AN30185A-VL

AN30185A VIN = 2.9V to 5.5V 2ch,0.8A General-purpose High Efficiency Power LSI FEATURES z z z z z z DESCRIPTION High-speed response DC-DC Step-Down Regulator circuit that employs hysteretic control system : 2-ch (1.0 V, 0.8 A / 1.8 V, 0.8 A) LDO : 1-ch (0.9 V, 10 mA) Built-in external Pch MOSFET gate drive circuits Built-in Reset function Built-in Under Voltage Lockout function (UVLO) 24pin Plastic Quad Flat Non-leaded Package (Size : 4 × 4 mm, 0.5 mm pitch) APPLICATIONS High Current Distributed Power Systems such as SSD (Solid State Drive), Cellular Phone, etc. AN30185A is a power management LSI which has DC-DC step down regulators (2-ch) that employs hysteretic control system. By this system, when load current changes suddenly, it responds at high speed and minimizes the changes of output voltage. Since it is possible to use capacitors with small capacitance and it is unnecessary to use parts for phase compensation, this IC realizes downsizing of set and reducing in the number of external parts. Output voltages are 1.0 V and 1.8 V. Each maximum current is 0.8 A. This LSI has a LDO circuit, external Pch-MOSFET gate drive circuits and a reset circuit of input power supply voltage. SIMPLIFIED APPLICATION EFFICIENCY CURVE [DC-DC1] 㪐㪇 3.3V 3.3V 㪏㪌 㪏㪇 㪎㪌 EN PVIN1 EN2 RESET PVIN1 PCNT DIS 4.7 μF LX1 PVIN2 4.7 μF AN30185A AVIN 2.2 μH 㪍㪇 㪭㪠㪥㪔㪊㪅㪊㪭 㪭㪠㪥㪔㪌㪭 㪋㪌 㪋㪇 10 μF 㪈 㪈㪇 㪈㪇㪇 㪈㪇㪇㪇 㫃㫆㪸㪻㩷㪺㫌㫉㫉㪼㫅㫋㩷㪲㫄㪘㪴 VOUT2 2.2 μH BUF VREG AGND1 AGND2 PGND1 PGND2 㪍㪌 㪌㪇 VOUT1 FB2 LX2 AVIN 㪎㪇 㪌㪌 FB1 PVIN2 4.7 μF 㪼㪽㪽㫀㪺㫀㪼㫅㪺㫐㩷㪲㩼㪴 10 kΩ Condition : VIN=3.3V or 5.0V , Vout=1.0V , Cout=10μF , Lout=2.2μH 10 μF 1.0 μF [DC-DC2] 1.0 μF 㪈㪇㪇 㪐㪌 㪐㪇 Notes) This application circuit is an example. The operation of mass production set is not guaranteed. You should perform enough evaluation and verification on the design of mass production set. You are fully responsible for the incorporation of the above application circuit and information in the design of your equipment. 㪼㪽㪽㫀㪺㫀㪼㫅㪺㫐㩷㪲㩼㪴 㪏㪌 㪏㪇 㪎㪌 㪎㪇 㪍㪌 㪭㪠㪥㪔㪊㪅㪊㪭 㪭㪠㪥㪔㪌㪭 㪍㪇 㪌㪌 㪌㪇 㪈 㪈㪇 㪈㪇㪇 㪈㪇㪇㪇 㫃㫆㪸㪻㩷㪺㫌㫉㫉㪼㫅㫋㩷㪲㫄㪘㪴 Condition : VIN=3.3V or 5.0V , Vout=1.8V , Cout=10μF , Lout=2.2μH Publication date: October 2012 1 Ver. BEB AN30185A ABSOLUTE MAXIMUM RATINGS Parameter Symbol Rating Unit Notes Supply voltage VIN 6.0 V *1 *3 Operating free-air temperature Topr – 40 to + 85 °C *2 Operating junction temperature Tj – 40 to + 150 °C *2 Storage temperature Tstg – 55 to + 150 °C *2 Input Voltage Range EN,EN2,FB1,FB2 – 0.3 to (VIN + 0.3) V *1 *3 LX1,LX2,PCNT,DIS, RESET,BUF,VREG – 0.3 to (VIN + 0.3) V *1 *3 HBM (Human Body Model) 2 kV - Output Voltage Range ESD Notes) Do not apply external currents and voltages to any pin not specifically mentioned. This product may sustain permanent damage if subjected to conditions higher than the above stated absolute maximum rating. This rating is the maximum rating and device operating at this range is not guaranteeable as it is higher than our stated recommended operating range. When subjected under the absolute maximum rating for a long time, the reliability of the product may be affected. *1:The values under the condition not exceeding the above absolute maximum ratings and the power dissipation. *2:Except for the power dissipation, operating ambient temperature, and storage temperature, all ratings are for Ta = 25°C. *3:VIN is voltage for AVIN, PVIN1 = PVIN2,(VIN + 0.3) V must not be exceeded 6 V. POWER DISSIPATION RATING PACKAGE θJA 9pin Wafer level chip size package 84.9 °C /W (WLCSP Type) PD(Ta=25°C) PD(Ta=85°C) Notes 1.472 W 0.765 W *1 Note). For the actual usage, please refer to the PD-Ta characteristics diagram in the package specification, follow the power supply voltage, load and ambient temperature conditions to ensure that there is enough margin and the thermal design does not exceed the allowable value. *1:Glass Epoxy Substrate(4 Layers) [Glass-Epoxy: 50 X 50 X 0.8t(mm)] Die Pad Exposed , Soldered. CAUTION Although this has limited built-in ESD protection circuit, but permanent damage may occur on it. Therefore, proper ESD precautions are recommended to avoid electrostatic damage to the MOS gates 2 Ver. BEB AN30185A RECOMMENDED OPERATING CONDITIONS Parameter Symbol Min. Typ. Max. Unit Notes VIN 2.9 3.3 5.5 V *1 *2 EN – 0.3 — VIN + 0.3 V *3 EN2 – 0.3 — VIN + 0.3 V *3 FB1 – 0.3 — VIN + 0.3 V *3 FB2 – 0.3 — VIN + 0.3 V *3 LX1,LX2 – 0.3 — VIN + 0.3 V *3 PCNT – 0.3 — VIN + 0.3 V *3 DIS – 0.3 — VIN + 0.3 V *3 RESET – 0.3 — VIN + 0.3 V *3 BUF – 0.3 — VIN + 0.3 V *3 VREG – 0.3 — VIN + 0.3 V *3 Supply voltage range Input Voltage Range Output Voltage Range Note) Do not apply external currents and voltages to any pin