Digitally Programmable TinyBuck) Regulator, 3.0 A, 2.4 MHz FAN53526 Descriptions The FAN53526 is a step-down switching voltage regulator that delivers a digitally programmable output from an input voltage supply of 2.5 V to 5.5 V. The output voltage is programmed through an I2C interface capable of operating up to 3.4 MHz. Using a proprietary architecture with synchronous rectification, the FAN53526 is capable of delivering 3.0 A continuous at over 80% efficiency, maintaining that efficiency at load currents as low as 10 mA. The regulator operates at a nominal fixed frequency of 2.4 MHz, which reduces the value of the external components. Additional output capacitance can be added to improve regulation during load transients without affecting stability. At moderate and light loads, Pulse Frequency Modulation (PFM) is used to operate in Power-Save Mode with a typical quiescent current of 50 mA at room temperature. Even with such a low quiescent current, the part exhibits excellent transient response during large load swings. At higher loads, the system automatically switches to fixed-frequency control, operating at 2.4 MHz. In Shutdown Mode, the supply current drops below 1 mA, reducing power consumption. PFM Mode can be disabled if fixed frequency is desired. The FAN53526 is available in a 15-bump, 1.310 mm x 2.015 mm, 0.4 mm ball pitch WLCSP. Features * * * * * * * * * * * * Fixed-Frequency Operation: 2.4 MHz Best-in-Class Load Transient Continuous Output Current Capability: 3.0 A 2.5 V to 5.5 V Input Voltage Range Digitally Programmable Output Voltage: -0.600 V to 1.39375 V in 6.25 mV Steps Programmable Slew Rate for Voltage Transitions I2C-Compatible Interface Up to 3.4 Mbps PFM Mode for High Efficiency in Light-Load Quiescent Current in PFM Mode: 50 mA (Typical) Input Under-Voltage Lockout (UVLO) Thermal Shutdown and Overload Protection 15-Bump Wafer-Level Chip Scale Package (WLCSP) www.onsemi.com WLCSP-15 CASE 567QS MARKING DIAGRAM Pin-1 Mark 1, 2 KK . X Y Z 1 2 K K X Y Z = Two Alphanumeric Characters for Device Mark = Two Alphanumeric Characters for Lot Rune Code Mark = Pin 1 Indicator = Alphabetical Year Code = 2-weeks Date Code = Assembly Plant Code PIN CONFIGURATION VIN A1 SW A2 PGND A3 B1 B2 B3 C1 PGND C2 AGND C3 VSEL D1 EN D2 SDA D3 AGND E1 SCL E2 VOUT E3 Applications * Application, Graphic, and DSP Processors ORDERING INFORMATION ARMt, Tegrat, OMAPt, NovaThor, ARMADAt, Kraitt, etc. Hard Disk Drives, LPDDR3, LPDDR4 Tablets, Netbooks, Ultra-Mobile PCs Smart Phones Gaming Devices See detailed ordering and shipping information on page 2 of this data sheet. * * * * (c) Semiconductor Components Industries, LLC, 2006 October, 2019 - Rev. 6 1 Publication Order Number: FAN53526/D FAN53526 PVIN CIN_LOAD VOUT SDA SCL C BY C IN EN L1 SW FAN 53526 VSEL C OUT PGND LOAD AGND Figure 1. Typical Application Table 1. ORDERING INFORMATION Power-Up Defaults DVS Range / Step Size I2C Slave Address Temperature Range Packing Method Device Marking Part Number VSEL0 VSEL1 FAN53526UC84X 1.125 1.125 F7 FAN53526UC89X 1.15625 1.15625 CL FAN53526UC100X 1.225 1.225 F9 FAN53526UC106X 1.2625 1.2625 Package C7 C0 0.600 V to 1.39375 V / 6.25 mV FAN53526UC128X 1.20 1.20 FAN53526UC00X 0.60 0.60 FAN53526UC64X 1.00 1.00 GG FAN53526UC88X 1.15 1.15 LM FAN53526UC288X 1.15 1.15 FAN53526UC168X 1.125 1.125 -40 to 85_C WLCSP F3 Tape & Reel GA LN C2 FR RECOMMENDED EXTERNAL COMPONENTS Table 2. RECOMMENDED EXTERNAL COMPONENTS FOR 3.0 A MAXIMUM LOAD CURRENT Component Description L1 330 nH, 2016 Case Size Vendor Parameter Typ. L1 Alternative (Note 1) 470 nH 2016 Case Size COUT1, COUT2 47 mF, 6.3 V, X5R, 0603 GRM188R60J476ME15 (Murata) C 47 COUT1, COUT2 Alternative (Note 1) 22 mF, 10 V, X5R, 0603 CL10A226MP8NUNB (SAMSUNG) C 22 CIN 1 Piece; 4.7 mF, 10 V, X5R, 0603 C1608X5R1A475K (TDK) C 4.7 CBY 1 Piece; 100 nF, 6.3V, X5R, 0201 GRM033R60J104KE19D (Murata) C 100 Unit See Table 3 mF nF 1. COUT Alternative and L1 Alternative can be used if not following reference design. CBY is recommended to reduce any high frequency component on VIN bus. CBY is optional and used to filter any high frequency component on VIN bus. www.onsemi.com 2 FAN53526 Table 3. RECOMMENDED INDUCTORS Manufacturer Part # L (nH) DCR (mW Typ.) ISAT (Note 2) L W H Toko DFE201612E-R33N 330 15 7.0 2.0 1.6 1.2 Toko DFE201612E-R47N 470 21 6.1 2.0 1.6 1.2 Cyntek PIFE20161B-R47MS-39 470 30 3.1 2.0 1.6 1.2 SEMCO CIGT201610UMR47MNE 470 30 4.0 2.0 1.6 0.9 SEMCO CIGT201610UMR47MNE 470 33 3.0 2.0 1.2 0.9 2. ISAT where the dc current drops the inductance by 30%. PIN