NB650HGL-Z

NB650/NB650H High-Effeciency, Fast-Transient, 6A, 28V Synchronous Step-Down Converters with 2-Bit VID DESCRIPTION FEATURES The NB650/NB650H is fully-integrated, highfrequency, synchronous, rectified, step-down, switch-mode converters with dynamic-output– voltage control. It offers a very compact solution to achieve 6A of continuous output current over a wide input supply range, and has excellent load and line regulation. The NB650/NB650H operates at high efficiency over a wide outputcurrent–load range.     Wide 4.5V-to-28V Operating Input Range 6A Output Current Internal 50mΩ High-Side, 18mΩ Low-Side Power MOSFETs Proprietary Switching Loss Reduction Technique 1% Reference Voltage Programmable Soft-Start Time 2-bit VID Input Soft Shutdown Frequency Programmable from 150kHz to 1MHz SCP, OCP, OVP, UVP, and Thermal Shutdown Optional OCP Protection: Latch-Off Mode (NB650) and Hiccup Mode (NB650H) Output Adjustable from 0.6V to 13V Available in QFN17 (3mm×4mm) Package Constant-On-Time control mode provides fast transient response and eases loop stabilization.      2-bit VID inputs support changing the output voltage on-the-fly.  Full protection features include short-circuit protection, over-current protection, over-voltage protection, under-voltage protection, and thermal shut down.  The NB650/NB650H requires a minimal number of readily-available standard external components, and is available in a space-saving 3mm×4mm QFN17 package. APPLICATIONS        Notebook Systems and I/O Power Networking Systems Digital Set Top Boxes Flat-Panel Televisions and Monitors 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. TYPICAL APPLICATION （FOR NOTEBOOK） NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 1 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS ORDERING INFORMATION Part Number Package Top Marking NB650GL* NB650 QFN17 (3 x 4mm) NB650HGL** NB650H * For Tape & Reel, add suffix –Z (e.g. NB650GL–Z) ** For Tape & Reel, add suffix –Z (e.g. NB650HGL–Z) PACKAGE REFERENCE TOP VIEW SW SW FREQ SS 17 16 1 15 14 13 AGND 12 IN 11 IN GND 10 GND GND 9 GND SW 2 3 RFB1 RFB2 FB SW 4 5 6 7 8 BST PG EN VID1 VID2 VCC EXPOSED PAD ON BACKSIDE QFN17 (3x4mm) ABSOLUTE MAXIMUM RATINGS (1) Thermal Resistance (4) Supply Voltage VIN .......................................28V VSW ....................................... -0.3V to VIN + 0.3V VSW ............................. -3V to VIN + 3V for 200ns One-Shot On Time Minimum Off Time Fold-back Off Time(5) OCP hold-off time(5) Feedback Voltage Feedback Current Soft Start Charging Current tON tOFF tFB tOC VFB IFB ISS RFREQ=200kΩ, VOUT=1.2V RFREQ=200kΩ ILIM=1 ILIM=1 Soft Stop Charging Current EN Input Low Voltage EN Input High Voltage ISS VILEN VIHEN EN Input Current OVP Feedback Threshold Threshold(5) UVP Feedback VID Inputs Low Voltage VID Inputs High Voltage VID Inputs Current Equivalent FB Slew Rate During VID On-The-Fly(5) VID Switch On Resistance(5) Power Good Rising Threshold Power Good Falling Threshold Power Good Delay Power Good Sink Current Capability Power Good Leakage Current Standby Mode Delay Time(5) VIN Under Voltage Lockout Threshold Rising VIN Under Voltage Lockout Threshold Hysteresis Thermal Shutdown(5) IEN Min Typ 8 0 400 0 10 VFB = 600mV VSS=0V 200 100 1.2 50 600 10 10 VSS=0.6V 10 594 Max 1 606 100 0.4 2 VEN = 2V VEN = 0V 1.5 0 0.8 VFB-OV VFB-UV VILVID VIHVID IVID Units μA μA μA A ns ns μs μs mV nA μA μA V V μA V 0 V V V μA SRFB ±20 mV/μs VIDRDS-ON PGVth-Hi PGVth-Lo 100 0.9 0.85 Ω VFB VFB PGTd VPG 0.5 12 ms V nA μs INUVVth 4 V INUVHYS 800 mV TSD 150 °C IPG_LEAK tSTANDBY 0.4 0.4 2 Sink 4mA VPG = 3.3V 0.4 10 Note: 5) Not tested. Not guaranteed. NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 3 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS PIN FUNCTIONS QFN17 Pin # Name 1,2 SW 3 BST 4 PG 5 EN 6,7 VID1 VID2 8 VCC 9,10 GND 11 IN 12 AGND 13 FB 14,15 RFB2 RFB1 