS-FET. The HS-FET waits until the valley current limit is removed before turning on again. Meanwhile, the output voltage drops until VFB is below the under-voltage (UV) threshold (typically 50% below the reference). Once UV is triggered, the device enters hiccup mode to restart the part periodically. During over-current protection (OCP), the MP8774H attempts to recover from the overcurrent fault with hiccup mode. This means that the chip disables the output power stage, discharges the soft-start capacitor, and attempts to soft start again automatically. If the over-current condition still remains after the soft start ends, the device repeats this operation cycle until the over-current condition disappears, and then the output rises back to the regulation level. OCP is a non-latch protection. Pre-Bias Start-Up The MP8774H is designed for monotonic startup into pre-biased loads. If the output is prebiased to a certain voltage during start-up, the BST voltage is refreshed and charged, and the voltage on the soft-start capacitor is charged as well. If the BST voltage exceeds its rising threshold voltage and the soft-start capacitor voltage exceeds the sensed output voltage at FB, the part begins working normally. Floating Driver and Bootstrap Charging An external bootstrap capacitor powers the floating power MOSFET driver. This floating driver has its own UVLO protection, with a rising threshold of 1.7V and a hysteresis of 150mV. VIN regulates the bootstrap capacitor voltage internally through D1, M1, R4, C4, LO, and CO (see Figure 6). If VIN - VSW exceeds 5V, U2 regulates M1 to maintain a 3.3V BST voltage across C4. The BST resistor (R4) is recommended to be less than 4.7Ω. VIN D1 3.3V M1 R4 C4 U2 SW VOUT LO CO Figure 6: Internal Bootstrap Charger Start-Up and Shutdown Circuit If both VIN and EN exceed their respective thresholds, the chip starts up. The reference block starts first, generating a stable reference voltage and current, and then the internal regulator is enabled. The regulator provides a stable supply for the remaining circuits. Three events can shut down the chip: EN low, VIN low, and thermal shutdown. The shutdown procedure starts by blocking the signaling path initially to avoid any fault triggering. The internal supply rail is then pulled down. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 16 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER APPLICATION INFORMATION Setting the Output Voltage An external resistor divider is used to set the output voltage. First, choose a value for R2. R2 should be chosen carefully, as a small R2 leads to considerable quiescent current loss, while a large R2 makes FB noise-sensitive. R2 is recommended to be between 2kΩ and 100kΩ. Set the current through R2 to be below 250µA for a good balance between system stability and no-load loss. Then determine R1 with Equation (3): R1  VOUT  VREF  R2 VREF (3) VOUT FB R1 Cf Rt R2 Figure 7: Feedback Network Table 1 lists the recommended resistor values for common output voltages. Table 1: Resistor Selection for Common Output Voltages VOUT (V) 1.0 1.2 1.5 1.8 2.5 3.3 5 R1 (kΩ) 20 20 20 20 20 20 20 R2 (kΩ) 30 20 13 10 6.34 4.42 2.7 L (μH) 0.33 0.33 0.33 0.47 0.47 0.56 0.68 Cf (pF) 56 56 56 56 56 56 56 L VOUT V  (1  OUT ) fSW  IL VIN Rt (kΩ) 1 1 1 1 1 1 1 Selecting the Inductor An inductor is necessary for supplying constant current to the output load while being driven by the switched input voltage. A larger-value inductor results in less ripple current and a lower output ripple voltage, but also has a larger physical footprint, higher series resistance, and lower saturation current. A good rule for determining the inductance value is to (4) Where ∆IL is the peak-to-peak inductor ripple current. The