not specifically mentioned. Voltage values, unless otherwise specified, are with respect to GND. GND is voltage for AGND1, AGND2, PGND1, PGND2. AGND1 = AGND2 = PGND1 = PGND2. Vin is voltage for AVIN, PVIN1, PVIN2. AVIN = PVIN1 = PVIN2. *1 : Please set the rising time of power input pin to the following range. In addition, please input the voltage with the rising time which has margin enough in consideration of the variation in external parts. *2 : The values under the condition not exceeding the above absolute maximum ratings and the power dissipation. *3 : (VIN + 0.3) V must not be exceeded 6 V. 0V 100 μs < Tr < 1.5 ms (Tr is the rise time from 0 V to the setup voltage of VIN.) 3 Ver. BEB AN30185A ELECTRICAL CHARACTERISTICS VIN = AVIN = PVIN1 = PVIN2 = 3.3V [DC-DC1] Cout = 10 μF (GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) [DC-DC2] Cout = 10 μF (GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) Ta = 25 °C ± 2 °C unless otherwise noted. Limits Parameter Symbol Conditions Min Typ Max Unit Notes [DC-DC1] (1.0 V DC/DC step-down regulator) [DC-DC2] (1.8 V DC/DC step-down regulator) Consumption current at active IACT EN = 3.3 V, IOUT1, IOUT2, IOUT(BUF) = 0 A — 200 300 μA — EN pin Low-level input voltage VENL VIN = 3.3 V — 0 0.3 V — EN pin High-level input voltage VENH VIN = 3.3 V 1.5 3.3 — V — EN pin leak current ILEAK EN EN = 3.3 V — 2.4 10 μA — EN2 pin Low-level input voltage VEN2L VIN = 3.3 V — 0 0.3 V — EN2 pin High-level input voltage VEN2H VIN = 3.3 V 1.5 3.3 — V — EN2 pin leak current ILEAK EN2 EN2 = 3.3 V — 2.0 10 μA — DC-DC1 output voltage DD1 VOUT IOUT1 = 450 mA 0.980 1.000 1.020 V — DC-DC2 output voltage DD2 VOUT IOUT2 = 500 mA 1.764 1.800 1.836 V — UVLO start voltage VUVLO VIN = 3.3 V → 0 V DET 2.4 2.5 2.6 V — UVLO stop voltage VUVLO VIN = 0 V → 3.3 V RMV 2.45 2.6 2.8 V — Reset detection voltage VRST DET VIN = 3.3 V → 0 V 2.740 2.810 2.880 V — Reset cancel voltage VRST RMV VIN = 0 V → 3.3 V 2.847 2.920 2.993 V — Reset ON resistance RON RST EN = 0 V — 10 20 Ω — DIS discharge resistance RON DIS EN = 0 V — 90 190 Ω — BUF output voltage BUF VOUT IOUT(BUF) = 10 μA 0.873 0.900 0.927 V — 4 Ver. BEB AN30185A ELECTRICAL CHARACTERISTICS (Continued) VIN = AVIN = PVIN1 = PVIN2 = 3.3V [DC-DC1] Cout = 10 μF (GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) [DC-DC2] Cout = 10 μF (GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) Ta = 25 °C ± 2 °C unless otherwise noted. Reference values Parameter Symbol Conditions Unit Notes — μA *1 6 — mV *1 — 8 — mV *1 DD1 I = 10 μA → 800 mA REGLD OUT1 — 10 — mV *1 DD2 I = 10 μA → 800 mA REGLD OUT2 — 15 — mV *1 Min Typ Max EN = 0 V — 0 DC-DC1 line regulation VIN = 2.9 V → 5.5 V DD1 REGIN IOUT1 = 450 mA — DC-DC2 line regulation VIN = 2.9 V → 5.5 V DD2 REGIN IOUT2 = 500 mA DC-DC1 load regulation DC-DC2 load regulation [DC-DC1] (1.0 V DC/DC step-down regulator) [DC-DC2] (1.8 V DC/DC step-down regulator) Consumption current at standby ISTB DC-DC1 output current limit DD1 ILMT FB1 = 1.0 V → 0.5 V — 1.6 — A *1 DC-DC2 output current limit DD2 ILMT FB2 = 1.8 V → 0.9 V — 1.6 — A *1 DC-DC1 efficiency 1 DD1 EFF1 VIN = 3.3 V IOUT1 = 10 mA — 77 — % *1 DC-DC1 efficiency 2 DD1 EFF2 VIN = 5 V IOUT1 = 10 mA — 71 — % *1 DC-DC1 efficiency 3 DD1 EFF3 VIN = 3.3 V IOUT1 = 450 mA — 80 — % *1 DC-DC1 efficiency 4 DD1 EFF4 VIN = 5 V IOUT1 = 450 mA — 77 — % *1 DC-DC2 efficiency 1 DD2 EFF1 VIN = 3.3 V IOUT2 = 10 mA — 86 — % *1 DC-DC2 efficiency 2 DD2 EFF2 VIN = 5 V IOUT2 = 10 mA — 80 — % *1 DC-DC2 efficiency 3 DD2 EFF3 VIN = 3.3 V IOUT2 = 500 mA — 85 — % *1 DC-DC2 efficiency 4 DD2 EFF4 VIN = 5 V IOUT2 = 500 mA — 84 — % *1 DC-DC1 output ripple voltage 1 DD1 VRPL1 IOUT1 = 10 mA — 30 — mV[p-p] *1 DC-DC1 output ripple voltage 2 DD1 VRPL2 IOUT1 = 450 mA — 7 — mV[p-p] *1 D-CDC2 output ripple voltage 1 DD2 VRPL1 IOUT2 = 10 mA — 30 — mV[p-p] *1 DC-DC2 output ripple voltage 2 DD2 VRPL2 IOUT2 = 500 mA — 7 — mV[p-p] *1 *1 䋺Typical Value checked by design. 5 Ver. BEB AN30185A ELECTRICAL CHARACTERISTICS (Continued) VIN = AVIN = PVIN1 = PVIN2 = 3.3V [DC-DC1] Cout = 10 μF (GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) [DC-DC2] Cout = 10 μF (GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) Ta = 25 °C ± 2 °C unless otherwise noted. Reference values Parameter Symbol Conditions Min Typ Max Unit Notes [DC-DC1] (1.0 V DC/DC step-down regulator) [DC-DC2] (1.8 V DC/DC step-down regulator) DC-DC1 load transient response DD1 IOUT1 = 50 mA ↔ 200 mA DVAC Δ t = 1 μs — 25 — mV *1 DC-DC2 load transient response DD2 IOUT2 = 10 mA ↔ 250 mA DVAC Δ t = 1 μs — 25 — mV *1 DC-DC1 operating frequency DD1 FSW IOUT1 = 450 mA — 1.2 — MHz *1 DC-DC2 operating frequency DD2 FSW IOUT2 = 500 mA — 1.2 — MHz *1 DC-DC1 discharge resistance DD1 RDIS EN = 0 V — 100 — Ω *1 DC-DC2 discharge resistance DD2 RDIS EN = 0 V — 150 — Ω *1 DC-DC1 Pch-MOS ON resistance DD1 RONP — — 0.25 — Ω *1 DC-DC2 Pch-MOS ON resistance DD2 RONP — — 0.3 — Ω *1 DC-DC1 Nch-MOS ON resistance DD1 RONN — — 0.2 — Ω *1 DC-DC2 Nch-MOS ON resistance DD2 RONN — — 0.25 — Ω *1 DC-DC1 start time Capacitive load : 26 μF DD1 IOUT1 = 0 A TSTU The time until 90 % from 10 % of target value. — 0.1 — ms *1 DC-DC2 start time Capacitive load : 24 μF DD2 IOUT2 = 0 A TSTU The time until 90 % from 10 % of target value. — 0.15 — ms *1 *1 䋺Typical Value checked by design. 