CONFIGURATION VIN A1 SW A2 PGND A3 A3 A2 A1 B1 B2 B3 B3 B2 B1 C1 PGND C2 AGND C3 C3 C2 C1 VSEL D1 EN D2 SDA D3 D3 D2 D1 AGND E1 SCL E2 VOUT E3 E3 E2 E1 Top View Bottom View Figure 2. Pin Configuration Table 4. PIN DEFINITIONS Pin # Name Description D1 VSEL Voltage Select. When this pin is LOW, VOUT is set by the VSEL0 register. When this pin is HIGH, VOUT is set by the VSEL1 register. Polarity of pin in conjunction with the MODE bits in the Control register 02h, will select Forced PWM or Auto PFM/PWM mode of operation. VSEL0=Auto PFM, and VSEL1=FPWM. The VSEL pin has an internal pull-down resistor (250kW), which is only activated with a logic low. D2 EN Enable. The device is in Shutdown Mode when this pin is LOW. Device keeps register content when EN pin is LOW. The EN Pin has an internal pull-down resistor (250kW), which is only activated with a logic low. E2 SCL I2C Serial Clock D3 SDA I2C Serial Data E3 VOUT VOUT. Sense pin for VOUT. Connect to COUT. A3, B3, C2 PGND Power Ground. The low-side MOSFET is referenced to this pin. CIN and COUT should be returned with a minimal path to these pins. C3, E1 AGND Analog Ground. All signals are referenced to this pin. Avoid routing high dV/dt AC currents through this pin. A1, B1, C1 VIN Power Input Voltage. Connect to the input power source. Connect to CIN with minimal path. A2, B2 SW Switching Node. Connect to the inductor. www.onsemi.com 3 FAN53526 ABSOLUTE MAXIMUM RATINGS 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. Table 5. ABSOLUTE MAXIMUM RATINGS Symbol Parameter VIN Parameter Voltage on SW, VIN Pins Min Max Unit IC Not Switching -0.3 7.0 V IC Switching -0.3 6.5 -0.3 VIN (Note 3) -0.3 VIN (Note 3) -0.3 6.5 V 100 V/ms Voltage on EN Pin Voltage on All Other Pins VOUT IC Not Switching Voltage on VOUT Pin VINOV_SLEW ESD Maximum Slew Rate of VIN > 6.5V, PWM Switching Human Body Model, ANSI/ESDA/JEDEC JS-001-2012 2000 Charged Device Model per JESD22-C101 1000 V TJ Junction Temperature -40 +150 C TSTG Storage Temperature -65 +150 C +260 C TL Lead Soldering Temperature, 10 Seconds 3. Lesser of 7V or VIN + 0.3 V. 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. On Semiconductor does not recommend exceeding them or designing to Absolute Maximum Ratings. Table 6. RECOMMENDED OPERATING CONDITIONS Symbol Parameter VIN Supply Voltage Range IOUT Output Current Min. Max. Unit 2.5 Typ. 5.5 V 0 3.0 A TA Operating Ambient Temperature -40 +85 C TJ Operating Junction Temperature -40 +125 C Max. Unit Table 7. THERMAL PROPERTIES Symbol Parameter JA Junction-to-Ambient Thermal Resistance (Note 4) Min. Typ. 42 C/W 4. Junction-to-ambient thermal resistance is a function of application and board layout. This data is simulated with four-layer 2s2p boards with vias in accordance to JESD51- JEDEC standard. Special attention must be paid not to exceed the junction temperature www.onsemi.com 4 FAN53526 ELECTRICAL CHARACTERISTICS Table 8. ELECTRICAL CHARACTERISTICS Minimum and maximum values are at VIN=3.6 V, TA=-40C to +85C, unless otherwise noted. Typical values are at TA=25C, VIN=3.6 V, and EN=HIGH. VOUT = 1.15625 V. Parameter Symbol Condition Min. Typ. Max. Unit Power Supplies ILOAD=0 50 mA ILOAD=0, MODE Bit=1 (Forced PWM) 15 mA H/W Shutdown Supply Current EN=GND 0.1 3.0 mA S/W Shutdown Supply Current EN=VIN, BUCK_ENx=0, 2.5 V VIN 5.5 V 2 12 mA VUVLO Under-Voltage Lockout Threshold VIN Rising 2.32 2.45 V VUVHYST Under-Voltage Lockout Hysteresis IQ I SD Quiescent Current 350 mV EN, VSEL, SDA, SCL VIH high-Level Input Voltage 2.5 V VIN 5.5 V VIL low-Level Input Voltage 2.5 V VIN 5.5 V IIN Input Bias Current Input Tied to GND or VIN 1.1 V 0.01 0.4 V 1.00 mA VOUT Regulation VREG VOUT DC Accuracy 2.5 V VIN 5.5 V, VOUT from Minimum to Maximum, IOUT(DC)=0 to 3.0 A, Auto PFM/PWM -2.5 2.5 2.5 V VIN 5.5 V, VOUT from Minimum to Maximum, IOUT(DC)=0 to 3.0 A, Forced PWM -1.5 1.5 -2.3 -0.5 -14 -3 VIN=3.8 V, VOUT=0.6 V, IOUT(DC)=500 mA, Auto PFM/PWM % mV DV OUT DI LOAD Load Regulation IOUT(DC)=1 to 3 A -0.01 %/A DV OUT DV IN Line Regulation 2.5 V VIN 5.5 V, IOUT(DC)=1.5 A 0.01 %/A ILOAD Step 0.01 A 1.5 A, tr=tf=200 ns, VOUT=1.15625 V 50 ILOAD Step 0 A 500 mA, tr=tf=100 ns, VIN=3.8 V, VOUT=0.6 V 16 VTRSP Transient Response mV Power Switch / Protection ILIMPK P-MOS Peak Current Limit 4.00 TLIMIT Thermal Shutdown 150 C THYST Thermal Shutdown Hysteresis 17 C VSDWN Input OVP Shutdown Rising Threshold Falling Threshold 4.75 5.50 6.15 5.50 5.73 2.05 2.40 A V Frequency Control fSW Oscillator Frequency 2.75 MHz DAC Resolution Differential 7 Nonlinearity(5) Bits 0.5 www.onsemi.com 