Single-chip Type with Built-in FET Switching Regulator Series Output 1.5A or Less High Efficiency Step-down Switching Regulator with Built-in Power MOSFET BD9153MUV No.09027EAT40 ●Description ROHM’s high efficiency dual step-down switching regulators and Linear Regulator Controller, BD9153MUV is a power supply designed to produce a low voltage including 3.3,0.8 volts from 5.5/4.5 volts power supply line. Offers high efficiency with our original pulse skip control technology and synchronous rectifier. Employs a current mode control system to provide faster transient response to sudden change in load. ●Features 1) Offers fast transient response with current mode PWM control system. 2) Offers highly efficiency for all load range with synchronous rectifier (Pch/Nch FET) and SLLMTM (Simple Light Load Mode) 3) Incorporates Nch FET controller for Linear Regulator. 4) Incorporates reset function with 50ms counter. 5) Incorporates soft-start fanction, thermal protection and ULVO functions. 6) Incorporates short-current protection circuit with time delay function. 7) Incorporates shutdown function Icc=0µA(Typ.) 8) Employs small surface mount package : VQFN024V4040 ●Applications Power supply for LSI including DSP, Micro computer and ASIC ●Absolute Maximum Rating (Ta=25℃) Parameter Symbol Vcc,PVcc Voltage VCC,PVCC FB1,FB2,FB3,VS Voltage VFB1, VFB2, VFB3, VVS SW1,SW2,ITH1,ITH2 Voltage VSW1, VSW2, VITH1, V ITH2 EN,RST,DET,GATE Voltage V EN, V RST, V DET, V GATE Pd1 Pd2 Power Dissipation Pd3 Pd4 Operating Temperature Range Topr Storage Temperature Range Tstg Maximum Junction Temperature Tjmax *1 *2 *3 *4 *5 Unit V V V V W W W W ℃ ℃ ℃ Pd should not be exceeded. IC only 1-layer. mounted on a 74.2mm×74.2mm×1.6mm glass-epoxy board, occupied area by copper foil : 10.29mm2 4-layer. mounted on a 74.2mm×74.2mm×1.6mm glass-epoxy board, occupied area by copper foil : 10.29mm2 , in 1,4 layer, 5505mm2 in 2,3 layer 4-layer. mounted on a 74.2mm×74.2mm×1.6mm glass-epoxy board, occupied area by copper foil : 5505mm2, in each layers ●Operating Conditions (Ta=-40~+85℃) Parameter Vcc Voltage EN Voltage Output Voltage range SW Average Output Current *6 Limit -0.3~+7*1 -0.3~+7 -0.3~+7 -0.3~+7 2 0.34* 0.69 *3 2.20 *4 3.56*5 -40~+85 -55~+150 +150 Symbol VCC VEN VOUT1 VOUT2 VOUT3 ISW1 ISW2 Min. 4.5 0 1.8 0.8 0.8 - Typ. 5.0 - Max. 5.5 5.5 3.3 2.5 2.5 1.5*6 1.5*6 Unit V V V V V A A Pd should not be exceeded. www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 1/18 2009.08 - Rev.A Technical Note BD9153MUV ●Electrical Characteristics ◎(Ta=25℃ VCC=5V, EN=VCC ,unless otherwise specified.) Parameter Standby Current Bias Current EN Low Voltage EN High Voltage EN Input Current Oscillation Frequency Pch FET ON Resistance Nch FET ON Resistance FB Reference Voltage ITH sink curren1 ITH source current 1 ITH sink curren2 ITH source current 2 UVLO Threshold Voltage1 UVLO Release Voltage1 UVLO Threshold Voltage2 UVLO Release Voltage2 VS Discharge Resistance Soft Start Time Timer Latch Time Output Short circuit Threshold Voltage RST Release Voltage RST threshold Voltage RST Delay RST ON Reststance GATE Source Current GATE Sink Current www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. Symbol ISTB ICC VENL VENH IEN FOSC RONP1 RONP2 RONN1 RONN2 VFB1,2 VFB3 VFB3 ITHSI1 ITHSO1 ITHSI2 ITHSO2 VUVLOL1 VUVLOH1 VUVLOL2 VUVLOH2 RVS TSS TLATCH VSCP1 VSCP2 VSCP3 VRST1 VRST2 TRST RONRST IGSO IGSI Min. 2 0.8 0.788 0.784 0.780 10 10 10 10 3.6 3.65 2.4 2.425 0.4 1.0 0.691 0.668 40 0.5 1.0 2/18 Limit Typ. 0 600 GND Vcc 2 1.0 0.17 0.17 0.13 0.13 0.8 0.8 0.8 18 18 18 18 3.8 3.9 2.5 2.55 40 0.8 2.0 0.4 0.4 0.4 0.720 0.696 50 140 1.5 5.0 Max. 10 1000 0.8 10 1.2 0.3 0.3 0.2 0.2 0.812 0.816 0.820 4.0 4.2 2.6 2.7 80 1.6 4.0 0.56 0.56 0.56 0.749 0.724 60 280 - Unit µA µA V V µA MHz Ω Ω Ω Ω V V V µA µA µA µA V V V V Ω ms ms V V V V V ms Ω mA mA Condition EN=0V Standby Mode Active Mode EN=2V Vcc=5V Vcc=5V Vcc=5V Vcc=5V ±1.5% ±2.0%(Ta=25℃) ±2.5%(Ta=-40~+85℃) VFB1=1.0V VFB1=0.6V VFB2=1.0V VFB2=0.6V Vcc=5→0V Vcc=0→5V Vcc=5→0V Vcc=0→5V Vcc=5V SCP/TSD ON FB1=0.8→0V FB2=0.8→0V FB3=0.8→0V DET=0V→0.8V DET=0.8V→0V VFB3=0.6V , VGATE=2.5V VFB3=1.0V , VGATE=2.5V 2009.08 - Rev.A Technical Note BD9153MUV ●Block