Output 1.5A Less High-efficiency Step-down Switching Regulator with Bu
|
|
|
Top Searches for this datasheet
Single-chip Type with Built-in Switching Regulator Series
Output 1.5A Less High-efficiency Step-down Switching Regulator with Built-in Power MOSFET
BD9161FVM
No.09027EAT29
Description ROHM's high efficiency step-down switching regulator BD9161FVM power supply designed produce 1.2volts (low voltage) from 3.3volts power supply line. Offers high efficiency with original pulse skip control technology synchronous rectifier. Employs current mode control system provide faster transient response sudden change load. Features Offers fast transient response with current mode control system. Offers highly efficiency load range with synchronous rectifier (Nch/Pch FET) Incorporates 100% Duty function. Incorporates soft-start function. Incorporates thermal protection ULVO functions. Incorporates short-current protection circuit with time delay function. Incorporates shutdown function Icc=0A (Typ.) Employs small surface mount package MSOP8 Power supply HDD, CPU, ASIC Absolute Maximum Rating (Ta=25) Parameter voltage PVCC voltage Voltage Voltage Power Dissipation Power Dissipation Power Dissipation Power Dissipation voltage
Symbol PVCC SW,ITH Topr Tstg Tjmax
Rating -0.3+7 -0.3+7
Unit
-0.3+7 -0.3+7 387.5*2 587.4*3 -25+85 -55+150 +150
should exceeded. Derating done 3.1mW/ temperatures above Ta=25. Derating done 4.7mW/ temperatures above Ta=25,Mounted Glass Epoxy PCB.
Operating Conditions (Ta=25) Parameter voltage PVCC voltage voltage Output Voltage Setting Range average output current
should exceeded.
Symbol VCC*4 PVCC*4 SW,ITH Isw*4
Limits Min. Typ. Max.
Unit
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
1/13
2009.05 Rev.A
BD9161FVM
Electrical Characteristics (Ta=25, VCC=PVCC=3.3V, EN=VCC, unless otherwise specified.) Limits Parameter Symbol Min. Typ. Standby current ISTB Bias current voltage VENL High voltage VENH input current Oscillation frequency FOSC resistance RONP 0.35 resistance RONN 0.37 Output voltage VOUT 0.784 SInk current ITHSI Source Current ITHSO UVLO threshold voltage VUVLO1 UVLO hysteresis voltage VUVLO2 2.22 2.35 Soft start time Timer latch time TLATCH Output Short circuit Threshold Voltage VSCP
Technical Note
Max. 0.68 0.816 0.56
Unit
Conditions EN=GND Standby mode Active mode VEN=3.3V PVCC=3.3V PVCC=3.3V VOUT VOUT VCC=HL VCC=LH SCP/TSD operated VOUT
Block Diagram, Application Circuit
2.9±0.1
Max3.25(include.BURR)
0.29±0.15 0.6±0.2
VREF Current Comp. Amp. SLOPE Soft Start Current Sense/ Protect Driver Logic
3.3V Input
4.0±0.2
2.8±0.1
PVCC
0.475
0.9Max. 0.75±0.05 0.08±0.05
1PIN MARK
0.145 -0.03
+0.05
PGND
Output
+0.05 0.22 -0.04
UVLO
0.65
0.08
MSOP8 (Unit:mm)
Fig.1 BD9161FVM Dimension function table
Fig.2 BD9161FVM Block Diagram function Output voltage Feedback (Adjustable) GmAmp output pin/Connected phase compensation capacitor Enable (Active High) Ground source Pch/Nch drain output source power supply input
name PGND PVCC
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
1/13
2009.05 Rev.A
BD9161FVM
Characteristics data(Reference data)
Technical Note
OUTPUT VOLTAGE:VOUT[V]
OUTPUT VOLTAGE:VOUT[V]
OUTPUT VOLTAGE:VOUT[V]
VOUT=2.5V Ta=25 Io=0A
VOUT=2.5V
VOUT=2.5V
VCC=3.3V Ta=25 Io=0A
VOLTAGE:VEN[V]
VCC=3.3V Ta=25
OUTPUT CURRENT:IOUT
INPUT VOLTAGE:VCC[V]
Fig.3 Vcc-Vout
Fig.4 Ven-Vout
Fig.5 Iout-Vout
2.55 2.54
OUTPUT VOLTAGE:VOUT[V]
FREQUENCY:FOSC[MHz]
2.53 2.52 2.51 2.50 2.49 2.48 2.47 2.46 2.45
EFFICIENCY:[%]
VOUT=2.5V VCC=3.3V Io=0A
1.20 1.10 1.00 0.90 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10 0.00
OUTPUT CURRENT:IOUT[mA] 1000
VCC=3.3V VCC=3.3V
VOUT=2.5V VCC=3.3V Ta=25
TEMPERATURE:Ta[]
TEMPERATURE:Ta[]
Fig. Ta-VOUT
Fig.7 Efficiency
Fig.8 Fosc
0.40 0.35
VCC=3.3V
FREQUENCY:FOSC[MHz]
0.30 0.25 0.20 0.15 0.10 0.05 0.00
RESISTANCE:R
VOLTAGE:VEN[V]