5 LSB FAN53526 Table 8. ELECTRICAL CHARACTERISTICS Minimum and maximum values are at VIN=3.6 V, TA=-40C to +85C, unless otherwise noted. Typical values are at TA=25C, VIN=3.6 V, and EN=HIGH. VOUT = 1.15625 V. Symbol Parameter Condition Min. Typ. Max. Unit Soft-Start tSS Regulator Enable to Regulated VOUT RLOAD > 5W, VOUT=1.15625V, From EN Rising Edge to 95% VOUT 150 ms 5. Monotonicity assured by design. Table 9. I2C TIMING SPECIFICATIONS Minimum and maximum values are at VIN=3.6 V, TA=-40C to +85C, unless otherwise noted. Typical values are at TA=25C, VIN=3.6 V, and EN=HIGH. VOUT = 1.15625 V. Symbol Parameter Condition Min. Typ. Max. Unit Power Supplies fSCL tBUF tHD;STA tLOW SCL Clock Frequency Bus-Free Time between STOP and START Conditions START or REPEATED START Hold Time SCL LOW Period Standard Mode 100 Fast Mode 400 Fast Mode Plus 1000 High-Speed Mode, CB 100 pF 3400 High-Speed Mode, CB 400 pF 1700 Standard Mode 4.7 Fast Mode 1.3 Fast Mode Plus 0.5 Standard Mode 4 Fast Mode 600 Fast Mode Plus 260 High-Speed Mode 160 Standard Mode 4.7 Fast Mode 1.3 Fast Mode Plus 0.5 High-Speed Mode, CB 100 pF 160 High-Speed Mode, CB 400 pF 320 Standard Mode tHIGH tSU;STA SCL HIGH Period Repeated START Setup Time 4 Fast Mode 600 Fast Mode Plus 260 High-Speed Mode, CB 100 pF 60 High-Speed Mode, CB 400 pF 120 Standard Mode 4.7 Fast Mode 600 Fast Mode Plus 260 High-Speed Mode 160 www.onsemi.com 6 kHz ms ms ns ms ns ms ns ms ns FAN53526 Table 9. I2C TIMING SPECIFICATIONS Minimum and maximum values are at VIN=3.6 V, TA=-40C to +85C, unless otherwise noted. Typical values are at TA=25C, VIN=3.6 V, and EN=HIGH. VOUT = 1.15625 V. Symbol Parameter Condition Min. Typ. Max. Unit Power Supplies tSU;DAT tHD;DAT tRCL tFCL tRCL1 tRDA tFDA tSU;STO CB Data Setup Time Data Hold Time SCL Rise Time SCL Fall Time Rise Time of SCL After a REPEATED START Condition and After ACK Bit SDA Rise Time SDA Fall Time Stop Condition Setup Time Standard Mode 250 Fast Mode 100 Fast Mode Plus 50 High-Speed Mode 10 ns Standard Mode 0 3.45 Fast Mode 0 900 Fast Mode Plus 0 450 High-Speed Mode, CB 100 pF 0 70 High-Speed Mode, CB 400 pF 0 150 Standard Mode 20+0.1CB 1000 Fast Mode 20+0.1CB 300 Fast Mode Plus 20+0.1CB 120 High-Speed Mode, CB 100 pF 10 80 High-Speed Mode, CB 400 pF 20 160 Standard Mode 20+0.1CB 300 Fast Mode 20+0.1CB 300 Fast Mode Plus 20+0.1CB 120 High-Speed Mode, CB 100 pF 10 40 High-Speed Mode, CB 400 pF 20 80 High-Speed Mode, CB 100 pF 10 80 High-Speed Mode, CB 400 pF 20 160 Standard Mode 20+0.1CB 1000 Fast Mode 20+0.1CB 300 Fast Mode Plus 20+0.1CB 120 High-Speed Mode, CB 100 pF 10 80 High-Speed Mode, CB 400 pF 20 160 Standard Mode 20+0.1CB 300 Fast Mode 20+0.1CB 300 Fast Mode Plus 20+0.1CB 120 High-Speed Mode, CB 100 pF 10 80 High-Speed Mode, CB 400 pF 20 160 Standard Mode 4 Fast Mode 600 Fast Mode Plus 120 High-Speed Mode 160 Capacitive Load for SDA and SCL 7 ns ns ns ns ns ns ms ns 400 www.onsemi.com ms pF FAN53526 Timing Diagrams OO OO OO OO OO OO OO OO NN NN NN NN NN NN OOO OOO tF SDA SCL tSU;STA tR TSU;DAT tHIGH tLOW tHD;STA tHD;DAT tSU;STA SCLH tHD;STO REPEATED START STOP Figure 3. I2C Interface Timing for Fast Plus, Fast, and Slow Modes UU UU UU UU UU UU UU UUU UUU tFDA SDAH tBUF tHD;STA START tRDA tFCL REPEATED START REPEATED START tRCL tSU;STO tHIGH tLOW tHD;STA START SSSS UU UUU SSSSUU OOUUU OO OO OO OO tSU;DAT tRCL1 II IIII II IIII IIII IIII IIII OO II OOII tHD;DAT note A = MCS Current Source Pull-up = RP Resistor Pull-up Note A: First rising edge of SCLH after Repeated Start and after each ACK bit. Figure 4. I2C Interface Timing for High-Speed Mode www.onsemi.com 8 STOP FAN53526 TYPICAL CHARACTERISTICS (Unless otherwise specified, Auto PFM/PWM Mode, VIN = 3.6 V, VOUT = 1.15625V, VSEL = EN = VIN, TA = 25C; circuit and components according to Figure 1 and Table 2. Efficiency test conditions; ILOAD: 1 mA to 3 A, L = 330 nH, DFE201612E-R33N (Toko). CIN = 4.7 mF, 0603, C1608X5R1A475K (TDK), COUT x 2 = 2X47 mF, 0603, GRM188R60J476ME (Murata).) Figure 5. Efficiency vs. Load Current and Input Voltage, VOUT=1.15625V Figure 6. Efficiency vs. Load Current and Temperature, VIN=3.6V, VOUT=1.15625V Figure 7. Output Regulation vs. Load Current and Input Voltage, VOUT=1.15625V Figure 8. PWM Entry / Exit Level vs. Input Voltage, VOUT=1.15625V Figure 9. Output Ripple vs. Load Current, VIN=4.2V and 3.6V, VOUT=1.15625V, Auto and Forced PWM Figure 10. Frequency vs. Load Current, VIN=4.2V and 3.6V, VOUT=1.15625V, Auto PWM www.onsemi.com 9 FAN53526 TYPICAL CHARACTERISTICS (continued) (Unless otherwise specified, Auto