6 Ver. BEB AN30185A ELECTRICAL CHARACTERISTICS (Continued) VIN = AVIN = PVIN1 = PVIN2 = 3.3V [DC-DC1] Cout = 10 μF (GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) [DC-DC2] Cout = 10 μF (GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) Ta = 25 °C ± 2 °C unless otherwise noted. Reference values Parameter Symbol Conditions Min Typ Max Unit Notes [DC-DC1] (1.0 V DC/DC step-down regulator) [DC-DC2] (1.8 V DC/DC step-down regulator) BUF line regulation BUF REG IN VIN = 2.9V → 5.5V IOUT(BUF) = 10 μA — 0 — mV *1 BUF load regulation BUF REG LD IOUT(BUF) = 10 μA → 10 mA — 5 — mV *1 BUD output current limit BUF ILMT BUF = 0V — 10 — mA *1 BUF PSRR BUF PSR IOUT(BUF) = 10 μA f = 10 kHz — –50 — dB *1 BUF load transient response 1 BUF I = 10 μA → 10 mA DVAC OUT(BUF) Δ t = 1 μs 1 — 160 — mV *1 BUF load transient response 2 BUF I = 10 mA → 10 μA DVAC OUT(BUF) Δ t = 1 μs 2 — 100 — mV *1 BUF discharge resistance BUF RDIS — 80 — Ω *1 BUF start time IOUT(BUF) = 0 A BUF The time until 90 % from 10 % TSTU of target value. — 50 — μs *1 — 30 — ms *1 — 2.5 — μA *1 — 1 — ms *1 Reset delay EN = 0 V RST DLY — PCNT sink current IPCNT PCNT = 3.3 V Timer latch time TLAT CH DC-DC1 Ground-short detection voltage DD1 SCP FB1 = 1.0 V → 0 V — 0.5 — V *1 DC-DC2 Ground-short detection voltage DD2 SCP FB2 = 1.8 V → 0 V — 0.9 — V *1 TSD operating temperature TJSO Temperature error detection — 160 — °C *1 — *1 䋺Typical Value checked by design. 7 Ver. BEB AN30185A BUF VREG AGND1 FB1 RESET Top View AVIN PIN CONFIGURATION 18 17 16 15 14 13 PVIN2 19 12 PGND1 PVIN2 20 11 PGND1 LX2 21 10 LX1 LX2 22 9 LX1 PGND2 23 8 PVIN1 PGND2 24 7 PVIN1 EN FB2 AGND2 PIN FUNCTION Pin No. Pin name 4 5 6 PCNT 3 EN2 2 DIS 1 Type Description 1 EN Input ON/OFF control pin 2 FB2 Input Feed Back pin ( for DC-DC2 ) 3 AGND2 4 EN2 Input DCDC2 and BUF control pin 5 DIS Output Discharge pin ( open drain ) 6 PCNT Output External Pch MOSFET gate control pin 7 PVIN1 Power supply Power supply pin ( for DC-DC1 ) 8 PVIN1 Power supply Power supply pin ( for DC-DC1 ) 9 LX1 Output Driver output pin ( for DC-DC1 ) 10 LX1 Output Driver output pin ( for DC-DC1 ) 11 PGND1 Ground Ground pin ( for DC-DC1 ) 12 PGND1 Ground Ground pin ( for DC-DC1 ) 13 RESET Output Reset output pin ( open drain ) 14 FB1 Input Feed Back pin ( for DC-DC1 ) 15 AGND1 Ground Ground pin 16 VREG Output LDO output pin ( Power supply for internal control circuit / 2.55 V ) 17 AVIN 18 BUF 19 PVIN2 Power supply Power supply pin ( for DC-DC2 ) 20 PVIN2 Power supply Power supply pin ( for DC-DC2 ) 21 LX2 Output Driver output pin ( for DC-DC2 ) 22 LX2 Output Driver output pin ( for DC-DC2 ) 23 PGND2 Ground Ground pin ( for DC-DC2 ) 24 PGND2 Ground Ground pin ( for DC-DC2 ) Ground Ground pin Power supply Power supply pin Output LDO output pin ( 0.9 V ) Notes) Concerning detail about pin description, please refer to OPERATION and APPLICATION INFORMATION section. 8 Ver. BEB AN30185A FUNCTIONAL BLOCK DIAGRAM 13 : RESET PCNT 17 : AVIN UVLO RESET 6 : PCNT 5 : DIS Enable 1.24 V BGR DC-DC1 (1.0 V, 800 mA) 14 : FB1 16 : VREG SHP VREG OCP TSD Control logic Driver 7,8 : PVIN1 9,10 : LX1 Enable 11,12 : PGND1 ENC 1 : EN 0.94 ms delay 2.81 ms delay DC-DC2 (1.8 V, 800 mA) 2 : FB2 Enable SHP OCP 19,20 : PVIN2 0.47 ms delay Control logic OSC Driver 21,22 : LX2 23,24 : PGND2 4 : EN2 Enable 18 : BUF 15 : AGND1 BUF 3 : AGND2 Notes) This block diagram is for explaining functions. Part of the block diagram may be omitted, or it may be simplified. 