Diagram, Application Circuit 4.0±0.1 PVCC OUT1 Current Comp 4.0±0.1 FB1 R Gm Amp D9153 Q Sense/ Slope1 EN SW1 Protect S Lot No. Soft Start1 Driver 1.0Max. Logic 0.02 +0.03 -0.02 (0.22) CLK1 VREF 24 12 13 18 0.75 0.5 UVLO2 CLK2 PVCC SCP2 7 19 UVLO1 SCP/ TSD OSC 6 2.4±0.1 1 PGND1 SCP1 S C0.2 2.4±0.1 Current Current Comp OUT2 R Gm Amp FB2 Sense/ Q Protect S Soft Start2 OUT2 SW2 + Slope2 0.25 +0.05 -0.04 OUT1 + ITH1 0.08 S 0.4±0.1 Current Driver CLK2 Logic PGND2 ITH2 (Unit : mm) Soft Start1 Fig.1 BD9153MUV TOP View OUT1 GATE DET FB3 SCP3 OUT3 VS RST SCP/TSD UVLO1 ITH1 Timer FB1 AGND PGND1 Fig.2 BD9153MUV Block Diagram ●Pin No. & function table Pin No. Pin name Function Pin No. Pin name 1 PGND2 Nch FET Source pin (2CH) 13 GATE 2 PVCC2 Pch FET Source pin (2CH) 14 FB3 Function Gate drive pin Output Voltage3 detector pin 3 PVCC2 Pch FET Source pin (2CH) 15 AVCC 4 PVCC1 Pch FET Source pin (1CH) 16 DET Voltage detector pin 5 PVCC1 Pch FET Source pin (1CH) 17 RST RST signal output pin 6 PGND1 Nch FET Source pin (1CH) 18 AGND 7 PGND1 Nch FET Source pin (1CH) 19 ITH2 8 SW1 SW pin (1ch) 20 FB2 Output Voltage2 detector pin 9 SW1 SW pin (1ch) 21 EN Enable pin (High Active) 10 VS Discharge function pin 22 SW2 11 FB1 Output Voltage1 detector pin 23 SW2 12 ITH1 GmAmp1output pin 24 PGND2 www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 3/18 AVCC power supply input pin Ground GmAmp2 output pin SW pin (2ch) SW pin (2ch) Nch FET Source pin (2ch) 2009.08 - Rev.A Technical Note BD9153MUV ●Characteristics data【BD9153MUV】 3.0 【VOUT1=3.3V】 2.5 2.0 【VOUT2=1.2V】 1.5 1.0 0.5 【VOUT1=3.3V】 3.5 3.0 2.5 2.0 1.5 VCC=5V 【VOUT2=1.2V】 Ta=25℃ Io=0A 1.0 0.5 0.0 0.0 0 1 2 3 4 INPUT VOLTAGE:VCC[V] 1 Fig.3 VCC – VOUT1,VOUT2 VCC=5V Io=0A -20 0 20 40 60 TEMPERATURE:Ta[℃] 1.0 0.5 90 80 1.20 1.18 VCC=5V Io=0A 70 60 【VOUT1=3.3V】 50 40 【VOUT2=1.2V】 30 VCC=5V Ta=25℃ 20 10 -40 -20 0 20 40 60 TEMPERATURE:Ta[℃] 0 80 10 100 1000 OUTPUT CURRENT:IOUT[mA] Fig. 7 Ta-VOUT2 250 225 0.6 0.4 VCC=5V 1.1 ON RESISTANCE:RON[mΩ] FREQUENCY:FOSC[MHz] 0.8 10000 Fig.8 Efficiency 1.2 1.0 4 Fig.5 IOUT - VOUT 【VOUT2=1.2V設定】 【VOUT2=1.2V 】 Fig. 6 Ta-VOUT1 0.2 1 2 3 OUTPUT CURRENT:IOUT [A] 100 1.23 80 1.2 VCC=5V Ta=25℃ 【VOUT2=1.2V】 0 1.15 -40 1.5 5 EFFICIENCY:η[%] OUTPUT VOLTAGE:VOUT[V] OUTPUT VOLTAGE:VOUT[V] 3.25 3.20 FREQUENCY:FOSC[MHz] 2 3 4 EN VOLTAGE:VEN[V] 1.25 3.30 2.0 Fig.4 VEN - VOUT 3.40 3.35 2.5 0.0 0 5 【VOUT1=3.3V】 【VOUT1=3.3V】 3.0 OUTPUT VOLTAGE:VOUT[V] Ta=25℃ Io=1.5A OUTPUT VOLTAGE:VOUT[V] OUTPUT VOLTAGE:VOUT[V] 3.5 4.0 3.5 1 0.9 Ta=25℃ VCC=5V 200 PMOS 175 150 125 NMOS 100 75 50 25 0.8 0.0 -40 -20 0 20 40 60 0 4.5 80 TEMPERATURE:Ta[℃] 4.75 5 5.25 INPUT VOLTAGE:VCC[V] Fig.9 Ta- Fosc 5.5 -40 Fig.10 VCC-Fosc 0 20 40 60 80 TEMPERATURE:Ta[℃] 100 Fig.11 Ta – RONN, RONP 600 2.0 CIRCUIT CURRENT:ICC[μA] 1.8 1.6 EN VOLTAGE:VEN[V] -20 1.4 1.2 1.0 0.8 0.6 VCC=5V 0.4 VCC=5V,Ta=25℃ 500 EN 400 VOUT1 300 VOUT1 200 VOUT2 VCC=5V 100 0.2 VOUT3 0 0.0 -40 -20 0 20 40 60 TEMPERATURE:Ta[℃] Fig.12 Ta-EN www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 80 EN1=E2 -40 -20 0 20 40 60 VOUT2 VCC=5.0V Ta=25℃ 80 TEMPERATURE:Ta[℃] Fig.13 Ta-Icc 4/18 Fig.14 Soft start wave form (Io1=0mA, Io2=0mA, Io3=0mA) 2009.08 - Rev.A Technical Note BD9153MUV EN SW1 SW1 VOUT1 VOUT2 VOUT1 VCC=5.0V Ta=25℃ VOUT3 VOUT1 VCC=5.0V,Vout1=3.3V Ta=25℃ VCC=5.0V,Vout1=3.3V Ta=25℃ Fig.16 SW1 wave form (Io1=0mA) Fig.15 Soft start wave form (Io1=1.5A, Io2=1.5A, Io3=1.0A) Fig.17 SW1 wave form (Io1=1.5A) SW2 SW2 VOUT1 VOUT2 VOUT2 IOUT1 VCC=5.0V,Vout2=1.2V Ta=25℃ VCC=5.0V,Vout2=1.2V Ta=25℃ VCC=5.0V,Vout1=3.3V Ta=25℃ Fig.19 SW2 wave form (Io2=1.5A) Fig.18 SW2 wave form (Io2=0mA) Fig.20 VOUT1 transient responce (Io10.5A→1.5A / 10usec) VOUT1 VOUT2 VOUT2 IOUT1 IOUT2 IOUT2 VCC=5.0V,Vout1=3.3V Ta=25℃ VCC=5.0V,Vout2=1.2V Ta=25℃ Fig.21 VOUT1 transient responce (Io11.5A→0.5A/ 10usec) Fig.22 VOUT2 transient responce (Io20.5A→1.5A/ 10usec) VOUT3 VOUT3 IOUT3 IOUT3 VCC=5.0V,Vout3=2.5V Ta=25℃ Fig.24 VOUT3 transient responce (Io30.5A→1A/ 10usec) www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. VCC=5.0V,Vout2=1.2V Ta=25℃ Fig.23 VOUT2 transient responce (Io21.5A→0.5A/ 10usec) VCC=5.0V,Vout3=2.5V Ta=25℃ Fig.25 VOUT3 transient responce (Io3500mA→1A/ 10usec) 5/18 