FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Features Single-Supply Operation with 4 A Output Current Wide Input Range with Dual Supply: 3.0 V to 24 V Wide Output Voltage Range: 0.8 V to 80% VIN Over 94% Peak Efficiency 1% Reference Accuracy Over Temperature Fully Synchronous Operation with Integrated Schottky Diode on Low-Side MOSFET Boosts Efficiency Single Supply Device for VIN > 6.5 V – 24 V Synchronizable to External Clock with Master/Slave Provisions Power-Good Signal 5x6mm, 25-Pin, 3-Pad MLP Package Programmable Frequency Operation (200600 KHz) Accepts Ceramic Capacitors on Output External Compensation for Flexible Design Starts on Pre-Bias Outputs Integrated Bootstrap Diode Programmable Over-Current Protection Under-Voltage, Over-Voltage, and ThermalShutdown Protections Applications Servers & Telecom Graphics Cards & Displays Computing Systems Set-Top Boxes & Game Consoles Point-of-Load Regulation Description The FAN21SV04 TinyBuck™ is a highly efficient, small-footprint, programmable-frequency, 4 A, integrated synchronous buck regulator. FAN21SV04 contains both synchronous MOSFETs and a controller/driver with optimized interconnects in one package, which enables designers to solve highcurrent requirements in a small area with minimal external components, thereby reducing cost. Onboard internal 5 V regulator enables single-supply operation for input voltages >6.5 V. The FAN21SV04 can be configured to drive multiple slave devices OR synchronize to an external system clock. In slave mode, FAN21SV04 may be set up to be free-running in the absence of a master clock signal. External compensation, programmable switching frequency, and current-limit features allow for design optimization and flexibility. High-frequency operation allows for all-ceramic solutions. Fairchild’s advanced BiCMOS power process, combined with low-RDS(ON) internal MOSFETs and a thermally efficient MLP package, provide the ability to dissipate high power in a small package. Integration helps minimize critical inductances, making layout simpler and more efficient compared to discrete solutions. Output over-voltage, under-voltage, over-current, and thermal-shutdown protections help protect the device from damage during fault conditions. FAN21SV04 prevents pre-biased output discharge during startup in point-of-load applications. Related Resources TinyCalc™ Calculator Design Tool AN-8022 — TinyCalc™ Calculator User Guide Ordering Information Operating Temperature Range Package Packing Method FAN21SV04MPX -10°C to 85°C Molded Leadless Package (MLP) 5x6 mm Tape and Reel FAN21SV04EMPX -40°C to 85°C Molded Leadless Package (MLP) 5x6 mm Tape and Reel Part Number © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator November 2012 IN VIN CHF CIN Boot Diode 5V_Reg BOOT C4 Reg Q1 R5 CBOOT VIN_Reg PWM + DRIVER RRAMP Enable L Q2 RAMP Power Good OUT SW C5 COUT PGND POWER MOSFETS EN RILIM CLK ILIM RT R1 FB RT R3 AGND COMP C3 C1 RBIAS C2 R2 Figure 1. Typical Application as Master at VIN=6.5 V to 24 V Block Diagram VIN_Reg Reg 5V BOOT 5V_Reg IILIM Boot Diode Current Limit Comparator VIN ILIM Int ref COMP Error Amplifier FB CBOOT R PWM Comparator Q S Gate Drive Circuit FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Typical Application Diagram VOUT SW L SS VREF COUT CLK OSC EN RAMP GEN Summing Amplifier Current Sense AGND PGND RAMP Figure 2. Block Diagram © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 2 Figure 3. MLP 5x6 mm Pin Configuration (Bottom View) Pad / Pin Definitions Pad / Pin Name Description P1, 6-12 SW Switching Node. Junction of high-side and low-side MOSFETs. P2, 3-5 VIN Power Conversion Input Voltage. Connect to the main input power source. P3, 21-23 PGND Power Ground. Power return and Q2 source. 1 BOOT High-Side Drive BOOT Voltage. Connect through capacitor (CBOOT) to SW. The IC has an internal synchronous bootstrap diode to recharge the capacitor on this pin to 5 V_Reg when SW is LOW. 2 VIN_Reg Regulator Input Voltage. Input voltage to the internal regulator. Connect to input voltage >6.5 V with 10 Ω resistor and a 1 µF bypass capacitor at the pin (see Figure 10). 13 PGOOD Power-Good. An open-drain output that pulls LOW when the voltage on the FB pin is outside the specified limits. PGOOD does not assert HIGH until the fault latch is enabled (see Figure 31). 