9 Ver. BEB AN30185A OPERATION 1. Pin Setting For Start / Stop Control EN High Low EN2 High Low High Low DC-DC1(1.0V) ON ON OFF OFF External Pch-MOSFE Gate control circuit ON ON OFF OFF DC-DC2(1.8V) ON OFF OFF OFF BUF(0.9V) ON OFF OFF OFF EN pin is the main control pin. When EN pin becomes High, DC-DC1 and external Pch-MOSFET gate control circuit turn on,and DC-DC2 and BUF become controllable by EN2 pin. EN2 pin is the control pin for DC-DC2 and BUF. When EN2 pin becomes High, DC-DC2 and BUF turn on. Even if EN2 is High under the condition that EN is Low, DC-DC2 and BUF do not turn on. 10 Ver. BEB AN30185A OPERATION (Continued) 2. Start / Stop Control Timing Chart Note) The characteristics listed below are reference values derived from the design of the IC and are not guaranteed. Start / Stop control sequence by EN pin under the condition that EN2 pin is fixed to High is as follows. VIN EN EN2 UVLO 30 ms RESET 100 μs 1.0 V FB1 Terminated with a resistor VIN PCNT 0.94 ms VIN Constant current discharge (2.5 μA) 300 μs 3.3 V DIS (3.3 V line) Terminated with a resistor 2.81 ms 150 μs 1.8 V FB2 Terminated with a resistor 3.75 ms 0.47 ms 50 μs BUF 4.22 ms 0.9 V Terminated with a resistor Note) All values given in the above figure are typical values. 11 Ver. BEB AN30185A OPERATION (Continued) 2. Start / Stop Control Timing Chart Note) The characteristics listed below are reference values derived from the design of the IC and are not guaranteed. Start / Stop sequence in case that EN pin and EN2 pin are connected to power supply (VIN) is as follows. 2.92 V VIN 2.6 V 2.81 V 2.5 V EN 0.85 V EN2 UVLO 30 ms RESET Natural discharge 100 μs 1.0 V Terminated with a resistor FB1 VIN PCNT 0.94 ms VIN Constant current discharge (2.5 μA) 300 μs DIS (3.3 V line) 3.3 V Terminated with a resistor 2.81 ms 150 μs 1.8 V FB2 Terminated with a resistor Natural discharge Terminated with a resistor 3.75 ms 0.47 ms 50 μs BUF Natural discharge 4.22 ms 0.9 V Note) All values given in the above figure are typical values. 12 Ver. BEB AN30185A OPERATION (Continued) 2. Start / Stop Control Timing Chart Note) The characteristics listed below are reference values derived from the design of the IC and are not guaranteed. Start / Stop control sequence by EN2 pin under the condition that EN pin is fixed to High is as follows. VIN EN EN2 UVLO RESET 1.0 V FB1 PCNT DIS (3.3 V line) FB2 3.3 V 150 μs 1.8 V 1.88㨪3.76 ms Terminated with a resistor 50 μs 0.47 ms BUF 0.9 V Terminated with a resistor Note) All values given in the above figure are typical values. 13 Ver. BEB AN30185A OPERATION (Continued) 3. Protection Note) The characteristics listed below are reference values derived from the design of the IC and are not guaranteed. • UVLO function When power supply rises to 2.6 V or higher at EN = High, UVLO is released, and the operation of each function starts. Since this function's hysteresis is 100 mV, UVLO detects when power supply falls to 2.5 V or lower, then each function shuts down. • Reset function RESET pin shifts to High at 30 ms delay after power supply rises to 2.92 V or higher. (Output type : Nch MOS open drain) Since this function's hysteresis is 110 mV, RESET pin shifts to Low when power supply falls to 2.81 V or lower.(No delay in case of High → Low) • DC-DC1 (Output voltage : 1.0 V) When UVLO is released, DC-DC1 starts and outputs 1.0 V. Soft-start function operates for 1 ms after startup. Since output voltage rises slowly, limiting input current, it is possible to prevent rush current and overshoot. When UVLO detects, DC-DC1 turns off. When EN pin shifts to Low, an output pin (FB1) is terminated with a resistor. • External Pch-MOSFET gate control function PCNT pin is discharged by the constant current (2.5 μA) at 0.94 ms delay after UVLO is released. By connecting the gate of Pch MOSFET to PCNT pin, it is possible to turn on this FET softly. At the same time, the termination with a resistor of DIS pin is released. Just after UVLO detects, PCNT pin voltage becomes VIN and DIS pin is terminated with a resistor. • DC-DC2 (Output voltage : 1.8 V) When both EN pin and EN2 pin are fixed to High, DC-DC2 turns on and outputs 1.8 V. Start-up timing is as follows. 1) In case that EN pin becomes Low → High when EN2 pin is fixed to High → 3.75 ms delay from UVLO release 2) In case that EN2 pin becomes Low → High within 3.75 ms from UVLO release when EN pin is fixed to High → 3.75 ms delay from UVLO release 3) In case that EN2 pin becomes Low → High after 3.75 ms from UVLO release when EN pin is fixed to High → 1.88 ms to 3.76 ms delay from when EN2 pin becomes Low → High DC-DC2 has the same soft-start function as DC-DC1 and starts, preventing rush current and overshoot. DC-DC2 stops because UVLO detects. When EN pin shifts to Low, an output pin (FB2) is terminated with a resistor. DC-DC2 also stops when EN2 pin becomes Low, and the output pin is terminated with a resistor. • BUF (Output voltage : 0.9 V) BUF pin outputs 0.9 V when both EN pin and EN2 pin are fixed to High. Start-up timing is 0.47 ms delay after DC-DC2 turns on. BUF starts, preventing rush current and overshoot. BUF stops because UVLO detects. BUF is terminated with a resistor when EN pin shifts to Low. BUF also stops when EN2 pin becomes Low, and the output pin is terminated with a resistor. 