2009.08 - Rev.A Technical Note BD9153MUV ●Information on advantages Advantage 1:Offers fast transient response with current mode control system. BD9153MUV (Load response IO=1.5A→0.5A / usec) BD9153MUV (Load response IO=0.5A→1.5A / usec) VOUT1 VOUT1 Io1 Io1 Fig.26 Advantage 2: Offers high efficiency for all load range. ・For lighter load: Utilizes the current mode control mode called SLLM for lighter load, which reduces various dissipation such as switching dissipation (PSW), gate charge/discharge dissipation, ESR dissipation of output capacitor (PESR) and on-resistance dissipation (PRON) that may otherwise cause degradation in efficiency for lighter load. Achieves efficiency improvement for lighter load. ・For heavier load: Utilizes the synchronous rectifying mode and the low on-resistance MOS FETs incorporated as power transistor. Achieves efficiency improvement for heavier load. 100 Efficiency η[%] ON resistance of Highside MOS FET : 170mΩ(Typ.) ON resistance of Lowside MOS FET : 130mΩ(Typ.) SLLMTM ② 50 ① PWM ①inprovement by SLLM system ②improvement by synchronous rectifier 0 0.001 0.01 0.1 Output current Io[A] 1 Offers high efficiency for all load range with the improvements mentioned above. Fig.27 Efficiency www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 6/18 2009.08 - Rev.A Technical Note BD9153MUV Advantage 3:・Supplied in smaller package due to small-sized power MOS FET incorporated. ・Output capacitor Co required for current mode control: 22μF ceramic capacitor ・Inductance L required for the operating frequency of 1 MHz: 2.2μH inductor ・Incorporates FET + Boot strap diode Reduces a mounting area required. R5 Cfb R6 R9 CITH2 RITH2 L2 R4 CO2 AGND ITH2 RST COUT2 COUT1 M1 DET AVCC FB3 GATE ITH1 FB2 FB1 EN VS SW2 SW 1 SW2 SW1 CIN1 50mm R2 RITH2 RITH1 R1 L1 CO1 PGND1 R4 R3 R8 CITH1 R9 R2 R1 PGND2 PVCC2 PVCC2 PVCC1 PVCC1 PGND1 R5 C1 R6 COUT3 CIN2 CIN2 RITH1 CITH1 M1 PGND2 R3 50mm CO3 R7 CIN1 R8 R7 Fig.28 www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 7/18 2009.08 - Rev.A Technical Note BD9153MUV ●Operation BD9153MUV is a synchronous rectifying step-down switching regulator that achieves faster transient response by employing current mode PWM control system. It utilizes switching operation in PWM (Pulse Width Modulation) mode for heavier load, while it utilizes SLLM (Simple Light Load Mode) operation for lighter load to improve efficiency. ○Synchronous rectifier It does not require the power to be dissipated by a rectifier externally connected to a conventional DC/DC converter IC, and its P.N junction shoot-through protection circuit limits the shoot-through current during operation, by which the power dissipation of the set is reduced. ○Current mode PWM control Synthesizes a PWM control signal with a inductor current feedback loop added to the voltage feedback. ・PWM (Pulse Width Modulation) control The oscillation frequency for PWM is 1 MHz. SET signal form OSC turns ON a highside MOS FET (while a lowside MOS FET is turned OFF), and an inductor current IL increases. The current comparator (Current Comp) receives two signals, a current feedback control signal (SENSE: Voltage converted from IL) and a voltage feedback control signal (FB), and issues a RESET signal if both input signals are identical to each other, and turns OFF the highside MOS FET (while a lowside MOS FET is turned ON) for the rest of the fixed period. The PWM control repeat this operation. TM ・SLLM (Simple Light Load Mode) control When the control mode is shifted from PWM for heavier load to the one for lighter load or vise versa, the switching pulse is designed to turn OFF with the device held operated in normal PWM control loop, which allows linear operation without voltage drop or deterioration in transient response during the mode switching from light load to heavy load or vise versa. Although the PWM control loop continues to operate with a SET signal from OSC and a RESET signal from Current Comp, it is so designed that the RESET signal is held issued if shifted to the light load mode, with which the switching is tuned OFF and the switching pulses are thinned out under control. Activating the switching intermittently reduces the switching dissipation