14 EN 15 5V_Reg 5V Regulator Output. Internal regulator output that provides power for the IC’s logic and analog circuitry. This pin should be connected to AGND through a >2.2 µf X5R/X7R capacitor. 16 AGND Analog Ground. The signal ground for the IC. All internal control voltages are referred to this pin. Tie this pin to the ground island/plane through the lowest impedance connection. 17 ILIM Current Limit. A resistor (RILIM) from this pin to AGND can be used to program the currentlimit trip threshold lower than the internal default setting. 18 RT Switching Frequency and Master/Slave Set. Connecting a resistor (RT) to AGND sets the switching frequency and configures the CLK pin as an output (master). Tying this pin to 5 V_Reg through a resistor configures the CLK signal as an input (slave) and establishes the free-running switching frequency. 19 FB Output Voltage Feedback. Connect through a resistor divider to the output voltage. 20 COMP Compensation. Error amplifier output. Connect the external compensation network between this pin and FB. 24 CLK Clock. Bi-directional signal pin, depending on master/slave configuration. When configured as a master, this pin represents the clock output that connects directly to the slave(s) for synchronizing with 180° phase shift. 25 RAMP Ramp Amplitude. A resistor (RRAMP) connected from this pin to VIN sets the internal ramp amplitude and also provides voltage feedforward functionality. ENABLE. Enables operation when pulled to logic HIGH or left open. Toggling EN resets the regulator after a latched-fault condition. This input has an internal pull-up. When a latched fault occurs, EN is discharged by a current sink. © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Pin Configuration www.fairchildsemi.com 3 Stresses exceeding the absolute maximum ratings may damage the device. The device may not function or be operable above the recommended operating conditions and stressing the parts to these levels is not recommended. In addition, extended exposure to stresses above the recommended operating conditions may affect device reliability. The absolute maximum ratings are stress ratings only. Parameter Conditions Min. Max. Units 28 V 6 V 35 V -0.5 6.0 V -0.5 24.0 -5 30 -0.3 6.0 VIN, VIN_Reg to AGND AGND=PGND 5V_Reg to AGND AGND=PGND BOOT to PGND BOOT to SW SW to PGND Continuous Transient (t < 20 ns, f < 600 KHz) All other pins ESD Human Body Model, JESD22-A114 Charged Device Model, JESD22-C101 Electrostatic Discharge Protection Level V V 1.5 kV 2.5 Recommended Operating Conditions The Recommended Operating Conditions table defines the conditions for actual device operation. Recommended operating conditions are specified to ensure optimal performance to the datasheet specifications. Fairchild does not recommend exceeding them or designing to Absolute Maximum Ratings. Symbol fSW VIN, VIN_Reg Parameter Conditions Switching Frequency Supply Voltage for Power and Bias TA Ambient Temperature TJ Junction Temperature Min. Typ. 200 500 Max Units 600 KHz VIN to PGND 3.0 24.0 VIN_Reg to AGND 6.5 24.0 FAN21SV04MPX -10 +85 FAN21SV04EMPX -40 +85 V °C +125 °C Max. Units +150 °C +300 °C Thermal Information Symbol TSTG TL θJC Parameter Min. Storage Temperature Typ. -65 Lead Soldering Temperature, 30 Seconds Thermal Resistance: Junction-to-Case P1 (Q2) 4 P2 (Q1) 7 P3 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Absolute Maximum Ratings °C/W 4 (1) θJ-PCB Thermal Resistance: Junction-to-Mounting Surface PD Total Power Dissipation in the package, TA=25°C(1) 35 °C/W 2.8 W Note: 1. Typical thermal resistance when mounted on a four-layer, two-ounce PCB, as shown in Figure 38. Actual results are dependent upon mounting method and surface related to the design. © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 4 Recommended operating conditions and using the circuit shown in Figure 1, with VIN, VIN_Reg=12 V, unless otherwise noted. Parameter Conditions Min. Typ. Max. Units 30 mA Power Supplies Operating Current (VIN+VIN_Reg) VIN=12 V, 5V_Reg Open, CLK Open, fSW =500 KHz, No Load 22 VIN_Reg Operating Current EN=High, 5 V_Reg Open, CLK Open, fSW =500 KHz 11 VIN_Reg Quiescent Current EN=High, FB=0.9 V 4 VIN_Reg Standby Current