VCC=3.3V PMOS NMOS
VCC=3.3V
VCC=3.3V
TEMPERATURE:Ta[]
TEMPERATURE:Ta[]
INPUT VOLTAGE:VCC
Fig.9 Ta-VEN
Fig.10 Ta-ICC
Fig.11 Vcc-Fosc
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
2/13
2009.05 Rev.A
BD9161FVM
Characteristics data(Reference data) Continued
Technical Note
VCC=PVCC
VOUT=2.5V
SLLMcontrol
VOUT=2.5V
control
VOUT=2.5V
VOUT VCC=3.3V Ta=25 Io=0A
VOUT VCC=3.3V Ta=25
VOUT VCC=3.3V Ta=25
Fig.12 Soft start waveform
Fig.13 waveform Io=10mA
Fig.14 waveform Io=500mA
100% Duty
VOUT=2.5V VOUT
VOUT=2.5V VOUT
VOUT=2.5V
VOUT VCC=2.7V Ta=25
IOUT
IOUT VCC=3.3V Ta=25 VCC=3.3V Ta=25
Fig. waveform Io=600mA
Fig. Transient response Io=250500mA(10s)
Fig.17 Transient response Io=500250mA(10s)
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
3/13
2009.05 Rev.A
BD9161FVM
Technical Note
Information advantages Advantage 1Offers fast transient response with current mode control system. Conventional product (VOUT which volts) BD9161FVM (Load response IO=250mA500mA)
VOUT VOUT 98mV 40mV
IOUT
IOUT
Voltage drop sudden change load reduced about 50%. Fig.18 Comparison transient response Advantage Offers high efficiency load range. lighter load: Utilizes current mode control mode called SLLM lighter load, which reduces various dissipation such switching dissipation (PSW), gate charge/discharge dissipation, dissipation output capacitor (PESR) on-resistance dissipation (PRON) that otherwise cause degradation efficiency lighter load.
Achieves efficiency improvement lighter load.
Efficiency
heavier load: Utilizes synchronous rectifying mode on-resistance FETs incorporated power transistor. resistance P-channel FET: 0.35 (Typ.) resistance N-channel FET: 0.37 (Typ.)
SLLM
inprovement SLLM
system
improvement synchronous rectifier
0.001
0.01 Output current Io[A]
Fig.19 Efficiency
Achieves efficiency improvement heavier load. Offers high efficiency load range with improvements mentioned above. Advantage Supplied smaller package small-sized power incorporated. Allows reduction size application products Output capacitor required current mode control: ceramic capacitor Inductance required operating frequency MHz: inductor Reduces mounting area required.
15mm DC/DC Convertor Controller RITH VOUT 10mm CITH
RITH CITH
Fig.20 Example application
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
4/13
2009.05 Rev.A
BD9161FVM
Technical Note
Operation BD9161FVM synchronous rectifying step-down switching regulator that achieves faster transient response employing current mode control system. utilizes switching operation (Pulse Width Modulation) mode heavier load, while utilizes SLLM (Simple Light Load Mode) operation lighter load improve efficiency. Current mode control Synthesizes control signal with inductor current feedback loop added voltage feedback. (Pulse Width Modulation) control oscillation frequency MHz. signal form turns P-channel (while N-channel turned OFF), inductor current increases. current comparator (Current Comp) receives signals, current feedback control signal (SENSE: Voltage converted from voltage feedback control signal (FB), issues RESET signal both input signals identical each other, turns P-channel (while N-channel turned rest fixed period. control repeats this operation.
SLLM (Simple Light Load Mode) control When control mode shifted from heavier load lighter load vise versa, switching pulse designed turn with device held operated normal control loop, which allows linear operation without voltage drop deterioration transient response during mode switching from light load heavy load vise versa. Although control loop continues operate with signal from RESET signal from Current Comp, designed that RESET signal held issued shifted light load mode, with which switching tuned switching pulses thinned under control. Activating switching intermittently reduces switching dissipation improves efficiency.