16 SS 17 FREQ Description Switch Output. Connect using wide PCB traces. Bootstrap. Requires a capacitor between SW and BST to form a floating supply across the high-side switch driver. Power Good. Output is an open drain and is high if the output voltage exceeds 90% of the nominal voltage. There is a delay from FB≥90%×Vref to PG goes high. EN=1 to enable. For automatic start-up, connect to VIN with a 100kΩ resistor. VID inputs. Control signals for the output-voltage scaling. Acts as the control signals for the internal VID switches. Usually uses an external resistor in parallel with the low-side FB resistor. Changing the VID ON/OFF state changes the FB divider scaling and result in different output voltages. Internal LDO output. The power supply of the internal control circuits. Decouple with 1μF capacitor. System Ground. The reference ground of the regulated output voltage. Layout requires extra care. Supply Voltage. Operates from a 4.5V-to-28V input rail. Requires C1 to decouple the input rail. Connect using wide PCB traces. Analog Ground. Feedback. Connect to the tap of an external resistor divider from the output to GND to set the output voltage. Drain of the internal VID switches. Typically uses an external resistor in parallel with the low-side FB resistor along with the internal VID switch to change the ON/OFF state of the VID switching to change the FB divider scaling and result in different output voltages. Soft-Start. Connect an external capacitor to program the soft-start time for the switchmode regulator. Frequency Set during CCM. The input voltage and the frequency-set resistor between the IN and FREQ pin determines the ON period. For best results, use an ON period longer than 200ns. NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 4 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS TYPICAL PERFORMANCE CHARACTERISTICS VIN=12V, VOUT =1.05V, L=1µH, TA=+25°C, unless otherwise noted. NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 5 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN=12V, VOUT =1.05V, L=1µH, TA=+25°C, unless otherwise noted. NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 6 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS TYPICAL PERFORMANCE CHARACTERISTICS (continued) VIN=12V, VOUT =1.05V, L=1µH, TA=+25°C, unless otherwise noted. NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 7 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS FUNCTIONAL BLOCK DIAGRAM Figure 1: Functional Block Diagram NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 8 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS OPERATION PWM Operation The NB650/NB650H is a fully-integrated, synchronous, rectified, step-down, switch-mode converter with dynamic output voltage control. It offers a very compact solution to achieve a 6A continuous output current over a wide input supply range, with excellent load and line regulation. The NB650/NB650H operates at high efficiency over a wide output current load range. Constant-on-time (COT) provides a fast transient response and easy loop stabilization. At the beginning of each cycle, the high-side MOSFET (HS-FET) turns on when the feedback voltage (VFB) falls below the reference voltage (VREF), which indicates an insufficient output voltage. The input voltage and the frequency-set resistor determine the ON as follows: t ON (ns)  9.6  RFREQ (k)  tDELAY1(ns) VIN (V)  0.4 (1) Where tDELAY1 is the 20ns delay of a comparator in the tON module. For best results, select tON ≥120ns. After the ON period elapses, the HS-FET turns off to enter the OFF state. The part turns ON again when VFB drops below VREF. By repeating this operation, the converter regulates the output voltage. The integrated low-side MOSFET (LSFET) turns on when the HS-FET is OFF to minimize conduction loss. There is a dead short between input and GND (shoot-through) if both HS-FET