EN=0, VIN=12 V 5V_Reg Output Voltage Internal VCC Regulator, No Load, 6.5 V<VIN_Reg<24 V 5V_Reg Max. Current Load VIN_Reg=12 V VIN_Reg UVLO Threshold Rising VIN, VIN=VIN_Reg Falling VIN, VIN=VIN_Reg Reference Reference Voltage measured at FB (See Figure 4 for Temperature Coefficient) Oscillator Frequency Frequency in Slave Mode Compared to Master Mode Minimum On Time Duty Cycle 4.7 Gain Bandwidth Product Output Voltage Swing (VCOMP) Output Current, Sourcing Output Current, Sinking FB Bias Current 5.3 V 5 mA 5.6 6.3 5 V V 806 FAN21SV04EMPX, TA=25°C 795 800 805 RT=50 kΩ to GND (Master Mode) 255 300 345 RT=24 kΩ to GND (Master Mode) 540 600 660 RT=24 kΩ to 50 kΩ to 5 V_Reg (Slave Mode) -15 40 80 Master (RT to GND) Master, VCLK=0.4 V Master, VCLK=2 V Slave: VCLK > 2 V Slave: VCLK=1 V Slave 70 0.25 -2.5 50 -230 1.73 5V_Reg=5 V, VCOMP=2.2 V 5V_Reg=5 V, VCOMP=1.2 V VFB=0.8 V, TA=25°C KHz % 65 85 ns % V 100 150 ns 85 100 0.35 -2.0 -200 1.83 -170 1.93 ns mA mA ns µA V 2.5 ms 3.1 ms 80 85 dB 12 15 Frequency=500 KHz VIN_Reg > 6.5 V mV +15 0.5 (2) (2) 5.0 800 VIN=6.5 V, fSW =600 KHz Fault Enable/SSOK (T1.0) Error Amplifier DC Gain (2) mA mA 794 VIN=16 V, 1.8 VOUT, RT=30 kΩ, RRAMP=200 kΩ Minimum Off Time Synchronization CLK Output Pulse Width CLK Output Sink Current CLK Output Source Current CLK Input Pulse Width CLK Input Source Current CLK Input Threshold, Rising Soft-Start VOUT to Regulation (T0.8) 5 1 FAN21SV04MPX, TA=25°C (2) Ramp Amplitude, Peak–to-Peak(2) mA 0.4 1.5 0.8 -850 2.2 1.2 -650 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Electrical Characteristics MHz 4.0 2.5 1.5 -450 V mA mA nA Note: 2. Specifications guaranteed by design and characterization; not production tested. © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 5 Recommended operating conditions using the circuit shown in Figure 1 with VIN, VIN_Reg=12 V, unless otherwise noted. Parameter Conditions Min. Typ. Max. Units EN Threshold, Rising 1.35 2.00 EN Hysteresis 250 mV 800 KΩ 1 µA Control Functions EN Pull-Up Resistance VIN_Reg >6.5 V EN Discharge Current Auto-Restart Mode, VIN_Reg>6.5 V FB OK Drive Resistance PGOOD Low Threshold 800 1000 (3) -14.0 -11.0 -8.0 FB > VREF, 2 Consecutive Clock Cycles(3) +7.0 +10.0 +13.5 FB < VREF, 2 Consecutive Clock Cycles PGOOD Low Voltage IOUT < 2 mA PGOOD Leakage Current VPGOOD=5 V V KΩ %VREF 0.4 V 0.2 1.0 µA Protection and Shutdown Current Limit RILIM open, fSW =500 KHz, VOUT=1.8 V, RRAMP=200 kΩ, 16 Consecutive Clock Cycles(3) 5.5 6.5 7.5 A ILIM Current VIN_Reg > 6.5 V, TA=25°C -11 -10 -9 µA Over-Temperature Shutdown Over-Temperature Hysteresis +155 Internal Temperature °C +30 °C Over-Voltage Threshold 2 Consecutive Clock Cycles(3) 110 115 120 %VOUT Under-Voltage Shutdown 16 Consecutive Clock Cycles(3) 68 73 78 %VOUT Fault-Discharge Threshold Measured at FB pin 250 mV Fault-Discharge Hysteresis Measured at FB pin (VFB ~500 mV) 250 mV Note: 3. Delay times are not tested in production. Guaranteed by design. © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Electrical Characteristics (Continued) www.fairchildsemi.com 6 1.010 1.20 1.005 1.10 I FB V FB VIN=12V, VCC=5V, TA=25°C, unless otherwise specified. 1.000 0.995 1.00 0.90 0.990 0.80 -50 0 50 100 150 -50 0 Temperature (oC) 50 100 150 Temperature (oC) Figure 4. Reference Voltage (VFB) vs. Temperature, Figure 5. Reference Bias Current (IFB) vs. Temperature, Normalized Normalized 1.02 1200 1.01 Frequency Frequency (KHz) 1500 900 600 600KHz 1.00 300KHz 0.99 300 0.98 0 0 20 40 60 80 100 120 -50 140 0 RT (KΩ) 100 150 o Temperature ( C) Figure 6. Frequency vs. RT (Master) Figure 7. Frequency vs. Temperature, Normalized 1.04 1.60 1.40 1.02 1.20 I ILIM RDS 50 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Typical Characteristics 1.00 1.00 Q1 ~0.32 %/oC 0.80 0.98 Q2 ~0.35 %/oC 0.96 0.60 -50 0 50 100 150 -50 50 100 150 Temperature ( C) Temperature ( C) Figure 8. RDS vs. Temperature, Normalized (5 V_Reg=VGS=5 V) © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 0 o o Figure 9. ILIM Current (IILIM) vs. Temperature, Normalized www.fairchildsemi.com 7 FAN21SV04 Figure 10. Single-Supply Application Circuit: 1.8 VOUT, 500 KHz, Master, 8 V – 20 V Input FAN21SV04 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Application Circuit Figure 11. Single -Supply Application Circuit: 1.2 VOUT, 500 KHz, Master 8 V – 20 V Input © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 8 Typical operating characteristics using the Figure 10 circuit; VIN=12 V, VCC=5 V, TA=25°C, unless otherwise specified. 