and improves the efficiency. SENSE Current Comp RESET VOUT Level Shift R Q FB SET Gm Amp. ITH S IL Driver Logic VOUT SW Load OSC Fig.29 Diagram of current mode PWM control SENSE PVCC SENSE PVCC Current Comp SET FB GND Current Comp SET FB GND GND RESET GND RESET GND SW IL SW GND IL(AVE) IL 0A VOUT(AVE) VOUT VOUT VOUT(AVE) Not switching Fig.31 SLLM Fig.30 PWM switching timing chart www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 8/18 TM switching timing chart 2009.08 - Rev.A Technical Note BD9153MUV ●Description of operations ・Soft-start function EN terminal shifted to “High” activates a soft-starter to gradually establish the output voltage with the current limited during startup, by which it is possible to prevent an overshoot of output voltage and an inrush current. ・Shutdown function With EN terminal shifted to “Low”, the device turns to Standby Mode, and all the function blocks including reference voltage circuit, internal oscillator and drivers are turned to OFF. Circuit current during standby is 0µA (Typ.). ・RST function If DET voltage over 0.72V(Typ.), RST terminal shifted to “High” after 50ms(Typ.) delay. And the hysteresis width of 24mV (Typ.) is provided to prevent output chattering. ・UVLO function Detects whether the input voltage sufficient to secure the output voltage of BU9153MUV is supplied. And the hysteresis width of 100mV (UVLO1 Typ.) ,50mV(UVLO2 Typ.) is provided to prevent output chattering. Each the outputs have UVLO. It is possible to set output sequence easy. 4.5V detect (RST Release voltage ×6.25) 3.9V detect (UVLO Release voltage 1) 2.55V detect (UVLO Release voltage2) 4.35V (RST Threshold Voltage ×6.25) 3.8V (UVLO Threshold Voltage 1) VCC=EN 2.5V (UVLO Threshold Voltage 2) 3.3V Output (DC/DC 1) 2.5V Output (LDO) 1.2V Output (DC/DC 2) VS discharge ON RST Output Natural discharge 0.8ms Soft-start 50ms (RST Delay) RST Fig.32 Soft-start, Shutdown, RST Delay, UVLO, timing chart www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 9/18 2009.08 - Rev.A Technical Note BD9153MUV ・Short-current protection circuit with time delay function Turns OFF the output to protect the IC from breakdown when the incorporated current limiter is activated continuously for the fixed time(TLATCH) or more. The output thus held tuned OFF may be recovered by restarting EN or by re-unlocking UVLO. EN Output Short circuit Threshold Voltage OUT1 Output OFF Latch OUT2 OUT3 IL Limit Io1 Io2 Io3 t2<TLATCH t1<TLATCH Standby mode t3=TLATCH Standby mode Operating mode Timer latch EN Operating mode EN Fig.33 Short-current protection circuit with time delay timing chart ●Switching regulator efficiency Efficiency ŋ may be expressed by the equation shown below: η= VOUT×IOUT Vin×Iin ×100[%]= POUT Pin ×100[%]= POUT POUT+PDα ×100[%] Efficiency may be improved by reducing the switching regulator power dissipation factors PDα as follows: Dissipation factors: 2 1) ON resistance dissipation of inductor and FET:PD(I R) 2) Gate charge/discharge dissipation:PD(Gate) 3) Switching dissipation:PD(SW) 4) ESR dissipation of capacitor:PD(ESR) 5) Operating current dissipation of IC:PD(IC) 2 2 1)PD(I R)=IOUT ×(RCOIL+RON) (RCOIL[Ω]:DC resistance of inductor, RON[Ω]:ON resistance of FET, IOUT[A]:Output current.) 2)PD(Gate)=Cgs×f×V (Cgs[F]:Gate capacitance of FET, f[H]:Switching frequency, V[V]:Gate driving voltage of FET) 3)PD(SW)= Vin2×CRSS×IOUT×f IDRIVE (CRSS[F]:Reverse transfer capacitance of FET, IDRIVE[A]:Peak current of gate.) 2 4)PD(ESR)=IRMS ×ESR (IRMS[A]:Ripple current of capacitor, ESR[Ω]:Equivalent series resistance.) 5)PD(IC)=Vin×ICC (ICC[A]:Circuit current.) www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 10/18 2009.08 - Rev.A Technical Note BD9153MUV ●Consideration on permissible dissipation and heat generation As BU9153MUV functions with high efficiency without significant heat generation in most applications, no special consideration is needed on permissible dissipation or heat generation. In case of extreme conditions, however, including lower input voltage, higher output voltage, heavier load, and/or higher temperature, the permissible dissipation and/or heat generation must be carefully considered. For dissipation, only conduction losses due to DC resistance of inductor and ON resistance of FET are considered. Because the conduction losses are considered to play the leading role among other dissipation mentioned above including gate charge/discharge dissipation and switching dissipation. 