PFM/PWM Mode, VIN = 3.6 V, VOUT = 1.15625V, VSEL = EN = VIN, TA = 25C; circuit and components according to Figure 1 and Table 2. Efficiency test conditions; ILOAD: 1 mA to 3 A, L = 330 nH, DFE201612E-R33N (Toko). CIN = 4.7 mF, 0603, C1608X5R1A475K (TDK), COUT x 2 = 2X47 mF, 0603, GRM188R60J476ME (Murata).) Figure 11. Quiescent Current vs. Input Voltage and Temperature, Auto Mode, VOUT=1.15625V Figure 12. Shutdown Current vs. Input Voltage and Temperature VIN IOUT VOUT VOUT Figure 13. Line Transient, 3.6-4.2 VIN, 1.15625 VOUT, 10 ms Edge at 1 A Load Figure 14. Load Transient, 3.6 VIN, 1.15625 VOUT, 0.01-1.5 A, 120 ns Edge IOUT EN VOUT VOUT Figure 15. Startup, 5 W Load, VOUT = 1.15625 V, VIN = 3.6 V Figure 16. Load Transient, 3.6 VIN, 1.15625 VOUT, 1.5-3 A, 120 ns Edge www.onsemi.com 10 FAN53526 TYPICAL CHARACTERISTICS (continued) (Unless otherwise specified, Auto PFM/PWM Mode, VIN = 3.6 V, VOUT = 1.15625V, VSEL = EN = VIN, TA = 25C; circuit and components according to Figure 1 and Table 2. Efficiency test conditions; ILOAD: 1 mA to 3 A, L = 330 nH, DFE201612E-R33N (Toko). CIN = 4.7 mF, 0603, C1608X5R1A475K (TDK), COUT x 2 = 2X47 mF, 0603, GRM188R60J476ME (Murata).) IOUT (9500mA/div) 500mA 0mA 618mV VOUT (10mV/div) 0.6V offset + 16mV - 16mV 582mV Figure 17. Load Transient, 3.8 VIN, 0.6 VOUT, 0-500 mA, 100 ns Edge, 47 mF COUT Operating Description For very light loads, the FAN53526 operates in Discontinuous Current Mode (DCM) single-pulse PFM, which produces low output ripple compared with other PFM architectures. Transition between PWM and PFM is relatively seamless, providing a smooth transition between DCM and CCM Modes. PFM can be disabled by programming the MODE bits in the CONTROL register in combination with the state of the VSEL pin. See table in the Control Register, 02h. The FAN53526 is a step-down switching voltage regulator that delivers a programmable output voltage from an input voltage supply of 2.5 V to 5.5 V. Using a proprietary architecture with synchronous rectification, the FAN53526 is capable of delivering 3.0 A at over 80% efficiency. The regulator operates at a nominal frequency of 2.4 MHz at full load, which reduces the value of the external components to 330 nH or 470 nH for the output inductor and 44 F for the output capacitor. High efficiency is maintained at light load with single-pulse PFM. An I2C-compatible interface allows transfers up to 3.4 Mbps. This communication interface can be used to: * Dynamically re-program the output voltage in 6.25 mV increments; * Reprogram the mode to enable or disable PFM; * Control voltage transition slew rate; or * Enable / disable the regulator. Enable and Soft-Start When the EN pin is LOW; the IC is shut down, all internal circuits are off, and the part draws very little current. In this state, I2C can be written to or read from as long as input voltage is above the UVLO. The registers keep the content when the EN pin is LOW. The registers are reset to default values during a Power On Reset (POR). When the OUTPUT_DISCHARGE bit in the Control register is enabled (logic HIGH) and the EN pin is LOW or the BUCK_ENx bit is LOW, an 11 W load is connected from VOUT to GND to discharge the output capacitors. Raising EN while the BUCK_ENx bit is HIGH activates the part and begins the soft-start cycle. During soft-start, the modulator's internal reference is ramped slowly to minimize surge currents on the input and prevent overshoot of the output voltage. Synchronous rectification is inhibited, allowing the IC to start into a pre-charged capacitive load. If large values of output capacitance are used, the regulator may fail to start. The maximum COUT capacitance for starting with a heavy constant-current load is approximately: Control Scheme The FAN53526 uses a proprietary non-linear, fixed-frequency PWM modulator to deliver a fast load transient response, while maintaining a constant switching frequency over a wide range of operating conditions. The regulator performance is independent of the output capacitor ESR, allowing for the use of ceramic output capacitors. Although this type of operation normally results in a switching frequency that varies with input voltage and load current, an internal frequency loop holds the switching frequency constant over a large range of input voltages and load currents. www.onsemi.com 11 FAN53526 C OUTMAX [ (I LMPK * I LOAD) @ 320m tri-state before reattempting soft-start 1700 ms later. This limits the duty cycle of full output current during soft-start to prevent excessive heating. The IC