95 3.3V Eff 8-20V 500kHz 95 1.8V_Eff 8-20V_500kHz 90 Efficiency(%) Efficiency(%) 90 85 80 8V 85 8Vin 12Vin 80 16Vin 12V 75 20Vin 75 16V 20V 70 70 0 0.5 Figure 12. 1 1.5 2 Load(A) 2.5 3 3.5 0 4 0.5 1 1.5 2 2.5 3 3.5 4 Load(A) Figure 13. 3.3 VOUT Efficiency, 500 KHz(4) 1.8 VOUT Efficiency Over VIN vs. Load 95 1.8V_Eff 8-20V_300kHz 3.3V_Eff 8-20V_300kHz 95 90 85 Efficiency(%) Efficiency(%) 90 8V 80 12V 85 8V 80 12V 16V 75 16V 75 20V 20V 70 70 0 0.5 1 1.5 2 Load(A) 2.5 3 3.5 0 4 0.5 1 1.5 2 2.5 3 3.5 4 Load(A) Figure 14. 1.8 VOUT Efficiency, 300 KHz(4) Figure 15. 3.3 VOUT Efficiency, 300 KHz(4) 95 1.2V_Eff 8-20V_500kHz 95 90 5V_Eff 8-20V_300kHz Efficiency(%) Efficiency (%) 90 85 80 85 8Vin 80 12Vin 8V 75 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Typical Performance Characteristics 16Vin 12V 75 20Vin 16V 20V 70 70 0 0.5 1 1.5 2 Load (A) 2.5 3 3.5 4 0 0.5 1 1.5 2 Load(A) 2.5 3 3.5 4 Figure 17. 5 VOUT Efficiency, 300 KHz(4) Figure 16. 1.2 VOUT Efficiency, 500 KHz (Figure 11) Note: 4. Circuit values for this configuration change in Figure 10. © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 9 Typical operating characteristics using the Figure 10 circuit; VIN=12 V, VCC=5 V, TA=25°C, unless otherwise specified. 0.10 0.15 Line Regulation Load Regulation 0.08 0.05 0.1 % Change in output voltage as compared at 0 Amps % Change in output voltage as compared to set value at 6.5V No load 0.5A Load 0.03 0.00 -0.03 -0.05 12V 0.05 16V 0 -0.05 -0.1 -0.08 -0.15 -0.10 0 5 Figure 18. 10 15 Input Voltage (V) 20 0 25 1 1.5 2 2.5 3 3.5 4 Load(A) 1.8 VOUT Line Regulation Figure 19. 1.8 VOUT Load Regulation 70 70 Peak Case Tempr over Mosfet Location @Room Tempr - 3.3V Output, 500kHz 60 60 50 Temperature (Deg C) Temperature (Deg C) 0.5 40 30 12V_HS 12V_LS 20 Peak Case Tempr over Mosfet Location @Room Tempr - 5V Output, 300kHz 50 40 30 20 12V_HS 10 12V_LS 24V_HS 24V_LS 10 0 0 0 0.5 1 1.5 2 2.5 3 3.5 4 0 0.5 1 1.5 2 Load(A) Load(A) Figure 20. Peak MOSFET Temperatures 3.3 V Output, 12 V and 24 V Input (500KHz)(5) 2.5 3 3.5 4 Figure 21. Peak Case Temperature Over MOSFET Locations 5 V Output (300 KHz) 95 Recommended FAN21SV04 Safe Operating Area curves for 70 Deg Temperature rise VIN = 20V, Natural Convection. 1.8V_Eff 12V Input 6 90 Load Current (Amps) 5 Efficiency(%) 85 300kHz 400kHz 80 500kHz 600kHz 75 4 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Typical Performance Characteristics (Continued) 3 2 300KHz 500KHz 1 600Khz 0 70 0 0.5 1 1.5 2 Load(A) 2.5 3 3.5 0 4 2 4 6 8 10 12 14 Output Voltage (Volts) Figure 23. Typical Output Operating Area Based on Thermal Limitations Figure 22. 1.8 VOUT Efficiency Over fSW Note: 5. Circuit values for this configuration change in Figure 10. © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 10 Typical operating characteristics using the Figure 10 circuit. VIN=12 V unless otherwise specified. VOUT, 1V/div VOUT, 100mv/div EN, 1V/div CLK, 5V/div IOUT, 2A/div PGOOD, 5V/div Figure 24. CLK and VOUT at Startup Figure 25. Transient Response, 2-4 A Load VOUT, 1V/div EN, 2V/div SW, 10V/div SW, 10V/div Figure 26. Startup on Pre-Bias Figure 27. Restart on Fault CLK, 5V/div VOUT, 1V/div SW, 5V/div CLK, 5V/div FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Typical Performance Characteristics (Continued) EN, 5V/div PGOOD, 5V/div Figure 29. Figure 28. Shutdown, 1 A Load © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 Slave (500 KHz Free-Run to 600 KHz Synchronization) www.fairchildsemi.com 11 PWM Generation Internal Regulator Refer to Figure 2 for the PWM control mechanism. FAN21SV04 uses the summing-mode method of control to generate the PWM pulses. An amplified currentsense signal is summed with an internally generated ramp and the combined signal is compared with the output of the error amplifier to generate the pulse width to drive the high-side MOSFET. Sensed current from the previous cycle is used to modulate the output of the summing block. The output of the summing block is also compared against a voltage