inductor should not saturate under the maximum inductor peak current. Calculate the peak inductor current with Equation (5): ILP  IOUT  Figure 7 shows the feedback circuit. MP8774H design the peak-to-peak ripple current in the inductor to be between 30% and 40% of the maximum output current, and ensure that the peak inductor current is below the maximum switch current limit. The inductance value can be calculated with Equation (4): VOUT V  (1  OUT ) 2fSW  L VIN (5) Selecting the Input Capacitor The step-down converter has a discontinuous input current, and requires a capacitor to supply AC current to the converter while maintaining the DC input voltage. For the best performance, use ceramic capacitors placed as close to VIN as possible. Capacitors with X5R and X7R ceramic dielectrics are recommended because they are fairly stable amid temperature fluctuations. 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 with Equation (6): ICIN  IOUT  VOUT V  (1  OUT ) VIN VIN (6) The worst-case condition occurs at VIN = 2VOUT, calculated with Equation (7): ICIN  IOUT 2 (7) For simplification, choose an 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 an input capacitor that meets the specification. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 17 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER The input voltage ripple can be estimated with Equation (8): VIN  IOUT V V  OUT  (1  OUT ) fSW  CIN VIN VIN (8) The worst-case condition occurs at VIN = 2VOUT, calculated with Equation (9): VIN  I 1  OUT 4 fSW  CIN (9) Selecting the Output Capacitor An output capacitor is required to maintain the DC output voltage. Ceramic or POSCAP capacitors are recommended. The output voltage ripple can be estimated with Equation (10): VOUT  VOUT V 1  (1  OUT )  (RESR  ) fSW  L VIN 8  fSW  COUT (10) The maximum output capacitor value (Co_max) can be limited approximately with Equation (13): CO _ MAX  (ILIM_ AVG  IOUT )  t ss / VOUT (13) Where ILIM_AVG is the average start-up current during the soft-start period, and tss is the softstart time. Design Example Table 2 shows a design example when ceramic capacitors are applied. Table 2: Design Example 12V VIN 1V VOUT 12A IOUT For detailed application schematics, see page 20. The typical performance and waveforms are shown in the Typical Characteristics section on page 6. For more devices applications, refer to the related evaluation board datasheet. For ceramic capacitors, the capacitance dominates the impedance at the switching frequency. The output voltage ripple is mainly caused by the capacitance. For simplification, the output voltage ripple can be estimated with Equation (11): VOUT  VOUT V  (1  OUT ) 8  fSW 2  L  COUT VIN (11) For POSCAP capacitors, the ESR dominates the impedance at the switching frequency. For simplification, the output ripple can be estimated with Equation (12): VOUT  VOUT V  (1  OUT )  RESR fSW  L VIN (12) In addition to considering the output ripple, choosing a larger output capacitor can also result in a better load transient response. Be sure to consider the maximum output capacitor limitation in the design application. If the output capacitor value is too high, the output voltage cannot reach the design value during the softstart time, and fails to regulate. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 18 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER PCB Layout Guidelines Efficient PCB layout of the switching power supplies is critical for stable operation. Poor layout design can result in poor line or load regulation and stability issues. For better performance, it is recommended to use a 4layer board (two middle layers are GND). For best results, refer to Figure 8 and follow the guidelines below: Top Layer VIN GND 1. Place the high-current paths (GND, VIN, and SW) very close to the device with short, direct, and wide traces. 