14 Ver. BEB AN30185A OPERATION (Continued) 3. Protection Note) The characteristics listed below are reference values derived from the design of the IC and are not guaranteed. Ground-short protection function DC-DC1 and DC-DC2 have ground-short detection circuits respectively. When output voltage falls to 50% or lower Of target value (DC-DC1 : 0.5 V, DC-DC2 : 0.9 V), it shifts to the protection sequence shown in [3.Protection]. However, even if BUF pin shorts to GND, BUF does not shift to the protection sequence. Over-current limit function DC-DC1, DC-DC2 and BUF have over-current limit circuits respectively. This function limits the output current which exceeds the setup value. The over-current limit characteristics are as follows. Output voltage Output voltage 0.8A to 2.0 A VO 0.9 V Ground-short detection level ½ VO 0 0 1.6A(typ) Output VO = 1.0 V(DC-DC1), 1.8 V(DC-DC2) current 40 mA Output current 10 mA b) BUF a) DC-DC1/2 The output currents of DC-DC1 and DC-DC2 are limited to 1.6 A(typ) regardless of the output voltage. BUF has limit characteristics, which the output current decreases as the output voltage falls. The peak input current is 40 mA(typ). The input current at BUF = 0 V is 10 mA(typ). 15 Ver. BEB AN30185A OPERATION (Continued) 3. Protection Note) The characteristics listed below are reference values derived from the design of the IC and are not guaranteed. Protection Sequence When the following state continues for 1 ms(typ), AN30185A shifts to the protection sequence. — Any of DCDC1 and DCDC2 shorts to GND. (Output voltage is 50% or lower of target value.) — TSD circuit detects abnormal state. When this LSI shifts to the protection sequence, it is latched to the state at which each function is shut down. It recovers from the protection sequence by applying to EN pin again or releasing UVLO again. The protection sequence example is as follows. (D) EN EN2 30 ms RESET (A) < 1 ms FB1 1.0 V 0.5 V Ground-short cancel 0.94 ms VIN PCNT DIS (3.3 V line) 3.3 V (B) 1.8 V 1 ms FB2 (C) Ground-short release 1 ms 3.75 ms 4.22 ms BUF Normal operation Protection operation Normal operation (Start sequence) In (A) of the above figure, DCDC1 output shorts to GND. However, this LSI doesn't shift to protection sequence because the term of ground-short is 1 ms or shorter. In (B) of the above figure, DCDC2 output shorts to GND. After ground-short state continues for 1 ms, this LSI shifts to protection sequence, DCDC1, DCDC2 and external Pch-MOSFET gate drive circuits shift to OFF state, and BUF shifts to OFF state after another 1 ms and are latched. Even if ground-short is released, the operation of each circuit does not recover (C). During the protection sequence, RESET pin is not set to Low. In (D) of the above figure, they recover to normal start sequence after EN is input again. 16 Ver. BEB AN30185A OPERATION (Continued) 3. Protection Note) The characteristics listed below are reference values derived from the design of the IC and are not guaranteed. VREG pin Ground Short Operation VREG pin is an output pin of LDO used in internal circuits. The operation of each function stops just after VREG pin Is shorted to GND. Since each function is not latched unlike the case of [3.Protection : Protection sequence], it recovers by the release of ground-short. The operation is as follows. Ground-short Ground-short release 2.55 V VREG 2.1 V 30 ms RESET FB1 1.0 V 0.94 ms VIN PCNT 3.3 V DIS (3.3 V line) PCNTB 3.75 ms 1.8 V FB2 4.22 ms BUF Normal operation OFF state 17 Normal operation (Start sequence) Ver. BEB AN30185A TYPICAL CHARACTERISTICS CURVES (1) Output ripple voltage VIN = 3.3 V , Cout = 10 μF ( GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) DC-DC1 DC-DC2 Iout1 = 10 mA LX1 LX2 Vout1 Vout2 DC-DC1 Iout2 = 10 mA DC-DC2 Iout1 = 450 mA Iout2 = 500 mA LX1 LX2 Vout1 Vout2 18 Ver. BEB AN30185A TYPICAL CHARACTERISTICS CURVES (Continued) (1) Output ripple voltage VIN = 5.0 V , Cout = 10 μF ( GRM21BB31A106K[Murata] ) , L = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) DC-DC2 DC-DC1 Iout1 = 10 mA Iout2 = 10 mA LX2 LX1 Vout1 Vout2 DC-DC2 DC-DC1 Iout1 = 450 mA Iout2 = 500 mA LX1 LX2 Vout1 Vout2 19 Ver. BEB AN30185A TYPICAL CHARACTERISTICS CURVES (Continued) (2) Load transient response VIN = 3.3 V , Cout = 10 μF ( GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) DC-DC1 DC-DC2 Iout1 = 50 mA to 200 mA , Δ t = 1 μsec Iout1 Iout2 = 10 mA to 250 mA , Δ t = 1 μsec Iout2 LX1 LX2 