threshold set by the RLIM resistor to limit the inductor current on a cycle-by-cycle basis. RRAMP resistor helps set the charging current for the internal ramp and provides input voltage feedforward function. The controller facilitates external compensation for enhanced flexibility. FAN21SV04 facilitates single-supply operation for input voltages >6.5 V. At startup, the output of the internal regulator tracks the input voltage and comes into regulation (5 V) when VIN_Reg exceeds the UVLO threshold. The EN pin is released at the same time. The output voltage of the internal regulator (5 V_Reg) is set to 5 V. The internal regulator supplies power to all the control circuits including the drivers. For applications with VIN<6.5 V, FAN21SV04 can be used if VIN_Reg is provided with a separate low-power source >6.5 V. VIN_Reg supply should come up after VIN during dual-supply operation. The VIN_Reg pin should always be decoupled with at least a 10 Ω resistor and a 1 µF ceramic capacitor (see Figure 10, Figure 11). Since 5 V_Reg is used to drive the internal MOSFET gates, high peak currents are present on the 5 V_Reg pin. Connect a >2.2 µf X5R or X7R decoupling capacitor between the 5 V_Reg pin and AGND. For VIN>20 V operation, use a 3.3 Ω resistor in series with the boot capacitor to reduce noise into the regulator. Initialization Once VIN_Reg voltage exceeds the UVLO threshold and EN is HIGH, the IC checks for a shorted FB pin before releasing the internal soft-start ramp (SS). If the parallel combination of R1 and RBIAS is ≤ 1 kΩ, the internal SS ramp is not released and the regulator does not start. In addition to supplying power for the control circuits internally, 5 V_Reg output can be used as a reference voltage for other applications requiring low noise reference voltage. 5 V_Reg is capable of sourcing up to 5 mA of output current. Enable FAN21SV04 has an internal pull-up to the enable (EN) pin so that the IC is enabled once VIN_Reg exceeds the UVLO threshold. Connecting a small capacitor across EN and AGND delays the rate of voltage rise on the EN pin. The EN pin also serves for the restart whenever a fault occurs (refer to the Auto-Restart section). If the regulator is enabled externally, the external EN signal should go HIGH only after 5 V_Reg is established. For applications where such sequencing is required, FAN21SV04 can be enabled (after the VCC comes up) with external control, as shown in Figure 30. When EN is pulled LOW externally, 5 V_Reg output is still present, but the IC is in standby mode with no switching. Soft-Start FAN21SV04 uses an internal digital soft-start circuit to slowly ramp up the output voltage and limit inrush current during startup. When 5 V_Reg is in regulation and EN is HIGH, the circuit releases SS and enables the PWM regulator. Soft-start time is a function of the switching frequency (number of clock cycles). If auto-restart is not desired, tie the EN pin HIGH with a logic gate to keep the 1 µA current sink from discharging EN to 1.1 V. Figure 32 shows one method to pull up EN to VCC for a latch configuration. Once internal SS ramp has charged to 0.8 V (T0.8), the output voltage is in regulation. Until SS ramp reaches 1.0 V (T1.0), only the over-current-protection circuit is active during soft-start and all other output protections are inhibited. FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Circuit Operation In dual-supply operation mode, it is necessary to apply VIN before VIN_Reg reaches its UVLO threshold to avoid skipping the soft-start cycle. VIN_Reg UVLO or toggling the EN pin discharges the SS and resets the IC. Figure 30. Enabling with External Control © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 12 Auto-Restart After a fault, the EN pin is discharged with 1 µA current pull-down to a 1.1 V threshold before the internal 800 kΩ pull-up is restored. A new soft-start cycle begins when EN charges above 1.35 V. Depending on the external circuit, the FAN21SV04 can be configured to remain latched off or automatically restart after a fault, as listed in Table 1. Table 1. Fault / Restart Configurations EN Pin Controller / Restart State Pull to GND Connected to 5V_Reg with 100KΩ Open OFF (Disabled) Cap to GND Figure 31. Typical Soft-Start Timing Diagram No