allows for software enable of the regulator, when EN is HIGH, through the BUCK_EN bits. BUCK_EN0 and BUCK_EN1 are both initialized HIGH. These options start after a POR, regardless of the state of the VSEL pin. (eq. 1) V OUT where COUTMAX is expressed in F and ILOAD is the load current during soft-start, expressed in A. If the regulator is at its current limit for 16 consecutive current limit cycles, the regulator shuts down and enters Table 10. HARDWARE AND SOFTWARE ENABLE Pins BITS EN VSEL BUCK_EN0 BUCK_EN1 Output Mode 0 X X X OFF Shutdown 1 0 0 X OFF Shutdown 1 0 1 X ON Auto 1 1 X 0 OFF Shutdown 1 1 X 1 ON FPWM VSEL Pin and I2C Programming Output Voltage VSEL0 and VSEL HIGH corresponds to VSEL1. Upon POR, VSEL0 and VSEL1 are reset to their default voltages, as shown in Table 8. The output voltage is set by the NSELx control bits in VSEL0 and VSEL1 registers. The output is given as: V OUT + 0.600V ) NSELx @ 6.25mV (eq. 2) For example, if NSEL =1010000 (80 decimal), then VOUT = 0.600 + 0.5 = 1.100 V. Output voltage can also be controlled by toggling the VSEL pin LOW or HIGH. VSEL LOW corresponds to Transition Slew Rate Limiting When transitioning from a low to high voltage, the IC can be programmed for one of eight possible slew rates using the SLEW bits in the Control register, as shown in Table 5. Table 11. TRANSITION SLEW RATE Decimal Bin Slew Rate 0 000 64.00 mV/ms 1 001 32.00 mV/ms 2 010 16.00 mV/ms 3 011 8.00 mV/ms 4 100 4.00 mV/ms 5 101 2.00 mV/ms 6 110 1.00 mV/ms 7 111 0.50 mV/ms Input Over-Voltage Protection (OVP) Transitions from high to low voltage rely on the output load to discharge VOUT to the new set point. Once the high-to-low transition begins, the IC stops switching until VOUT has reached the new set point. When VIN exceeds VSDWN (~ 6.2 V), the IC stops switching to protect the circuitry from internal spikes above 6.5 V. An internal filter prevents the circuit from shutting down due to noise spikes. Under-Voltage Lockout (UVLO) Current Limiting When EN is HIGH, the under-voltage lockout keeps the part from operating until the input supply voltage rises HIGH enough to properly operate. This ensures proper operation of the regulator during startup or shutdown. A heavy load or short circuit on the output causes the current in the inductor to increase until a maximum current threshold is reached in the high-side switch. Upon reaching www.onsemi.com 12 FAN53526 I2C Interface this point, the high-side switch turns off, preventing high currents from causing damage. 16 consecutive current limit cycles in current limit, cause the regulator to shut down and stay off for about 1700 ms before attempting a restart. The serial interface is compatible with Standard, Fast, Fast Plus, and HS Mode I2C BusR specifications. The SCL line is an input and its SDA line is a bi-directional open-drain output; it can only pull down the bus when active. The SDA line only pulls LOW during data reads and when signaling ACK. All data is shifted in MSB (bit 7) first. Thermal Shutdown When the die temperature increases, due to a high load condition and/or high ambient temperature, the output switching is disabled until the die temperature falls sufficiently. The junction temperature at which the thermal shutdown activates is nominally 150C with a 17C hysteresis. I2C Slave Address In hex notation, the slave address assumes a 0 LS Bit. The hex slave address is C0 for all options except FAN53526UC168X, which has a hex slave address of C2. Monitor Register (Reg05) The Monitor register indicates of the regulation state of the IC. If the IC is enabled and is regulating, its value is (1000 0001). Table 12. I2C SLAVE ADDRESS Bits Hex 7 6 5 4 3 2 1 C0 1 1 0 0 0 0 0 C2 1 1 0 0 0 0 1 Other slave addresses can be assigned. Contact an On Semiconductor representative. SDA Bus Timing tHD;STA 0 Slave Address MS Bit SCL As shown in Figure 18 data is normally transferred when SCL is LOW. Data is clocked in on the rising edge of SCL. Typically, data transitions shortly at or after the falling edge of SCL to allow sufficient time for the data to set up before the next SCL rising edge. Figure 19. START Bit A transaction ends with a STOP condition, defined as SDA transitioning from 0 to 1 with SCL high, as shown in Figure 20. Data change allowed Slave Releases SDA SDA tH SCL Master Drives tHD;STO ACK(0) or NACK(1) SCL tSU Figure 20. STOP Bit During a read from the FAN53526, the master issues a REPEATED START after sending the register address and before resending the slave address. The REPEATED START is a 1 to 0 