Vout2 Vout1 DC-DC1 DC-DC2 Iout1 = 200 mA to 50 mA , Δ t = 1 μsec Iout2 = 250 mA to 10 mA , Δ t = 1 μsec Iout2 Iout1 LX1 LX2 Vout1 Vout2 20 Ver. BEB AN30185A TYPICAL CHARACTERISTICS CURVES (Continued) (2) Load transient response VIN = 5.0 V , Cout = 10 μF ( GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) DC-DC1 DC-DC2 Iout1 = 50 mA to 200 mA , Δ t = 1 μsec Iout1 Iout2 = 10 mA to 250 mA , Δ t = 1 μsec Iout2 LX1 LX2 Vout2 Vout1 DC-DC1 DC-DC2 Iout1 = 200 mA to 50 mA , Δ t = 1 μsec Iout2 = 250 mA to 10 mA , Δ t = 1 μsec Iout1 Iout2 LX1 LX2 Vout1 Vout2 21 Ver. BEB AN30185A TYPICAL CHARACTERISTICS CURVES (Continued) (3) Efficiency VIN = 3.3 V or 5.0V , Cout = 10 μF ( GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) DC-DC2 㪐㪇 㪈㪇㪇 㪏㪌 㪐㪌 㪏㪇 㪐㪇 㪎㪌 㪏㪌 㪼㪽㪽㫀㪺㫀㪼㫅㪺㫐㩷㪲㩼㪴 㪼㪽㪽㫀㪺㫀㪼㫅㪺㫐㩷㪲㩼㪴 DC-DC1 㪎㪇 㪍㪌 㪍㪇 㪏㪇 㪎㪌 㪎㪇 㪍㪌 㪌㪌 㪭㪠㪥㪔㪊㪅㪊㪭 㪭㪠㪥㪔㪌㪭 㪌㪇 㪭㪠㪥㪔㪊㪅㪊㪭 㪭㪠㪥㪔㪌㪭 㪍㪇 㪌㪌 㪋㪌 㪌㪇 㪋㪇 㪈 㪈㪇 㪈㪇㪇 㪈 㪈㪇㪇㪇 㪈㪇 㪈㪇㪇 㪈㪇㪇㪇 㫃㫆㪸㪻㩷㪺㫌㫉㫉㪼㫅㫋㩷㪲㫄㪘㪴 㫃㫆㪸㪻㩷㪺㫌㫉㫉㪼㫅㫋㩷㪲㫄㪘㪴 (4) Load regulation VIN = 3.3 V or 5.0V , Cou t= 10 μF ( GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) DC-DC2 DC-DC1 㪈㪅㪉 㪉 㪈㪅㪈㪌 㪈㪅㪐㪌 㪭㪠㪥㪔㪊㪅㪊㪭 㪭㪠㪥㪔㪌㪭 㪭㪠㪥㪔㪊㪅㪊㪭 㪭㪠㪥㪔㪌㪭 㪈㪅㪐 㫆㫌㫋㫇㫌㫋㩷㫍㫆㫃㫋㪸㪾㪼㩷㪲㪭㪴 㫆㫌㫋㫇㫌㫋㩷㫍㫆㫃㪸㫋㪾㪼㩷㪲㪭㪴 㪈㪅㪈 㪈㪅㪇㪌 㪈 㪇㪅㪐㪌 㪈㪅㪏㪌 㪈㪅㪏 㪈㪅㪎㪌 㪇㪅㪐 㪈㪅㪎 㪇㪅㪏㪌 㪈㪅㪍㪌 㪇㪅㪏 㪈㪅㪍 㪇 㪈㪇㪇 㪉㪇㪇 㪊㪇㪇 㪋㪇㪇 㪌㪇㪇 㪍㪇㪇 㪎㪇㪇 㪏㪇㪇 㪇 㪈㪇㪇 㪉㪇㪇 㪊㪇㪇 㫃㫆㪸㪻㩷㪺㫌㫉㫉㪼㫅㫋㩷㪲㫄㪘㪴 㪋㪇㪇 㪌㪇㪇 㪍㪇㪇 㪎㪇㪇 㪌 㪌㪅㪌 㪏㪇㪇 㫃㫆㪸㪻㩷㪺㫌㫉㫉㪼㫅㫋㩷㪲㫄㪘㪴 (5) Line regulation Cout = 10 μF ( GRM21BB31A106K[Murata] ) , Lout = 2.2 μH ( NR3012T2R2M[Taiyo Yuden] ) DC-DC2 DC-DC1 㪉 㪈㪅㪉 㪈㪅㪈㪌 㪈㪅㪐㪌 㪠㫃㫆㪸㪻㪔㪋㪌㪇㫄㪘 㪠㫃㫆㪸㪻㪔㪏㪇㪇㫄㪘 㪦㫌㫋㫇㫌㫋㩷㪭㫆㫃㫋㪸㪾㪼㩷㪲㪭㩷㪴 㪦㫌㫋㫇㫌㫋㩷㪭㫆㫃㫋㪸㪾㪼㩷㪲㪭㩷㪴 㪠㫃㫆㪸㪻㪔㪌㪇㪇㫄㪘 㪠㫃㫆㪸㪻㪔㪏㪇㪇㫄㪘 㪈㪅㪐 㪈㪅㪈 㪈㪅㪇㪌 㪈 㪇㪅㪐㪌 㪈㪅㪏㪌 㪈㪅㪏 㪈㪅㪎㪌 㪇㪅㪐 㪈㪅㪎 㪇㪅㪏㪌 㪈㪅㪍㪌 㪈㪅㪍 㪇㪅㪏 㪉㪅㪌 㪊 㪊㪅㪌 㪋 㪋㪅㪌 㪌 㪌㪅㪌 㪉㪅㪌 㪍 㪊 㪊㪅㪌 㪋 㪋㪅㪌 㪍 㪠㫅㫇㫌㫋㩷㪭㫆㫃㫋㪸㪾㪼㩷㪲㪭㩷㪴 㪠㫅㫇㫌㫋㩷㪭㫆㫃㫋㪸㪾㪼㩷㪲㪭㩷㪴 22 Ver. BEB AN30185A APPLICATIONS INFORMATION 1. Application circuit 3.3V 3.3V R-RST EN PVIN1 EN2 RESET PVIN1 U1 DIS C-PVIN1 FB1 LX1 PVIN2 PVIN2 C-PVIN2 VOUT1 L-OUT1 C-OUT1 AN30185A FB2 LX2 AVIN AVIN C-PAIN PCNT VOUT2 L-OUT2 C-OUT2 BUF VREG AGND1 AGND2 PGND1 PGND2 C-BUF C-VREG 2. Layout of Evaluation Board Figure : Bottom Layer with silk screen ( Bottom View )with Evaluation board Figure : Top Layer with silk screen ( Top View ) with Evaluation board Notes) This application circuit and layout is an example. The operation of mass production set is not guaranteed. You should perform enough evaluation and verification on the design of mass production set. You are fully responsible for the incorporation of the above application circuit and information in the design of your equipment. 23 Ver. BEB AN30185A APPLICATIONS INFORMATION (Continued) 3. Recommended Component Reference Designator QTY Value Manufacturer Part Number C-PVIN1 1 4.7 μF Murata GRM21BB31A475KA74L C-PVIN2 1 4.7 μF Murata GRM21BB31A475KA74L CAVIN 1 4.7 μF Murata GRM21BB31A475KA74L C-VREG 1 1 μF Murata GRM155B31A105KE15D C-BUF 1 1 μF Murata GRM155B31A105KE15D C-VOUT1 1 10 μF Murata GRM21BB31A106KE18L C-VOUT2 1 10 μF Murata GRM21BB31A106KE18L L-OUT1 1 2.2 μH TAIYO YUDEN NR3012T2R2M L-OUT2 1 2.2 μH TAIYO YUDEN NR3012T2R2M U1 1 — Panasonic MTM76111 R-RST 1 10 KΩ Panasonic ERA3ARW103V 24 Ver. BEB AN30185A PACKAGE INFORMATION (Reference Data) Package Code : HQFN024-P-0404 Unit:mm Br / Sb Free Body Material : Epoxy Resin Lead Material : Cu Alloy Lead Finish Method : Au Plating 25 Ver. BEB AN30185A IMPORTANT NOTICE 1.The products and product specifications described in this book are subject to change without notice for modification and/or improvement. At the final stage of your design, purchasing, or use of the products, therefore, ask for the most up-to-date Product Standards in advance to make sure that the latest specifications satisfy your requirements. 2.When using the LSI for new models, verify the safety including the long-term reliability for each product. 3.When the application system is designed by using this LSI, be sure to confirm notes in this book. Be sure to read the notes to descriptions and the usage notes in the book. 4.The technical information described in this book is intended only to show the main characteristics and application circuit examples of the products. No license is granted in and to any intellectual property right or other right owned by Panasonic Corporation or any other company. Therefore, no responsibility is assumed by our company as to the infringement upon any such right owned by any other company which may arise as a result of the use of technical information de-scribed in this book. 5.This book may be not reprinted or reproduced whether wholly or partially, without the prior written permission of our company. 