Restart – Latched OFF Immediate Restart After Fault New Soft-Start Cycle After EN is HIGH (Auto Restart Mode) With EN left open, restart is immediate. If auto-restart is not desired, tie the EN pin HIGH with a logic gate to keep the 1 µA current sink from discharging EN to 1.1 V. Figure 32 shows one method to pull up EN to VCC for a latch configuration. Startup on Pre-Bias The regulator does not allow the low-side MOSFET to operate in full synchronous mode until SS reaches 95% of VREF (~0.76 V). This enables the regulator to startup on a pre-biased output and ensures that output is not discharged during the soft-start cycle. Protections The converter output is monitored and protected against extreme overload, short-circuit, over-voltage, and undervoltage conditions. Under-Voltage Protection If FB remains below the under-voltage threshold for 16 consecutive clock cycles, the fault latch is set and the converter shuts down. This protection is not active until the internal SS ramp reaches 1.0 V during soft-start. Figure 32. Enable Control with Latch Option Power Good (PGOOD) Signal FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Over-Temperature Protection The chip incorporates an over-temperature protection circuit that sets the fault latch when a die temperature of about 155°C is reached. The IC is allowed to restart when the die temperature falls below 125°C. PGOOD is an open-drain output that asserts LOW when VOUT is out of regulation, as measured at the FB pin. The thresholds are specified in the Electrical Specifications section. PGOOD does not assert HIGH until soft start is complete (T1.0) (see Figure 31). Over-Voltage Protection If FB exceeds 115% • VREF for two consecutive clock cycles, the fault latch is set and shutdown occurs. A shorted high-side MOSFET condition is detected when SW voltage exceeds ~0.7 V while the low-side MOSFET is fully enhanced. The fault latch is set immediately upon detection. The OV/UV fault conditions are not allowed to set the fault latch during soft-start. They are active only after T1.0 (see Figure 31). © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 13 transient response use a higher ripple-current setting while regulator designs that require higher efficiency keep ripple current on the low side and operate at a lower switching frequency. The inductor value is calculated by the following formula: 5 V_Reg Output The 5 V_Reg pin is the output of the internal regulator that supplies all power to the control circuit. It is important to keep this pin decoupled to AGND with a >2.2 µf X5R or X7R decoupling capacitor. In addition, for operation with VIN>20 V, add a 3.3 Ω resistor in series with the boot capacitor to reduce the switching noise into the regulator. L= The output voltage of the regulator can be set from 0.8 V to ~80% of VIN by an external resistor divider (R1 and RBIAS in Figure 1). For output voltages >3.3 V, output current rating may need to be de-rated depending on the ambient temperature, power dissipated in the package, and the PCB layout (refer to Thermal Information table on page 4, Figure 20, Figure 21, and Figure 23). Setting the Ramp Resistor Value RRAMP resistor plays a critical role by providing charging current to the internal ramp capacitor and also serving as a means to provide input voltage feedforward. RRAMP is calculated by the following formula: R RAMP(KΩ ) = The internal reference is set to 0.8 V with 650 nA sourced from the FB pin to ensure that the regulator does not start if the pin is left open. −2 (4) For wide input operation, first calculate RRAMP for the minimum and maximum input voltage conditions and use larger of the two values calculated. (1) In all applications, current through the RRAMP pin must be greater than 10 µA from the equation below for proper operation: Connect RBIAS between FB and AGND. If R1 is open (see Figure 1), the output voltage is not regulated and a latched fault occurs after the SS is complete (T1.0). VIN − 1.8 ≥ 10 μA RRAMP + 2 If the parallel combination of R1 and RBIAS is ≤ 1 KΩ, the internal SS ramp is not released and the regulator does not start. (5) If the calculated RRAMP values in Equation (4) result in a current less than 10 µA, use the RRAMP value that satisfies Equation (5). In