and LS-FET turn on at the same time. An internally-generated dead-time (DT) between HS-FET OFF and LS-FET ON, or LS-FET OFF and HS-FET OFF avoids shoot-through. Figure 2: Heavy-Load Operation Light-Load Operation When the load current decreases, the NB650/NB650H automatically reduces the switching frequency to maintain high efficiency. Figure 3 shows the light-load operation. VFB does not reach VREF when the inductor current approaches zero. As the output current drops from heavy-load condition, the inductor current also decreases and eventually approaches zero. The LS-FET driver enters a tri-state (high-Z) whenever the inductor current reaches zero. A current modulator takes control of the LS-FET and limits the inductor current to less than 600μA to slowly discharge the output capacitors to GND through LS-FET as well as R1 and R2A, R2B and R2C. The HS-FET does not turn ON as frequently as in heavy-load condition. As a result, the efficiency at light-load condition increases greatly. This operation mode is also called skip mode. Heavy-Load Operation As shown in Figure 2, the HS-FET and LS-FET repeatedly turn on/off when the output current is high, and the inductor current never goes to zero. It’s called continuous-conduction-mode (CCM) operation. In CCM operation, the switching frequency (fSW) is fairly constant. Figure 3: Light-Load Operation As the output current increases from the lightload condition, the time period within which the current modulator regulates becomes shorter. As the part exits light-load mode, the HS-FET turns on more frequently to increase the switching frequency. The output current reaches critical when the current modulator time is zero. The NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 9 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS following equation determines the critical level of the output current: IOUT  (VIN  VOUT )  VOUT 2  L  fSW  VIN (2) When the output current exceeds the critical level, light load mode turns into PWM mode, and the switching frequency stays fairly constant over the output current range. Switching Frequency The NB650/NB650H uses constant-on-time (COT) control, and has no dedicated internal oscillator. The input voltage is feed-forwarded to the on-time one-shot timer through the resistor RFREQ. The duty ratio is kept as VOUT/VIN. Hence, the switching frequency is fairly constant over the input voltage range. The switching frequency can be set as follows:  9.6  R FREQ (k)    t DELAY 1 (ns )    VIN ( V )  0.4   f SW (kHz )    V (V)   IN   t DELAY 2 (ns )  VOUT ( V )  Jitter and FB Ramp Slope Figure 5 and Figure 6 show jitter in both PWM and skip modes. When there is noise in the VFB downward slope, the ON time of HS-FET deviates from its intended level and produces jitter. There is a relationship between a system’s stability and the steepness of the VFB ripple’s downward slope: The steepness of the VFB ripple’s slope dominates in noise immunity. The magnitude of the VFB ripple doesn’t directly affect the noise immunity. 1  10 6 (3) Figure 5: Jitter in PWM Mode Where tDELAY2 is another comparator delay of about 40ns. Figure 6: Jitter in Skip Mode Ramp with Large ESR Cap When using POSCAPs or other types of capacitors with larger ESR as output capacitors. the ESR ripple dominates the output ripple, and the slope on the FB is ESR-related. Figure 7 shows an equivalent circuit in PWM mode with the HS-FET off and without an external ramp circuit. The application section includes design steps for large ESR capacitors. Figure 4: Plot of VOUT as a Function of RFREQ and the Frequency NB650/NB650H is optimized to operate at high switching frequencies at high efficiency. Higher switching frequencies allow for smaller LC filter components to reduce system PCB space. NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 10 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS And R2 is the equivalent resistor from FB to GND that varies with VID input, the ramp on the VFB can then be estimated as: SW L Vo ESR R1 FB VRAMP  POSCAP VIN  VO R1 // R2  t ON  R 4  C4 R1 // R2  R9 (7) R2 Figure 7: Simplified Circuit in PWM Mode without External Ramp Compensation To realize the stability without the use of an external ramp, select an ESR value as follows: RESR t SW t  ON  0.7   2 COUT (4) Usually R9 is set to 0Ω, then equation 7 can be simplified as: VRAMP  VSLOPE1  Ramp with Small ESR Capacitor The ESR ripple when using ceramic output capacitors is not high enough to stabilize the system and requires an external compensation ramp. The application section includes a description of designing with small ESR capacitors. SW R4 Vo C4 IR4 IC4 R9  VOUT  VRAMP  t off R 4  C4 As shown in 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 limitations from equation 5, then we can only reduce R4. For a stable PWM operation, the Vslope1 should be designed as follows. t SW t + ON -RESRCOUT Io 103 0.7  π 2 (10) -Vslope1  VOUT + 2  L  COUT t SW -t on In skip mode, the downward slope of the VFB ripple is almost the same with or without the external ramp. Figure 9 shows the simplified circuit of the skip mode when both HS-FET and LS-FET are off. Ceramic R2 Figure 8: Simplified Circuit in PWM Mode with External Ramp Compensation Figure 7 shows a simplified equivalent circuit in PWM mode with the HS-FET OFF and an external ramp compensation circuit (R4, C4). The external ramp is derived from the inductor ripple current. If one chooses C4, R9, R1 and R2 to meet the following condition: 1 2  fSW  C4   1  R1  R2   R9  5  R1  R2  (5) Vo FB (6) R1 Cout Ro R2 Figure 9: Simplified Circuit in Skip Mode The downward slope of the VFB ripple in skip mode can be determined as: Where: IR4  IC4  IFB  IC4 (9) Where IO is the load current. R1 IFB FB (8) The downward slope of the VFB ripple then follows Where tSW is the switching period. L ( VIN  VO )   ON R 4  C4 VSLOPE2   VREF (R1  R2  // Ro)  COUT NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. (11) 11 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS Where RO is the equivalent load resistor. As described in Figure 6, VSLOPE2 in skip mode is smaller than VSLOPE1 in PWM mode, so the jitter in the skip mode is larger. For less jitter during ultra-light–load conditions, select smaller VFB resistors, though at the cost of light-load efficiency. VID Input Typically, R1 and R2 set the output voltage with VFB=0.6V. R2, in this case, is a combination of R2A, R2B, and R2C depends on the VID, which is active low. The NB650/NB650H can dynamically track VID codes as they change. As a result, the converter output voltage can change without the need to reset either the controller or the value of R1 and R2A. As shown in Figure 1, R2B and R2C are parallel with R2A. The equivalent value of R2 can change due to different VID codes. One can get four VOUT values depending on the VID codes with the details in the application information. The VID logic and equivalent R2s are shown in Table 1. Table 1: VID Logic VID2 VID1 R2 1 1 R2  R2A 1 0 R2  R2A //R2B 0 1 R2  R2A //R2C 0 0 R2  R2A //R2B //R2C Enable Control The NB650/NB650H has a dedicated Enable control pin (EN). Pulling this pin high or low enables or disables the IC. Tie EN to VIN through a resistor for automatic start-up. Soft Start/Stop The NB650/NB650H employs a soft-start/stop (SS) mechanism to ensure smooth output during power-up and power shutdown. When the EN pin goes high, an internal current source (10μA) charges up the SS capacitor. The SS capacitor voltage then acts as the VREF voltage to the PWM comparator. The output voltage smoothly ramps up with the SS voltage. Once the SS voltage reaches the same level as the REF voltage, it continues ramping up while the REF voltage becomes the reference to the PWM comparator. At