100% Duty control duty 100%. always usual control, case output voltage cannot keep (ex, drop input voltage), oscillation frequency becomes lower finally becomes 100% duty. output voltage value that depends only voltage hang from input voltage FET, keep output voltage even with input voltage.
SENSE Current Comp Level Shift Amp. RESET Driver Logic Load VOUT
VOUT
Fig.21 Diagram current mode control
Current Comp PVCC SENSE IL(AVE) Current Comp PVCC SENSE
RESET
RESET
VOUT
VOUT(AVE)
VOUT
VOUT(AVE)
switching
Fig.22 switching timing chart
Fig.23 SLLM
switching timing chart
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
5/13
2009.05 Rev.A
BD9161FVM
Technical Note
Description operations Soft-start function terminal shifted "High" activates soft-starter gradually establish output voltage with current limited during startup, which possible prevent overshoot output voltage inrush current. Shutdown function With terminal shifted "Low", device turns Standby Mode, function blocks including reference voltage circuit, internal oscillator drivers turned OFF. Circuit current during standby (Typ.). UVLO function Detects whether input voltage sufficient secure output voltage this supplied. hysteresis width (Typ.) provided prevent output chattering.
Hysteresis 50mV
VOUT
Soft start Standby mode Operating mode Standby mode UVLO
Operating mode
Standby mode
Operating mode
Standby mode
UVLO
UVLO
Fig.24 Soft start, Shutdown, UVLO timing chart
Short-current protection circuit with time delay function Turns output protect from breakdown when incorporated current limiter activated continuously fixed time (TLATCH) more. output thus held tuned recovered restarting re-unlocking UVLO.
Output latch VOUT Limit 1msec Standby mode Standby mode Timer latch
Operating mode
Operating mode
Fig.25 Short-current protection circuit with time delay timing chart
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
6/13
2009.05 Rev.A
BD9161FVM
Technical Note
Switching regulator efficiency Efficiency expressed equation shown below: POUT POUT POUT+PD Efficiency improved reducing switching regulator power dissipation factors follows: Dissipation factors: resistance dissipation inductor FETPD(I Gate charge/discharge dissipationPD(Gate) Switching dissipationPD(SW) dissipation capacitorPD(ESR) Operating current dissipation ICPD(IC) 1)PD(I R)=IOUT (RCOIL[]DC resistance inductor, RON[]ON resistance IOUT[A]Output current.) (Cgs[F]Gate capacitance FET, f[H]Switching frequency, V[V]Gate driving voltage FET) 3)PD(SW)= (CRSS[F]Reverse transfer capacitance FET, IDRIVE[A]Peak current gate.) IDRIVE 4)PD(ESR)=IRMS (IRMS[A]Ripple current capacitor, ESR[]Equivalent series resistance.) (ICC[A]Circuit current.) Consideration permissible dissipation heat generation this functions with high efficiency without significant heat generation most applications, special consideration needed permissible dissipation heat generation. case extreme conditions, however, including lower input voltage, higher output voltage, heavier load, and/or higher temperature, permissible dissipation and/or heat generation must carefully considered. dissipation, only conduction losses resistance inductor resistance considered. Because conduction losses considered play leading role among other dissipation mentioned above including gate charge/discharge dissipation switching dissipation.
1000 Power dissipation:Pd [mW]
587.4mW
Using alone j-a=322.6/W mounted glass epoxy j-a=212.8/W
duty (=VOUT/VCC) RONPON resistance P-channel RONNON resistance N-channel IOUTOutput current
387.5mW
Ambient temperature:Ta
Fig.26 Thermal derating curve (MSOP8) VCC=3.3V, VOUT=2.5V RONP=0.35, RONN=0.37 IOUT=0.6A, example, D=VOUT/VCC=2.5/3.3=0.758 =0.2653+0.08954 =0.35484[] P=0.6 127.7[mV] RONP greater than RONN this dissipation increases duty becomes greater. With consideration dissipation above, thermal design must carried with sufficient margin allowed.
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
7/13
2009.05 Rev.A
BD9161FVM
Selection components externally connected Selection inductor
Technical Note
inductance significantly depends output ripple current. seen equation (1), ripple current decreases inductor and/or switching frequency increases. [A](1) Appropriate ripple current output should 2030% more less maximum output current. [A](2) [H](3)
VOUT
Fig.27 Output ripple current
(IL: Output ripple current, Switching frequency)
Current exceeding current rating inductor results magnetic saturation inductor, which decreases efficiency. inductor must selected allowing sufficient margin with which peak current exceed current rating. VCC=3.3V, VOUT=2.5V, f=1MHz, 4.04 Select inductor resistance component (such ACR) minimize dissipation inductor better efficiency. Selection output capacitor (CO)
Output capacitor should selected with consideration stability region equivalent series resistance required smooth ripple voltage. Output ripple voltage determined equation
VOUT
[V](4) (IL: Output ripple current, ESR: Equivalent series resistance output capacitor) *Rating capacitor should determined allowing sufficient margin against output voltage. Less allows reduction output ripple voltage.