transition on SDA while SCL is HIGH, as shown in Figure 21. Figure 18. Data Transfer Timing Each bus transaction begins and ends with SDA and SCL HIGH. A transaction begins with a START condition, which is defined as SDA transitioning from 1 to 0 with SCL HIGH, as shown in Figure 19. www.onsemi.com 13 FAN53526 Slave Releases tSU;STA SDA The master generates a REPEATED START condition (Figure 21) that causes all slaves on the bus to switch to HS Mode. The master then sends I2C packets, as described above, using the HS Mode clock rate and timing. The bus remains in HS Mode until a STOP bit (Figure 20) is sent by the master. While in HS Mode, packets are separated by REPEATED START conditions (Figure 21). tHD;STA ACK(0) or NACK(1) SLADDR MS Bit SCL Figure 21. REPEATED START Timing High-Speed (HS) Mode Read and Write Transactions The protocols for High-Speed (HS), Low-Speed (LS), and Fast-Speed (FS) Modes are identical; except the bus speed for HS Mode is 3.4 MHz. HS Mode is entered when the bus master sends the HS master code 00001XXX after a START condition (Figure 19). The master code is sent in Fast or Fast-Plus Mode (less than 1 MHz clock); slaves do not ACK this transmission. The following figures outline the sequences for data read and write. Bus control is signified by the shading of the packet, defined as: * * Master Drives Bus and Slave Drives Bus All addresses and data are MSB first. Table 13. I2C BIT DEFINITIONS FOR FIGURE 22 AND FIGURE 23 Symbol Definition S START, see Figure 19 P STOP, see Figure 20 R REPEATED START, see Figure 21 A ACK. The slave drives SDA to 0 acknowledge the preceding packet. A NACK. The slave sends a 1 to NACK the preceding packet. 7 bits S Slave Address 0 0 8 bits 0 8 bits 0 A Reg Addr A Data A P Figure 22. Write Transaction 7 bits S Slave Address 0 0 8 bits 0 A Reg Addr A 7 bits R Slave Address 1 0 8 bits 1 A Data A Figure 23. Write Transaction Followed by a Read Transaction www.onsemi.com 14 P FAN53526 REGISTER DESCRIPTION Table 14. REGISTER MAP Hex Address Name 00 VSEL0 01 VSEL1 02 CONTROL 03 Function Binary Hex Controls VOUT settings when VSEL pin = LOW 1XXXXXXX XX Controls VOUT settings when VSEL pin = HIGH 1XXXXXXX XX Determines whether VOUT output discharge is enabled and also the slew rate of positive transitions 10000010 82 ID1 Read-only register identifies vendor and chip type 10000001 81 04 ID2 Read-only register identifies die revision 00001000 08 05 MONITOR Indicates device status 00000000 00 Table 15. BIT DEFINITIONS Bit Name Type Value VSEL0 Register Address: 00 Software buck enable. When EN pin is LOW, the regulator is off. When EN pin is HIGH, BUCK_EN bit takes precedent. 7 BUCK_EN0 R/W 1 6:0 NSEL0 R/W XXX XXXX VSEL1 Sets VOUT value from 0.600 to 1.39375 V (see Eq.2). Register Address: 01 Software buck enable. When EN pin is LOW, the regulator is off. When EN pin is HIGH, BUCK_EN bit takes precedent. 7 BUCK_EN1 R/W 1 6:0 NSEL1 R/W XXX XXXX CONTROL Sets VOUT value from 0.600 to 1.39375 V (see Eq.). Register Address: 02 0 When the regulator is disabled, VOUT is not discharged. When the regulator is disabled, VOUT discharges through an internal pull-down. 7 OUTPUT_ DISCHARGE R/W 1 6:4 SLEW R/W 000 -111 3 Reserved 2 RESET 1:0 Description MODE R/W R/W Sets the slew rate for positive voltage transitions (see Table 4) 0 Always reads back 0. 0 Setting to 1 resets all registers to default values. Always reads back 0. In combination with the VSEL pin, these two bits set the operation of the buck to be either in Auto-PFM/PWM Mode during light load or Forced PWM mode. See table below. Mode of Operation VSEL Pin Binary Operation 10 Low Low High High ID1 X0 X1 0X 1X Auto PFM/PWM Forced PWM Auto PFM/PWM Forced PWM Register Address: 03 7:5 VENDOR R 100 Signifies On Semiconductor as the IC vendor. 4 Reserved R 0 3:0 DIE_ID R 0001 Always reads back 0. ID2 DIE ID - FAN53525/6. Register Address: 04 7:4 Reserved R 0000 Always reads back 0000. 3:0 DIE_REV R 1000 FAN53526 Die Revision MONITOR 7 Register Address: 05 PGOOD R 1: Buck is enabled and soft-start is completed. 0 www.onsemi.com 15 FAN53526 Table 15. BIT DEFINITIONS Bit Name Type Value Description 6 UVLO R 0 1: Signifies the VIN is less than the UVLO threshold. 5 OVP R 0 1: Signifies the VIN is greater than the OVP threshold. 4 POS R 0 1: Signifies a positive voltage transition is in progress and the output voltage has not yet reached its new setpoint. 3 NEG R 0 1: Signifies a negative voltage transition is in progress and the output voltage has not yet reached its new setpoint. 