6.This LSI is intended to be used for general electronic equipment. Consult our sales staff in advance for information on the following applications: Special applications in which exceptional quality and reliability are required, or if the failure or malfunction of this LSI may directly jeopardize life or harm the human body. Any applications other than the standard applications intended. (1) Space appliance (such as artificial satellite, and rocket) (2) Traffic control equipment (such as for automobile, airplane, train, and ship) (3) Medical equipment for life support (4) Submarine transponder (5) Control equipment for power plant (6) Disaster prevention and security device (7) Weapon (8) Others : Applications of which reliability equivalent to (1) to (7) is required It is to be understood that our company shall not be held responsible for any damage incurred as a result of or in connection with your using the LSI described in this book for any special application, unless our company agrees to your using the LSI in this book for any special application. 7.This LSI is neither designed nor intended for use in automotive applications or environments unless the specific product is designated by our company as compliant with the ISO/TS 16949 requirements. Our company shall not be held responsible for any damage incurred by you or any third party as a result of or in connection with your using the LSI in automotive application, unless our company agrees to your using the LSI in this book for such application. 8.If any of the products or technical information described in this book is to be exported or provided to non-residents, the laws and regulations of the exporting country, especially, those with regard to security export control, must be observed. 9. Please use this product in compliance with all applicable laws and regulations that regulate the inclusion or use of controlled substances, including without limitation, the EU RoHS Directive. Our company shall not be held responsible for any damage incurred as a result of your using the LSI not complying with the applicable laws and regulations. 26 Ver. BEB AN30185A USAGE NOTES 1. When designing your equipment, comply with the range of absolute maximum rating and the guaranteed operating conditions (operating power supply voltage and operating environment etc.). Especially, please be careful not to exceed the range of absolute maximum rating on the transient state, such as power-on, power-off and mode-switching. Otherwise, we will not be liable for any defect which may arise later in your equipment. Even when the products are used within the guaranteed values, take into the consideration of incidence of break down and failure mode, possible to occur to semiconductor products. Measures on the systems such as redundant design, arresting the spread of fire or preventing glitch are recommended in order to prevent physical injury, fire, social damages, for example, by using the products. 2. Comply with the instructions for use in order to prevent breakdown and characteristics change due to external factors (ESD, EOS, thermal stress and mechanical stress) at the time of handling, mounting or at customer's process. When using products for which damp-proof packing is required, satisfy the conditions, such as shelf life and the elapsed time since first opening the packages. 3. Pay attention to the direction of LSI. When mounting it in the wrong direction onto the PCB (printed-circuit-board), it might smoke or ignite. 4. Pay attention in the PCB (printed-circuit-board) pattern layout in order to prevent damage due to short circuit between pins. In addition, refer to the Pin Description for the pin configuration. 5. Perform a visual inspection on the PCB before applying power, otherwise damage might happen due to problems such as a solder-bridge between the pins of the semiconductor device. Also, perform a full technical verification on the assembly quality, because the same damage possibly can happen due to conductive substances, such as solder ball, that adhere to the LSI during transportation. 6. Take notice in the use of this product that it might break or occasionally smoke when an abnormal state occurs such as output pin-VCC short (Power supply fault), output pin-GND short (Ground fault), or output-to-output-pin short (load short) . And, safety measures such as an installation of fuses are recommended because the extent of the abovementioned damage and smoke emission will depend on the current capability of the power supply. 