applications with large Input ripple voltage, the RRAMP resistor should be adequately decoupled from the input voltage to minimize ripple on the ramp pin. Setting the Switching Frequency Switching frequency is determined by a resistor, RT, connected between the RT pin and AGND (Master Mode) or 5 V_Reg (Slave Mode): Setting the Current Limit The current limit system involves two comparators. The MAX ILIMIT comparator is used with a VILIM fixed-voltage reference and represents the maximum current limit allowable. This reference voltage is temperature compensated to reflect the RDSON variation of the lowside MOSFET. The ADJUST ILIMIT comparator is used where the current limit needs to be set lower than the VILIM fixed reference. The 10 µA current source does not track the RDSON changes over temperature, so change is added into the equations for calculating the ADJUST ILIMIT comparator reference voltage, as is shown below. Figure 33 shows a simplified schematic of the overcurrent system. where RT is expressed in kΩ: (106 / f ) − 135 65 ( VIN − 1.8 ) • VOUT (30.5 − 4.5 • IOUT ) • VIN • f • 10 − 6 where frequency (f) is expressed in KHz. The external resistor divider is calculated using: RT (KΩ ) = (3) where f is the switching frequency. Setting the Output Voltage V − 0 .8 V 0 .8 V = OUT + 650nA R BIAS R1 VOUT ) VIN ΔIL • f VOUT • (1 - (2) where frequency (f) is expressed in KHz. In Slave Mode, the switching frequency is about 10% slower for the same RT. The regulator does not start if RT is open in Master Mode. Calculating the Inductor Value FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Application Information Typically the inductor value is chosen based on ripple current (ΔIL), which is chosen between 10 to 35% of the maximum DC load. Regulator designs that require fast © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 14 VERR + _ complete Type-3 compensation network. compensation eliminates R3 and C3. PWM COMP Type-2 PWM VCC VILIM + _ MAX ILIMIT 10µA + _ ILIM ADJUST ILIMIT ILIMTRIP RILIM Figure 34. Compensation Network Figure 33. Current-Limit System Schematic Since the FAN21SV04 employs summing current-mode architecture, Type-2 compensation can be used for many applications. For applications that require wide loop bandwidth and/or use very low-ESR output capacitors, Type-3 compensation may be required. Since the ILIM voltage is set by a 10 µA current source into the RILIM resistor, the basic equation for setting the reference voltage is: VRILIM = 10µA*RILIM (6) RRAMP provides feedforward compensation for changes in VIN. With a fixed RRAMP value, the modulator gain increases as VIN is reduced, which can make it difficult to compensate the loop. For low-input-voltage-range designs (3 V to 8 V), RRAMP and the compensation component values are different as compared to designs with VIN between 8 V and 24 V. To calculate RILIM: RILIM = VRILIM/ 10µA (7) The voltage VRILIM is made up of two components, VBOT (which relates to the current through the low-side MOSFET) and VRMPEAK (which relates to the peak current through the inductor). Combining those two voltage terms results in: RILIM = (VBOT + VRMPEAK)/ 10µA RILIM = {0.96 + (ILOAD * RDSON *KT*8)} + {D*(VIN – 1.8)/(fSW *0.03*RRAMP)}/10µA Master / Slave Configuration (8) When first enabled, the IC determines if it is configured as a master or slave for synchronization, depending on how RT is connected. (9) Table 2. where: Master / Slave Configuration VBOT = 0.96 + (ILOAD * RDSON *KT*8); RT to: Master / Slave VRMPEAK = D*(VIN – 1.8)/(fSW *0.03*RRAMP); GND Master ILOAD = the desired maximum load current; 5V_Reg RDSON = the nominal RDSON of the low-side MOSFET; Output Input Slaves free-run in the absence of an external clock signal input when RT is connected to 5 V_Reg, allowing regulation to be maintained. It is not recommended to leave RT open when running in Slave Mode to avoid noise pick up on the clock pin. KT = the normalized temperature coefficient for the low-side MOSFET (on datasheet graph); D = VOUT/VIN duty cycle; Slave free-running frequency should be set at least 25% lower than the incoming synchronizing pulse frequency. Maximum synchronizing clock frequency is recommended to be below 600 KHz. fSW = Clock frequency in kHz; and RRAMP = chosen