4.0 2 ①3.56W Power dissipation : Pd [W] 3.0 ① 4 layers (copper foil area : 5505mm ) (Copper foil in each layers) θj-a=35.1℃/W 2 ② 4 layers (copper foil area : 10.29mm ) (Copper foil in 2nd and 3rd layers) θj-a=56.8℃/W 2 ③ 1 layer (Copper foil area : 0mm ) θj-a=181.2℃/W ④IC only θj-a=367.6℃/W P=IOUT2×RON RON=D×RONP+(1-D)RONN D:ON duty (=VOUT/VCC) RONH:ON resistance of Highside MOS FET RONL:ON resistance of Lowside MOS FET IOUT:Output current ②2.2W 2.0 1.0 ③0.69W ④0.34W 0 0 25 SW1 75 100 105 125 Ambient temperature :Ta [℃] 150 Fig.34 Thermal derating curve (VQFN024V4040) (Example) VCC=5V, VOUT1=3.3V, VOUT2=1.2V, RONH=170mΩ, RONL=130mΩ IOUT=1.5A, for example, D1=VOUT1/VCC=3.3/5=0.66 D2=VOUT2/VCC=1.2/5=0.24 RON1=0.66×0.170+(1-0.66)×0.130 =0.1122+0.0442 =0.1564[Ω] RON2=0.24×0.170+(1-0.24)×0.130 =0.0408+0.0988 =0.1397[Ω] 2 2 P=1.5 ×0.1564+1.5 ×0.1397=0.666[W] As RONH is greater than RONL in BU9153MUV, the dissipation increases as the ON duty becomes greater. With the consideration on the dissipation as above, thermal design must be carried out with sufficient margin allowed. www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 11/18 2009.08 - Rev.A Technical Note BD9153MUV ●Selection of components externally connected 1. Selection of inductor (L) The inductance significantly depends on output ripple current. As seen in the equation (1), the ripple current decreases as the inductor and/or switching frequency increases. IL ΔIL VCC ΔIL= IL (VCC-VOUT)×VOUT L×VCC×f [A]・・・(1) Appropriate ripple current at output should be 20% more or less of the maximum output current. VOUT L ΔIL=0.2×IOUTmax. [A]・・・(2) Co L= Fig.35 Output ripple current (VCC-VOUT)×VOUT ΔIL×VCC×f [H]・・・(3) (ΔIL: Output ripple current, and f: Switching frequency) ※Current exceeding the current rating of the inductor results in magnetic saturation of the inductor, which decreases efficiency. The inductor must be selected allowing sufficient margin with which the peak current may not exceed its current rating. If VCC=5.0V, VOUT=1.2V, f=1.0MHz, ΔIL=0.3×1.5A=0.45A, for example,(BD9153MUV) L= (5-1.2)×1.2 0.45×5×1.0M =2.02μ → 2.2[μH] ※Select the inductor of low resistance component (such as DCR and ACR) to minimize dissipation in the inductor for better efficiency. 2. Selection of output capacitor (CO) VCC Output capacitor should be selected with the consideration on the stability region and the equivalent series resistance required to smooth ripple voltage. VOUT L Output ripple voltage is determined by the equation (4): ESR ΔVOUT=ΔIL×ESR [V]・・・(4) Co (ΔIL: Output ripple current, ESR: Equivalent series resistance of output capacitor) Fig.36 Output capacitor www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. ※Rating of the capacitor should be determined allowing sufficient margin against output voltage. A 22µF to 100μF ceramic capacitor is recommended. Less ESR allows reduction in output ripple voltage. 12/18 2009.08 - Rev.A Technical Note BD9153MUV 3. Selection of input capacitor (Cin) VCC Input capacitor to select must be a low ESR capacitor of the capacitance sufficient to cope with high ripple current to prevent high transient voltage. ripple current IRMS is given by the equation (5): Cin VOUT L Co IRMS=IOUT× √VOUT(VCC-VOUT) VCC The [A]・・・(5) < Worst case > IRMS(max.) When Vcc=2×VOUT, IRMS = IOUT 2 If VCC=5.0V, VOUT=1.8V, and IOUTmax.=1.5A, (BD9153MUV) Fig.37 Input capacitor IRMS=2× √1.8(5.0-1.8) 5.0 = 0.48[ARMS] A low ESR 22µF/10V ceramic capacitor is recommended to reduce ESR dissipation of input capacitor for better efficiency. 4. Determination of RITH, CITH that works as a phase compensator As the Current Mode Control is designed to limit a inductor current, a pole (phase lag) appears in the low frequency area due to a CR filter consisting of a output capacitor and a load resistance, while a zero (phase lead) appears in the high frequency area due to the output capacitor and its ESR. So, the phases are easily compensated by adding a zero to the power amplifier output with C and R as described below to cancel a pole at the power amplifier. fp(Min.) A fp= fp(Max.) Gain [dB] 0 fz(ESR) IOUTMin. Phase [deg] IOUTMax. 