this point, the soft-start finishes and it enters steady-state operation. When the EN pin goes low, a 10µA internal current source discharges the SS capacitor. Once the SS voltage reaches the REF voltage, acts as the reference to the PWM comparator. The output voltage decreases smoothly with the SS voltage until it reaches zero level. Determine the SS capacitor as follows: CSS (nF )  t SS (ms)  ISS (A ) VREF ( V ) (12) If the output capacitors have large capacitance values, avoid setting a short SS time. Use a minimum value of 4.7nF if the output capacitance value exceeds 330µF. Power Good The NB650/NB650H has power-good (PG) output. The PG pin is the open drain of a MOSFET. Connect to VCC or another voltage source through a resistor (e.g. 100kΩ). The MOSFET turns ON after the application of the input voltage so that the PG pin is pulled to GND before the SS is ready. After the FB voltage reaches 90% of the reference voltage, the PG pin is pulled high after a delay. The PG delay is determined as follows: t PG (ms )  4  t SS (ms ) 9 (13) When the FB voltage drops to 90% of the reference voltage, the PG pin is pulled low. Over-Current Protection and Short-Circuit Protection The NB650/NB650H has cycle-by-cycle overcurrent limit control. The inductor current is monitored during the ON state. Once the inductor current hits the current limit, the HS-FET turns off. At the same time, the over-current protection (OCP) timer starts. The OCP timer is set as 50μs. If the current limit is hit for every cycle within that 50μs period, then OCP will trigger. When the output is shorted to ground, the device hits its current limit and the FB voltage is less than 0.4V. The device treats this as a dead-short NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 12 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS on the output and triggers OCP immediately. This is short circuit protection (SCP). Under OCP/SCP condition, NB650 will latch off. The converter needs power cycle to restart. NB650H will try to recover from OCP/SCP fault with hiccup mode. That means in OCP/SCP protection, the NB650H will disable the output power stage, discharge soft-start capacitor and then automatically try to start again. If the overcurrent condition still holds after soft-start ends, the NB650H repeats this operation cycle till overcurrent fault is removed and output rises back to regulation level. Over/Under-Voltage Protection The NB650/NB650H monitors the output voltage through the FB voltage to detect overvoltage and under voltage on the output. When the FB voltage exceeds 0.8V, the over-voltage protection (OVP) triggers. Once OVP triggers, the LS-FET is always on while the HS-FET is always off. The device needs to power cycle to power up again. Under-voltage protection (UVP) triggers when the FB voltage is below 0.4V. Usually, UVP accompanies hitting the current limit, which results in SCP. UVLO Protection The NB650/NB650H has under-voltage lockout (UVLO) protection. When VIN exceeds the UVLOrising threshold voltage, the NB650/NB650H powers up. It shuts off when VIN falls below the UVLO-falling threshold voltage. This is non-latch protection. Thermal Shutdown The NB650/NB650H employs thermal shutdown by internally monitoring the temperature of the junction. 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 to around 125°C, it initiates a soft-start. NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 13 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS APPLICATION INFORMATION Setting the Output Voltage-Large ESR Caps A resistor divider from the output voltage to the FB pin sets the output voltage. Changing the VID codes for the NB650/NB650H accomplishes the same thing. When there is no external ramp, the output voltages are set by feedback resistors R1 and R2A, R2B and R2C. First, choose R1 within 5kΩto-100kΩ to ensure stable operation. VOUT1, VOUT2, VOUT3 