2. Place the input capacitor as close to VIN and GND as possible. Bottom Layer Figure 8: Recommended Layout 3. Place a VCC decoupling capacitor close to the device. 4. Connect AGND and PGND at the point of the VCC capacitor’s ground connection. 5. Place the external feedback resistors next to FB. 6. Keep the switching node (SW) short and away from the feedback network. GND VIN SW GND VOUT MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 19 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL APPLICATION CIRCUITS VIN 12V C1 22µF 8 C1A 22µF C1B 0.1µF VIN BST R3 0Ω C3 0.1µF L1 0.33µH R6 100kΩ MP8774H 3 EN PG 7 SW NC FB 14 PGND 9,10,11, 12,13 SS VOUT 1V 16 1,15 C6 56pF R1 C2 C2A C2B 20kΩ 22µF 22µF 22µF C2C 22µF 4 R2 30kΩ R4 1kΩ VCC C4 1µF AGND EN PG R5 100kΩ 2 6 C5 22nF 5 Figure 9: VIN = 12V, VOUT = 1V, IOUT = 12A (8) VIN 12V C1 22µF 8 C1A 22µF C1B 0.1µF VIN BST C3 0.1µF L1 0.33µH R6 100kΩ MP8774H 3 EN PG 7 R5 100kΩ SW NC FB 14 PGND 9,10,11, 12,13 SS VOUT 1.2V 16 1,15 C6 56pF R1 C2 C2A C2B 20kΩ 22µF 22µF 22µF C2C 22µF 4 R2 20kΩ R4 1kΩ VCC C4 1µF AGND EN PG 2 R3 0Ω 6 C5 22nF 5 Figure 10: VIN = 12V, VOUT = 1.2V, IOUT = 12A (8) VIN 12V C1 22µF 8 C1A 22µF C1B 0.1µF VIN BST C3 0.1µF L1 0.33µH MP8774H SW NC FB 9,10,11, 12,13 SS 5 VOUT 1.5V 16 1,15 C6 56pF R1 C2 C2A C2B 20kΩ 22µF 22µF 22µF C2C 22µF 4 R4 1kΩ VCC PGND C4 1µF 14 EN PG AGND 7 R5 100kΩ R3 0Ω R6 100kΩ 3 EN PG 2 6 R2 13kΩ C5 22nF Figure 11: VIN = 12V, VOUT = 1.5V, IOUT = 12A (8) MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 20 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL APPLICATION CIRCUITS (continued) VIN 12V C1 22µF 8 C1A 22µF C1B 0.1µF VIN BST C3 0.1µF L1 0.47µH 3 EN PG 7 SW NC FB 14 PGND 9,10,11, 12,13 SS VOUT 1.8V 16 1,15 C6 56pF R1 C2 C2A C2B 20kΩ 22µF 22µF 22µF C2C 22µF 4 R2 10kΩ R4 1kΩ VCC C4 1µF AGND R5 100kΩ R3 0Ω R6 100kΩ MP8774H EN PG 2 6 C5 22nF 5 Figure 12: VIN = 12V, VOUT = 1.8V, IOUT = 12A (8) VIN 12V C1 22µF 8 C1A 22µF C1B 0.1µF VIN BST C3 0.1µF L1 0.47µH 3 EN PG 7 SW NC FB 14 PGND 9,10,11, 12,13 SS VOUT 2.5V 16 1,15 C6 56pF R1 C2 C2A C2B 20kΩ 22µF 22µF 22µF C2C 22µF 4 R2 6.34kΩ R4 1kΩ VCC C4 1µF AGND R5 100kΩ R3 0Ω R6 100kΩ MP8774H EN PG 2 6 C5 22nF 5 Figure 13: VIN = 12V, VOUT = 2.5V, IOUT = 12A (8) VIN 12V C1 22µF 8 C1A 22µF C1B 0.1µF VIN BST C3 0.1µF L1 0.56µH 3 SW NC FB 9,10,11, 12,13 SS 5 VOUT 3.3V 16 1,15 C6 56pF R1 C2 C2A C2B 20kΩ 22µF 22µF 22µF C2C 22µF 4 R4 1kΩ VCC PGND C4 1µF 14 EN PG AGND 7 R5 100kΩ R3 0Ω R6 100kΩ MP8774H EN PG 2 6 R2 4.42kΩ C5 22nF Figure 14: VIN = 12V, VOUT = 3.3V, IOUT = 12A (8) MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 21 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER TYPICAL APPLICATION CIRCUITS (continued) VIN 12V C1 22µF 8 C1A 22µF C1B 0.1µF VIN BST C3 0.1µF L1 0.68µH 3 SW NC FB 9,10,11, 12,13 SS 5 VOUT 5V 16 1,15 C6 56pF R1 C2 C2A C2B 20kΩ 22µF 22µF 22µF C2C 22µF 4 R4 1kΩ VCC PGND C4 1µF 14 EN PG AGND 7 R5 100kΩ R3 0Ω R6 100kΩ MP8774H EN PG 2 6 R2 2.7kΩ C5 22nF Figure 15: VIN = 12V, VOUT = 5V, IOUT = 12A (8) Note: 8) When VIN is low, see the Selecting the Input Capacitor section on page 17. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 22 MP8774H – 18V, 12A, SYNCHRONOUS, STEP-DOWN CONVERTER PACKAGE INFORMATION QFN-16 (3mmx3mm) PIN 1 ID MARKING PIN 1 ID INDEX AREA TOP VIEW BOTTOM VIEW SIDE VIEW NOTE: 1) ALL DIMENSIONS ARE IN MILLIMETERS. 2) LEAD COPLANARITY SHALL BE 0.10 MILLIMETERS MAX. 3) JEDEC REFERENCE IS MO-220. 4) DRAWING IS NOT TO SCALE. 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. MP8774H Rev. 1.0 www.MonolithicPower.com 5/22/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. © 2019 MPS. All Rights Reserved. 23