2 RESET-STAT R 0 1: Indicates that a register reset was performed. This bit is cleared after register 5 is read. 1 OT R 0 1: Signifies the VIN is less than the UVLO threshold. 0 BUCK_STATUS R 0 1: Signifies the VIN is greater than the OVP threshold. APPLICATION INFORMATION Selecting the Inductor size typically decreases the DCR; but since I increases, the RMS current increases, as do core and skin-effect losses: The output inductor must meet both the required inductance and the energy-handling capability of the application. The inductor value affects the average current limit, the output voltage ripple, and the efficiency. The ripple current (I) of the regulator is: DI [ V OUT V IN @ V IN*V OUT L @ f SW I RMS + DI 2 OUT(DC) 2 ) DI 2 12 (eq. 5) The increased RMS current produces higher losses through the RDS(ON) of the IC MOSFETs and the inductor ESR. Increasing the inductor value produces lower RMS currents, but degrades transient response. For a given physical inductor size, increased inductance usually results in an inductor with lower saturation current. The increased RMS current produces higher losses through the RDS(ON) of the IC MOSFETs and the inductor ESR. Increasing the inductor value produces lower RMS currents, but degrades transient response. For a given physical inductor size, increased inductance usually results in an inductor with lower saturation current. (eq. 3) The maximum average load current, IMAX(LOAD), is related to the peak current limit, ILIM(PK), by the ripple current such that: I MAX(LOAD) + I LIM(PK)* I (eq. 4) The FAN53526 is optimized for operation with L=330 nH, but is stable with inductances up to 1.0 H (nominal). The inductor should be rated to maintain at least 80% of its value at ILIM(PK). Failure to do so decreases the amount of DC current the IC can deliver. Efficiency is affected by the inductor DCR and inductance value. Decreasing the inductor value for a given physical Table 16. EFFECTS OF INDUCTOR VALUE (FROM 330NH RECOMMENDED) ON REGULATOR PERFORMANCE IMAX(LOAD) DVOUT(Eq.(7)) Transient Response Increase Decrease Degraded Inductor Current Rating Output Capacitor and VOUT Ripple The current-limit circuit can allow substantial peak currents to flow through L1 under worst-case conditions. If it is possible for the load to draw such currents, the inductor should be capable of sustaining the current or failing in a safe manner. For space-constrained applications, a lower current rating for L1 can be used. The FAN53526 may still protect these inductors in the event of a short circuit, but may not be able to protect the inductor from failure if the load is able to draw higher currents than the DC rating of the inductor. Refer to Table 2 for the recommended inductors. If space is at a premium, 0603 capacitors may be used. Increasing COUT has negligible effect on loop stability and can be increased to reduce output voltage ripple or to improve transient response. Output voltage ripple, DVOUT, is calculated by: DV OUT + DI L f SW @ C OUT @ ESR 2 2 @ D @ (1 * D) ) 1 8 @ f SW @ C OUT where COUT is the effective output capacitance. www.onsemi.com 16 (eq. 6) FAN53526 The capacitance of COUT decreases at higher output voltages, which results in higher DVOUT. Equation 6 is only valid for CCM operation, which occurs in PWM Mode. The FAN53526 can be used with either 2 x 22 mF (0603) or 2 x 47 mF (0603) output capacitor configuration. If a tighter ripple and transient specification is need from the FAN53526, then the 2 x 47 mF is recommended. The lowest DVOUT is obtained when the IC is in PWM Mode and, therefore, operating at 2.4 MHz. In PFM Mode, fSW is reduced, causing DVOUT to increase. For the FAN53526, JA is 42C/W when mounted on its four-layer with vias evaluation board in still air with 2 oz. outer layer copper weight and 1 oz. inner layer. For long-term reliable operation, the junction temperature (TJ) should be maintained below 125C. To calculate maximum operating temperature (<125C) for a specific application: 1. Use efficiency graphs to determine efficiency for the desired VIN, VOUT, and load conditions. 