and VOUT4 are the voltages at different VID codes, arranged from low to high. Then determine R2A, R2B and R2C as follows: R2C  R2B  1 1  )  (VOUT1  VFB(AVG) ) R1 R4  R9 VOUT2  VFB(AVG) VFB(AVG) R2C  (20) 1 VOUT3  VFB(AVG) 1 1 1 (  ) VFB(AVG) R1 R4  R9 R2A 1 VOUT2  VOUT2  VREF 1 1   VREF R1 R2A (15) 1 VOUT3  21 VOUT3  VREF 1 1   VREF R1 R2A (16) The VFB(AVG) is the average value on FB. VFB(AVG) varies with the VIN, VO, and load condition; its value in skip mode is lower than in PWM mode, which means the load regulation is strictly related to the VFB(AVG). Also the line regulation is related to the VFB(AVG); use a lower VRAMP that meets the conditions of equation 10 for better load or line regulation. 1 2 For PWM operation, estimate VFB(AVG) from the following equation: VREF  (R1  R2A // R2B // R2C) 1  2 VOUT4 (17) R2A // R2B // R2C Where VOUTx is the output ripple determined by equation 30. Setting the Output Voltage-Small ESR Caps SW L VFB(AVG)  VREF  R4 Vo C4 R9 1 R1//R2 VRAMP 2 R1//R2  R9 (21) Usually, R9 is set to 0Ω, and it can also be set following equation 22 for better noise immunity. Set the value to 10×C4 for better DC blocking, but select a value less than 0.47µF when considering start up performance. For larger CDC values for better FB noise immunity, combine with reduced R1 and R2 to limit the CDC to a reasonable value without affecting system start-up. Note that even with CDC, the load and line regulation are still related to VRAMP. SW FB L R4 current of the converter. The input ripple current can be estimated as: VOUT V ICIN  IOUT   (1  OUT ) (26) VIN VIN The worst-case condition occurs at: 1 (VOUT2  VREF  VRAMP ) 1 2  1 R2A VREF  VRAMP 2 1 1  R1 (23) C4 R1 Ceramic R2 Figure 11: Simplified Circuit with Ceramic DCBlocking Capacitor (27) For simplification, choose an input capacitor whose RMS current rating is greater than half of the maximum load current. The input capacitance value determines the input voltage ripple of the converter. If the system requires a specific input voltage ripple, choose the input capacitor that meets the specification. The input voltage ripple can be estimated as: VIN  IOUT V V  OUT  (1  OUT ) fSW  CIN VIN VIN (28) The worst-case condition occurs at VIN = 2VOUT, where: VIN  Vo Cdc IOUT 2 I 1  OUT 4 fSW  CIN (29) Output Capacitor The output capacitor maintains the DC output voltage. Use ceramic or POSCAP capacitors. The output voltage ripple can be estimated as: VOUT  VOUT V 1  (1  OUT )  (RESR  ) (30) fSW  L VIN 8  fSW  COUT 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. Use ceramic capacitors for best performance. The capacitance varies significantly over temperature. Capacitors with X5R and X7R ceramic dielectrics are recommended because they are fairly stable over temperature. Where RESR is the equivalent series resistance (ESR) of the output capacitor. In the layout, place the input capacitors as close to the IN pin as possible. The output voltage ripple caused by ESR is very small, and therefore requires an external ramp to stabilize the system. The external ramp can be generated through resistor R4 and capacitor C4 following equations 5, 9 and 10. voltage generated from the ESR is high enough to stabilize the system. Therefore, an external ramp is not needed. A minimum ESR value of The capacitors must also have a ripple current rating greater than the maximum input ripple For POSCAP capacitors, the ESR dominates the impedance at the switching frequency. The ramp For ceramic capacitors, the capacitance dominates the impedance at the switching frequency, and causes the majority of the output voltage ripple. For simplification, the output voltage ripple can be estimated as: VOUT  VOUT V  (1  OUT ) VIN 8  fSW  L  COUT 2 NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. (31) 15 NB650/NB650H – 6A, 28V, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER 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 (32) Inductor The inductor supplies constant current to the output load while being driven by the switching input voltage. A larger value inductor results in less ripple current, which results in lower output ripple voltage. However, a larger value inductor is physically larger, has a higher series resistance, and/or lower saturation current. To determine the inductor value, allow the inductor peak-to-peak ripple current to reach approximately 30% to 40% of the maximum switch current limit. Make sure that the peak inductor current is below the maximum switch current limit. The inductance value can be calculated as: VOUT V L  (1  OUT ) (33) fSW  IL VIN Where ΔIL is the peak-to-peak inductor ripple cur rent. Choose an inductor that will not saturate under the maximum inductor peak current. The peak inductor current can be calculated as: VOUT V ILP  IOUT   (1  OUT ) (34) 2fSW  L VIN NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 16 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS TYPICAL APPLICATION Figure 12: Typical Application Circuit with No External Ramp VIN = 12V, VOUT = 1.05/1.15/1.20V, IOUT = 6A, fSW = 550kHz Figure 13: Typical Application with Low-ESR Ceramic Capacitor VIN = 12V, VOUT = 1.05/1.10/1.15/1.20V, IOUT = 6A, fSW = 550kHz NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 17 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS Figure 14: Typical Application Circuit with Low-ESR Ceramic Capacitor and DC-Blocking Capacitor VIN =12V, VOUT = 1.05/1.10/1.15/1.20V, IOUT = 6A, fSW = 550kHz Figure 15: Typical Application Circuit VIN = 19V, VOUT = 0.65/0.75/0.80/0.90V, IOUT = 6A NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 18 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS LAYOUT RECOMMENDATIONS SW 1. Place the high current paths (GND, IN, and SW) as close to the device as possible with direct, short, and wide traces. 2. Use a 0.1μF input decoupling capacitor to connect the IN and GND pins. Put the input decoupling capacitor and input capacitors as close to the IN and GND pins as possible. 3. Put the VCC 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. Place the external feedback resistors next to the FB pin. Make sure that there is no via on the FB trace. 6. Keep the BST voltage path (BST, CBST, and SW) as short as possible. 7. Connect the bottom IN and SW pads to large copper areas to achieve better thermal performance. 8. Use a four-layer layout to achieve better thermal performance. Inner1 Layer SW GND R3 C4 R3 R1 R3 R4 GND SW L1 SS RFB1 17 16 15 SW 1 SW SW 2 SW RFB2 FB 14 13 AGND 12 IN 11 IN PGND 10 PGND PGND 9 PGND Inner2 Layer C1 FREQ R3 R2A R3 R2C R3 R7 R3 R2B GND SW R3 C5 R3 C3 5 6 7 8 EN VID1 VID2 VCC C6 R3 R5 4 PG R3 3 BST GND VOUT VIN SW1 C2 GND Top Layer R3 R11 R3 R10 R3 R6 VOUT Bottom Layer Figure 16: PCB Layout Guide NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 19 NB650/NB650H – 6A, 28V, FAST-TRANSIENT, SYNCHRONOUS STEP-DOWN CONVERTERS PACKAGE OUTLINE DRAWING FOR 17L FCQFN (3X4MM) PACKAGE INFORMATION MF-PO-D-0091 revision 1.0 QFN17 (3 x 4mm) 1.00 BSC 0.35 0.45 2.90 3.10 0.50 0.70 17 12 PIN 1 ID MARKING 0.20 0.30 11 1 3.90 4.10 PIN 1 ID INDEX AREA 0.80 BSC 0.80 BSC 2 9 0.35 0.45 8 TOP VIEW 0.20 0.30 3 0.50 BSC BOTTOM VIEW 0.80 1.00 0.20 REF 0.00 0.05 SIDE VIEW 2.90 1.00 NOTE: 0.80 0.80 3.90 0.25 1) ALL DIMENSIONS ARE IN MILLIMETERS. 2) EXPOSED PADDLE SIZE DOES NOT INCLUDE MOLD FLASH. 3) LEAD COPLANARITY SHALL BE 0.10 MILLIMETER MAX. 4) JEDEC REFERENCE IS MO-220. 5) DRAWING IS NOT TO SCALE. 0.70 0.70 0.25 0.60 0.50 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. NB650/NB650H Rev. 1.13 www.MonolithicPower.com 10/7/2019 MPS Proprietary Information. Patent Protected. Unauthorized Photocopy and Duplication Prohibited. Preliminary Specifications Subject to Change © 2019 MPS. All Rights Reserved. 20