0 1 2π×RO×CO 1 2π×ESR×CO Pole at power amplifier When the output current decreases, the load resistance Ro increases and the pole frequency lowers. fz(ESR)= -90 fp(Min.)= 1 [Hz]←with lighter load 2π×ROMax.×CO fp(Max.)= 1 2π×ROMin.×CO Fig.38 Open loop gain characteristics A fz(Amp.) Gain [dB] [Hz] ←with heavier load Zero at power amplifier Increasing capacitance of the output capacitor lowers the pole frequency while the zero frequency does not change. (This is because when the capacitance is doubled, the capacitor ESR reduces to half.) 0 0 Phase [deg] -90 fz(Amp.)= 1 2π×RITH×CITH Fig.39 Error amp phase compensation characteristics www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 13/18 2009.08 - Rev.A Technical Note BD9153MUV R5 Cfb R6 CO3 R9 CITH2 RITH2 AGND M1 RST DET AVCC FB3 GATE ITH2 ITH1 FB2 FB1 EN VS RITH1 CITH1 SW1 SW2 L2 R4 L1 SW2 CO2 SW1 PGND2 R3 CO1 R2 PGND1 PGND2 PVCC2 PVCC2 R1 PVCC1 PVCC1 PGND1 CIN2 CIN1 R8 R7 Fig.40 Typical application Stable feedback loop may be achieved by canceling the pole fp (Min.) produced by the output capacitor and the load resistance with CR zero correction by the error amplifier. fz(Amp.)= fp(Min.) 1 2π×RITH×CITH = 1 2π×ROMax.×CO 5. Determination of VOUT1~3 output voltage The output voltage VOUT1~3 is determined by the equation (6)~(8): VOUT1=(R2/R1+1)×VFB1・・・(6) VFB1: Voltage at FB terminal (0.8V Typ.) VOUT2=(R4/R3+1)×VFB2・・・(7) VFB2: Voltage at FB terminal (0.8V Typ.) VOUT3=(R6/R5+1)×VFB3・・・(8) VFB3: Voltage at FB terminal (0.8V Typ.) With R1~R6 adjusted, the output voltage may be determined as required. L1 VOUT1 SW1 FB1 Cout1 R2 R1 Fig.41 Determination of output voltage Use 1 kΩ~100 kΩ resistor for R1. If a resistor of the resistance higher than 100 kΩ is used, check the assembled set carefully for ripple voltage etc. www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 14/18 2009.08 - Rev.A Technical Note BD9153MUV ●BD9153MUV Cautions on PC Board layout Top Layer Silk screen Bottom Layer Fig.42 Layout diagram Lay out the input ceramic capacitor CIN closer to the pins PVCC and PGND, and the output capacitor Co closer to the pin PGND. Lay out CITH and RITH between the pins ITH and GND as neat as possible with least necessary wiring. ① ② ※ VQFN024V4040 (BD9153MUV) has thermal PAD on the reverse of the package. The package thermal performance may be enhanced by bonding the PAD to GND plane which take a large area of PCB. ●Recommended components Lists on above application Symbol Value Manufacturer Coil 2.2µH TDK CIN1,CIN2 Ceramic capacitor 22µF Murata GRM32EB11A226KE20 Cout1,Cout2 Ceramic capacitor Murata GRM31CB30J226KE18 CITH1 Ceramic capacitor VOUT1=3.3V 680pF Murata GRM18 Series RITH1 Resistance VOUT1=3.3V 39kΩ Rohm MCR03 Series CITH2 Ceramic capacitor VOUT2=1.2V 680pF Murata GRM18 Series RITH2 Resistance VOUT2=1.2V 12kΩ Rohm MCR03 Series 56pF Murata GRM18 Series - Rohm RTF015N03 L1,2 Part Cfb Ceramic capacitor M1 Nch MOS FET 22µF Series LTF5022-2R2N3R2 ※The parts list presented above is an example of recommended parts. Although the parts are sound, actual circuit characteristics should be checked on your application carefully before use. Be sure to allow sufficient margins to accommodate variations between external devices and BU9153MUV when employing the depicted circuit with other circuit constants modified. Both static and transient characteristics should be considered in establishing these margins. When switching noise is substantial and may impact the system, a low pass filter should be inserted between the VCC and PVCC pins, and a schottky barrier diode or snubber established between the SW and PGND pins. www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 15/18 2009.08 - Rev.A Technical Note BD9153MUV ●I/O equivalence circuit ・EN pin ・SW1,SW2 pin PVCC PVCC PVCC EN SW1,SW2 ・FB1,FB2,FB3,DET pin ・ITH1,ITH2 pin AVCC FB1,FB2,FB3,DET ITH1,ITH2 ・RST, VS pin ・GATE pin AVCC RST,VS GATE Fig.43 I/O equivalence circuit www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 16/18 2009.08 - Rev.A Technical Note BD9153MUV ●Notes for use 1. Absolute Maximum Ratings While utmost care is taken to quality control of this product, any application that may exceed some of the absolute maximum ratings including the voltage applied and the operating temperature range may result in breakage. If broken, short-mode or open-mode may not be identified. So if it is expected to encounter with special mode that may exceed the absolute maximum ratings, it is requested to take necessary safety measures physically including insertion of fuses. 