ramp resistor value in kΩ. After 16 consecutive, pulse-by-pulse, current-limit cycles, the fault latch is set and the regulator shuts down. Cycling VCC or EN restores operation after a normal soft-start cycle (refer to the Auto-Restart section). Synchronization The synchronization method employed by the FAN21SV04 also provides the following features for maximum flexibility. The over-current protection fault latch is active during the soft-start cycle. Use 1% resistor for RILIM. Loop Compensation The control loop is compensated using a feedback network around the error amplifier. Figure 34 shows a © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 Slave, free-running CLK Pin FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator RAMP Synchronization to an external system clock Multiple FAN21SV04s can be synchronized to a single master or system clock www.fairchildsemi.com 15 Independently programmable phase adjustment for one or multiple slaves Free-running capability in the absence of system clock or, if the master is disabled/faulted, the slaves can continue to regulate at a lower frequency PCB Layout Good PCB layout and careful attention to temperature rise is essential for reliable operation of the regulator. Four-layer PCB with two-ounce copper on the top and bottom side and thermal vias connecting the layers is recommended. Keep power traces wide and short to minimize losses and ringing. Do not connect AGND to PGND below the IC. Connect AGND pin to PGND at the output OR to the PGND plane. The FAN21SV04 master outputs an 85 ns-wide clock (CLK) signal, delayed 180o from its leading PWM edge. This feature allows out-of-phase operation for the slaves, thereby reducing the input capacitance requirements when more than one converter is operating on the same input supply. The leading SW-node edge is delayed ~40 ns from the rising PWM signal. On a slave, synchronization is rising-edge triggered. The CLK input pin has a 1.8 V threshold and a 200 µA current source pull-up. SW In Master Mode, the clock signals go out after powergood signal asserts HIGH. Likewise, in Slave Mode, synchronization to an external clock signal occurs after the power-good signal goes HIGH. Until then, the converter operates in free-run mode. VIN PGND PGND VOUT Figure 38. Recommended PCB Layout Figure 35. Synchronization Timing Diagram Figure 36. Slave-CLK-Input Block Diagram One or more slaves can be connected directly to a master or system clock to achieve a 180o phase shift. FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Figure 37. Slaves with 180o Phase Shift Since the synchronizing circuit utilizes a narrow reset pulse, the actual phase delay is slightly more than 180o. The FAN21SV04 is not intended for use in single-output, multi-phase regulator applications. © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 16 2X TOP VIEW 2X RECOMMENDED LAND PATTERN ALL VALUES TYPICAL EXCEPT WHERE NOTED SIDE VIEW SEATING PLANE OPTIONAL LEAD DESIGN (LEADS# 1, 24 & 25 ONLY) SCALE: 1.5X A) DIMENSIONS ARE IN MILLIMETERS. B) DIMENSIONS AND TOLERANCES PER ASME Y14.5M, 1994 C) DIMENSIONS DO NOT INCLUDE MOLD FLASH OR BURRS. D) DESIGN BASED ON JEDEC MO-220 VARIATION WJHC E) TERMINALS ARE SYMMETRICAL AROUND THE X & Y AXIS EXCEPT WHERE DEPOPULATED. F) DRAWING FILENAME: MKT-MLP25AREV3 BOTTOM VIEW FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator Physical Dimensions Figure 39. 5x6 mm Molded Leadless Package (MLP) Package drawings are provided as a service to customers considering Fairchild components. Drawings may change in any manner without notice. Please note the revision and/or date on the drawing and contact a Fairchild Semiconductor representative to verify or obtain the most recent revision. Package specifications do not expand the terms of Fairchild’s worldwide terms and conditions, specifically the warranty therein, which covers Fairchild products. Always visit Fairchild Semiconductor’s online packaging area for the most recent package drawings: http://www.fairchildsemi.com/packaging/. © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 17 FAN21SV04 — TinyBuck™ 4 A, 24 V Single-Input Integrated Synchronous Buck Regulator © 2009 Fairchild Semiconductor Corporation FAN21SV04 • Rev. 1.0.3 www.fairchildsemi.com 18