7. The protection circuit is for maintaining safety against abnormal operation. Therefore, the protection circuit should not work during normal operation. Especially for the thermal protection circuit, if the area of safe operation or the absolute maximum rating is momentarily exceeded due to output pin to VCC short (Power supply fault), or output pin to GND short (Ground fault), the LSI might be damaged before the thermal protection circuit could operate. 8. Unless specified in the product specifications, make sure that negative voltage or excessive voltage are not applied to the pins because the device might be damaged, which could happen due to negative voltage or excessive voltage generated during the ON and OFF timing when the inductive load of a motor coil or actuator coils of optical pick-up is being driven. 9. The product which has specified ASO (Area of Safe Operation) should be operated in ASO 10. Verify the risks which might be caused by the malfunctions of external components. 11. Connect the metallic plates on the back side of the LSI with their respective potentials (AGND, PVIN, LX). The thermal resistance and the electrical characteristics are guaranteed only when the metallic plates are connected with their respective potentials. 27 Ver. BEB Request for your special attention and precautions in using the technical information and semiconductors described in this book (1) If any of the products or technical information described in this book is to be exported or provided to non-residents, the laws and regulations of the exporting country, especially, those with regard to security export control, must be observed. (2) The technical information described in this book is intended only to show the main characteristics and application circuit examples of the products. No license is granted in and to any intellectual property right or other right owned by Panasonic Corporation or any other company. Therefore, no responsibility is assumed by our company as to the infringement upon any such right owned by any other company which may arise as a result of the use of technical information described in this book. (3) The products described in this book are intended to be used for general applications (such as office equipment, communications equipment, measuring instruments and household appliances), or for specific applications as expressly stated in this book. Consult our sales staff in advance for information on the following applications: x Special applications (such as for airplanes, aerospace, automotive equipment, traffic signaling equipment, combustion equipment, life support systems and safety devices) in which exceptional quality and reliability are required, or if the failure or malfunction of the products may directly jeopardize life or harm the human body. It is to be understood that our company shall not be held responsible for any damage incurred as a result of or in connection with your using the products described in this book for any special application, unless our company agrees to your using the products in this book for any special application. (4) The products and product specifications described in this book are subject to change without notice for modification and/or improvement. At the final stage of your design, purchasing, or use of the products, therefore, ask for the most up-to-date Product Standards in advance to make sure that the latest specifications satisfy your requirements. (5) When designing your equipment, comply with the range of absolute maximum rating and the guaranteed operating conditions (operating power supply voltage and operating environment etc.). Especially, please be careful not to exceed the range of absolute maximum rating on the transient state, such as power-on, power-off and mode-switching. Otherwise, we will not be liable for any defect which may arise later in your equipment. Even when the products are used within the guaranteed values, take into the consideration of incidence of break down and failure mode, possible to occur to semiconductor products. Measures on the systems such as redundant design, arresting the spread of fire or preventing glitch are recommended in order to prevent physical injury, fire, social damages, for example, by using the products. (6) Comply with the instructions for use in order to prevent breakdown and characteristics change due to external factors (ESD, EOS, thermal stress and mechanical stress) at the time of handling, mounting or at customer's process. When using products for which damp-proof packing is required, satisfy the conditions, such as shelf life and the elapsed time since first opening the packages. (7) This book may be not reprinted or reproduced whether wholly or partially, without the prior written permission of our company. 20100202