2. Electrical potential at GND GND must be designed to have the lowest electrical potential In any operating conditions. 3. Short-circuiting between terminals, and mismounting When mounting to pc board, care must be taken to avoid mistake in its orientation and alignment. Failure to do so may result in IC breakdown. Short-circuiting due to foreign matters entered between output terminals, or between output and power supply or GND may also cause breakdown. 4. Thermal shutdown protection circuit Thermal shutdown protection circuit is the circuit designed to isolate the IC from thermal runaway, and not intended to protect and guarantee the IC. So, the IC the thermal shutdown protection circuit of which is once activated should not be used thereafter for any operation originally intended. 5. Inspection with the IC set to a pc board If a capacitor must be connected to the pin of lower impedance during inspection with the IC set to a pc board, the capacitor must be discharged after each process to avoid stress to the IC. For electrostatic protection, provide proper grounding to assembling processes with special care taken in handling and storage. When connecting to jigs in the inspection process, be sure to turn OFF the power supply before it is connected and removed. 6. Input to IC terminals + This is a monolithic IC with P isolation between P-substrate and each element as illustrated below. This P-layer and the N-layer of each element form a P-N junction, and various parasitic element are formed. If a resistor is joined to a transistor terminal as shown in Fig 44. ○P-N junction works as a parasitic diode if the following relationship is satisfied; GND>Terminal A (at resistor side), or GND>Terminal B (at transistor side); and ○if GND>Terminal B (at NPN transistor side), a parasitic NPN transistor is activated by N-layer of other element adjacent to the above-mentioned parasitic diode. The structure of the IC inevitably forms parasitic elements, the activation of which may cause interference among circuits, and/or malfunctions contributing to breakdown. It is therefore requested to take care not to use the device in such manner that the voltage lower than GND (at P-substrate) may be applied to the input terminal, which may result in activation of parasitic elements. Resistor Transistor (NPN) Pin A EN C B Pin B E Pin A N P + N P P N + N P substrate P+ Parasitic element P P C + N E P substrate GND Parasitic element B N GND Parasitic element GND GND Parasitic element Other adjacent elements Fig.44 Simplified structure of monorisic IC 7. Ground wiring pattern If small-signal GND and large-current GND are provided, It will be recommended to separate the large-current GND pattern from the small-signal GND pattern and establish a single ground at the reference point of the set PCB so that resistance to the wiring pattern and voltage fluctuations due to a large current will cause no fluctuations in voltages of the small-signal GND. Pay attention not to cause fluctuations in the GND wiring pattern of external parts as well. 8 . Selection of inductor It is recommended to use an inductor with a series resistance element (DCR) 0.15Ω or less. Note that use of a high DCR inductor will cause an inductor loss, resulting in decreased output voltage. Should this condition continue for a specified period (soft start time + timer latch time), output short circuit protection will be activated and output will be latched OFF. When using an inductor over 0.15Ω, be careful to ensure adequate margins for variation between external devices and BU9153MUV, including transient as well as static characteristics. www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. 