Fig.28 Output capacitor Inappropriate capacitance cause problem startup. 100F ceramic capacitor recommended.
Selection input capacitor (Cin)
Input capacitor select must capacitor capacitance sufficient cope with high ripple current prevent high transient voltage. ripple current IRMS given equation (5):
VOUT
OUT(VCC-VOUT)
[A](5) IOUT
Worst case IRMS(max.) When twice Vout, IRMS= Fig.29 Input capacitor
VCC=3.3V, VOUT=2.5V, IOUTmax.=0.6A 2.5(3.3-2.5) =0.284[ARMS] 10F/10V ceramic capacitor recommended reduce dissipation input capacitor better efficiency.
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
8/13
2009.05 Rev.A
BD9161FVM
Technical Note
Determination RITH, CITH that works phase compensator Current Mode Control designed limit inductor current, pole (phase lag) appears frequency area filter consisting output capacitor load resistance, while zero (phase lead) appears high frequency area output capacitor ESR. phases easily compensated adding zero power amplifier output with described below cancel pole power amplifier.
fp(Min.) Gain [dB] fp(Max.) IOUTMin. IOUTMax. fz(ESR)
fz(ESR)= Pole power amplifier When output current decreases, load resistance increases pole frequency lowers. fp(Min.)= [Hz]with lighter load [Hz]with heavier load
Phase [deg]
Fig.30 Open loop gain characteristics fp(Max.)=
Gain [dB] fz(Amp.)
Zero power amplifier Increasing capacitance output capacitor lowers pole frequency while zero frequency does change. (This because when capacitance doubled, capacitor reduces half.) fz(Amp.)=
Phase [deg]
Fig.31 Error phase compensation characteristics
VOUT VOUT RITH CITH
VCC,PVCC
VOUT
GND,PGND
Fig.32 Typical application Stable feedback loop achieved canceling pole (Min.) produced output capacitor load resistance with zero correction error amplifier. fz(Amp.)= fp(Min.)
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
9/13
2009.05 Rev.A
BD9161FVM
Determination output voltage output voltage VOUT determined equation (6): VADJ: Voltage terminal (0.8V Typ.) With adjusted, output voltage determined required. (Adjustable output voltage range 1.0V3.3V k100 resistor resistor resistance higher than used, check assembled carefully ripple voltage etc.
Technical Note
Output
Fig.33 Determination output voltage BD9161FVM Cautions Board layout
RITH CITH
PVCC PGND
VOUT
Fig.34 Board layout
sections drawn with heavy line, thick conductor pattern short possible. input ceramic capacitor closer pins PVCC PGND, output capacitor closer PGND. CITH RITH between pins neat possible with least necessary wiring.
Recommended component lists with above applications Symbol Part Value Coil Resistance Ceramic capacitor Ceramic capacitor Ceramic capacitor 4.7H VOUT=1.0V VOUT=1.2V VOUT=1.5V VOUT=1.8V VOUT=2.5V VOUT=1.0V VOUT=1.2V VOUT=1.5V VOUT=1.8V VOUT=2.5V
CITH
RITH
Resistance
820pF 560pF 470pF 470pF 330pF 6.8k 8.2k
Manufacturer Sumida ROHM Kyocera Kyocera murata murata murata murata murata ROHM ROHM ROHM ROHM ROHM
Series VLF5014AT-4R7M1R1 CMD6D11B MCR03 Series CM316X5R106K10A CM316X5R106K10A GRM18 Series GRM18 Series GRM18 Series GRM18 Series GRM18 Series MCR03 Series MCR03 Series MCR03 Series MCR03 Series MCR03 Series
parts list presented above example recommended parts. Although parts sound, actual circuit characteristics should checked your application carefully before use. sure allow sufficient margins accommodate variations between external devices this when employing depicted circuit with other circuit constants modified. Both static transient characteristics should considered establishing these margins. When switching noise substantial impact system, pass filter should inserted between PVCC pins, schottky barrier diode established between PGND pins.