2. Calculate total power dissipation using: ESL Effects 1 P T + V OUT @ I LOAD @ h * 1 The Equivalent Series Inductance (ESL) of the output capacitor network should be kept low to minimize the square-wave component of output ripple that results from the division ratio COUT ESL and the output inductor (LOUT). The square-wave component due to the ESL can be estimated as: DV OUT(SQ) [ V IN @ ESL COUT L1 (eq. 8) 3. Estimate inductor copper losses using: 2 P L + I LOAD @ DCR L (eq. 9) 4. Determine IC losses by removing inductor losses (step 3) from total dissipation: P IC + P T * P L (eq. 10) 5. Determine device operating temperature: (eq. 7) DT + P IC @ Q JA A good practice to minimize this ripple is to use multiple output capacitors to achieve the desired COUT value. For example, to obtain COUT=20 mF, a single 22 mF 0805 would produce twice the square wave ripple as two x 10 mF 0805. To minimize ESL, try to use capacitors with the lowest ratio of length to width. 0805 s have lower ESL than 1206 s. If low output ripple is a chief concern, some vendors produce 0508 capacitors with ultra-low ESL. Placing additional small-value capacitors near the load also reduces the high-frequency ripple components. T IC + T A ) DT (eq. 11) and Note that the RDS(ON) of the power MOSFETs increases linearly with temperature at about 1.4%/C. This causes the efficiency () to degrade with increasing die temperature. Layout Recommendations 1. The input capacitor (CIN) should be connected as close as possible to the VIN and GND pins. Connect to VIN and GND using only top metal. Do not route through vias. 2. Place the inductor (L) as close as possible to the IC. Use short wide traces for the main current paths. 3. The output capacitor (COUT) should be as close as possible to the IC. Connection to GND should be on top metal. Feedback signal connection to VOUT should be routed away from noisy components and traces (e.g. SW line). For remote sensing application, place one or all output capacitors near the load and if there are also output capacitors placed near the inductor, the maximum trace resistance between the inductor and the load should not exceed 30 mW. Input Capacitor The ceramic input capacitors should be placed as close as possible between the VIN and PGND pins to minimize the parasitic inductance. If a long wire is used to bring power to the IC, additional "bulk" capacitance (electrolytic or tantalum) should be placed between CIN and the power source lead to reduce under-damped ringing that can occur between the inductance of the power source leads and CIN. Thermal Considerations Heat is removed from the IC through the solder bumps to the PCB copper. The junction-to-ambient thermal resistance (JA) is largely a function of the PCB layout (size, copper weight, and trace width) and the temperature rise from junction to ambient (T). www.onsemi.com 17 FAN53526 Figure 24. Guidance for Layer 1 Figure 25. Layer 2 Figure 26. Layer 3 www.onsemi.com 18 FAN53526 Figure 27. Layer 4 1. Feedback trace connects to "+" side of the output capacitor. VIN EN 2. For remote sensing, place one or all output capacitors near the load. CBY CIN VOUT SDA FAN53526 SCL L1 SW VDD COUT_LOAD COUT VSEL PGND Core Processor (System Load) AGND GND 3. If there are also output capacitors placed near the inductor, the maximum trace resistance between the inductor and the load should not exceed 30 mW. Figure 28. Remote Sensing Schematic Table 17. PRODUCT SPECIFIC DIMENSIONS D E X Y 2.015 0 03 mm 1.310 0.03 mm 0.255 mm 0.2075 mm TinyBuck is registered trademark of Semiconductor Components Industries, LLC (SCILLC) or its subsidiaries in the United States and/or other countries. ARM is a registered trademark of ARM Limited (or its subsidiaries) in the EU and/or elsewhere. Tegra is a trademark of NVIDIA Corporation. OMAP is a trademark and brand of Texas Instruments Incorporated. NovaThor is a trademark of ST-Ericsson. ARMADA is a trademark of Emergency Technology, Inc. Krait is a trademark of Qualcomm Incorporated. www.onsemi.com 19 MECHANICAL CASE OUTLINE PACKAGE DIMENSIONS WLCSP15 2.015x1.31x0.586 CASE 567QS ISSUE O DOCUMENT NUMBER: DESCRIPTION: 98AON13347G DATE 31 OCT 2016 Electronic versions are uncontrolled except when accessed directly from the Document Repository. Printed versions are uncontrolled except when stamped "CONTROLLED COPY" in red. WLCSP15 2.015x1.31x0.586 PAGE 1 OF 1 ON Semiconductor and are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries. ON Semiconductor reserves the right to make changes without further notice to any products herein. ON Semiconductor makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does ON Semiconductor assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages. ON Semiconductor does not convey any license under its patent rights nor the rights of others. (c) Semiconductor Components Industries, LLC, 2019 www.onsemi.com ON Semiconductor and are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries. 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