17/18 2009.08 - Rev.A Technical Note BD9153MUV ●Ordering part number B D 9 Part No. 1 5 3 M Part No. U V - E 2 Packaging and forming specification Package MUV: VQFN24V4040 E2: Embossed tape and reel (VQFN24V4040) VQFN024V4040 <Tape and Reel information> 4.0±0.1 4.0±0.1 1.0MAX 2.4±0.1 0.4±0.1 7 12 19 18 0.5 The direction is the 1pin of product is at the upper left when you hold ( reel on the left hand and you pull out the tape on the right hand ) 6 24 0.75 E2 2.4±0.1 1 2500pcs (0.22) +0.03 0.02 -0.02 S C0.2 Embossed carrier tape Quantity Direction of feed 1PIN MARK 0.08 S Tape 13 +0.05 0.25 -0.04 1pin (Unit : mm) www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. Reel 18/18 Direction of feed ∗ Order quantity needs to be multiple of the minimum quantity. 2009.08 - Rev.A Notice Notes No copying or reproduction of this document, in part or in whole, is permitted without the consent of ROHM Co.,Ltd. The content specified herein is subject to change for improvement without notice. The content specified herein is for the purpose of introducing ROHM's products (hereinafter "Products"). If you wish to use any such Product, please be sure to refer to the specifications, which can be obtained from ROHM upon request. Examples of application circuits, circuit constants and any other information contained herein illustrate the standard usage and operations of the Products. The peripheral conditions must be taken into account when designing circuits for mass production. Great care was taken in ensuring the accuracy of the information specified in this document. However, should you incur any damage arising from any inaccuracy or misprint of such information, ROHM shall bear no responsibility for such damage. The technical information specified herein is intended only to show the typical functions of and examples of application circuits for the Products. ROHM does not grant you, explicitly or implicitly, any license to use or exercise intellectual property or other rights held by ROHM and other parties. ROHM shall bear no responsibility whatsoever for any dispute arising from the use of such technical information. The Products specified in this document are intended to be used with general-use electronic equipment or devices (such as audio visual equipment, office-automation equipment, communication devices, electronic appliances and amusement devices). The Products specified in this document are not designed to be radiation tolerant. While ROHM always makes efforts to enhance the quality and reliability of its Products, a Product may fail or malfunction for a variety of reasons. Please be sure to implement in your equipment using the Products safety measures to guard against the possibility of physical injury, fire or any other damage caused in the event of the failure of any Product, such as derating, redundancy, fire control and fail-safe designs. ROHM shall bear no responsibility whatsoever for your use of any Product outside of the prescribed scope or not in accordance with the instruction manual. The Products are not designed or manufactured to be used with any equipment, device or system which requires an extremely high level of reliability the failure or malfunction of which may result in a direct threat to human life or create a risk of human injury (such as a medical instrument, transportation equipment, aerospace machinery, nuclear-reactor controller, fuel-controller or other safety device). ROHM shall bear no responsibility in any way for use of any of the Products for the above special purposes. If a Product is intended to be used for any such special purpose, please contact a ROHM sales representative before purchasing. If you intend to export or ship overseas any Product or technology specified herein that may be controlled under the Foreign Exchange and the Foreign Trade Law, you will be required to obtain a license or permit under the Law. Thank you for your accessing to ROHM product informations. More detail product informations and catalogs are available, please contact us. ROHM Customer Support System http://www.rohm.com/contact/ www.rohm.com © 2009 ROHM Co., Ltd. All rights reserved. R0039A