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
10/13
2009.05 Rev.A
BD9161FVM
equivalence circuit
PVCC PVCC PVCC
Technical Note
Fig.36 equivalence circuit
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
11/13
2009.05 Rev.A
BD9161FVM
Technical Note
Cautions Absolute Maximum Ratings While utmost care taken quality control this product, application that exceed some absolute maximum ratings including voltage applied operating temperature range result breakage. broken, short-mode open-mode identified. expected encounter with special mode that exceed absolute maximum ratings, requested take necessary safety measures physically including insertion fuses. Electrical potential must designed have lowest electrical potential operating conditions. Short-circuiting between terminals, mismounting When mounting board, care must taken avoid mistake orientation alignment. Failure result breakdown. Short-circuiting foreign matters entered between output terminals, between output power supply also cause breakdown. 4.Operation Strong electromagnetic field noted that using strong electromagnetic radiation cause operation failures. Thermal shutdown protection circuit Thermal shutdown protection circuit circuit designed isolate from thermal runaway, intended protect guarantee thermal shutdown protection circuit which once activated should used thereafter operation originally intended. Inspection with board capacitor must connected lower impedance during inspection with board, capacitor must discharged after each process avoid stress electrostatic protection, provide proper grounding assembling processes with special care taken handling storage. When connecting jigs inspection process, sure turn power supply before connected removed. Input terminals This monolithic with isolation between P-substrate each element illustrated below. This P-layer N-layer each element form junction, various parasitic element formed. resistor joined transistor terminal shown junction works parasitic diode following relationship satisfied; GND>Terminal resistor side), GND>Terminal transistor side); GND>Terminal transistor side), parasitic transistor activated N-layer other element adjacent above-mentioned parasitic diode. structure inevitably forms parasitic elements, activation which cause interference among circuits, and/or malfunctions contributing breakdown. therefore requested take care device such manner that voltage lower than P-substrate) applied input terminal, which result activation parasitic elements.
Resistor
Transistor (NPN)
Parasitic element
substrate Parasitic element
substrate Parasitic element
Parasitic element
Other adjacent elements
Fig.37 Simplified structure monorisic Ground wiring pattern small-signal large-current provided, will recommended separate large-current pattern from small-signal pattern establish single ground reference point that resistance wiring pattern voltage fluctuations large current will cause fluctuations voltages small-signal GND. attention cause fluctuations wiring pattern external parts well.
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
12/13
2009.05 Rev.A
BD9161FVM
Ordering part number
Technical Note
Part
Part
Package FVM:MSOP8
Packaging forming specification Embossed tape reel (MSOP8)
MSOP8
<Tape Reel information>
2.9±0.1 (MAX 3.25 include BURR)
Tape
0.29±0.15 0.6±0.2
Embossed carrier tape 3000pcs
direction 1pin product upper right when hold
Quantity Direction feed
4.0±0.2
2.8±0.1
reel left hand pull tape right hand
1pin
1PIN MARK 0.475 +0.05 0.22 -0.04 0.08 0.65
+0.05 0.145 -0.03
0.9MAX 0.75±0.05
0.08±0.05
Direction feed
(Unit
Reel
Order quantity needs multiple minimum quantity.
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
13/13
2009.05 Rev.A
Notice
Notes
copying reproduction this document, part whole, permitted without consent ROHM Co.,Ltd. content specified herein subject change improvement without notice. content specified herein purpose introducing ROHM's products (hereinafter "Products"). wish such Product, please sure refer specifications, which obtained from ROHM upon request. Examples application circuits, circuit constants other information contained herein illustrate standard usage operations Products. peripheral conditions must taken into account when designing circuits mass production. Great care taken ensuring accuracy information specified this document. However, should incur damage arising from inaccuracy misprint such information, ROHM shall bear responsibility such damage. technical information specified herein intended only show typical functions examples application circuits Products. ROHM does grant you, explicitly implicitly, license exercise intellectual property other rights held ROHM other parties. ROHM shall bear responsibility whatsoever dispute arising from such technical information. Products specified this document intended used with general-use electronic equipment devices (such audio visual equipment, office-automation equipment, communication devices, electronic appliances amusement devices). Products specified this document designed radiation tolerant. While ROHM always makes efforts enhance quality reliability Products, Product fail malfunction variety reasons. Please sure implement your equipment using Products safety measures guard against possibility physical injury, fire other damage caused event failure Product, such derating, redundancy, fire control fail-safe designs. ROHM shall bear responsibility whatsoever your Product outside prescribed scope accordance with instruction manual. Products designed manufactured used with equipment, device system which requires extremely high level reliability failure malfunction which result direct threat human life create risk human injury (such medical instrument, transportation equipment, aerospace machinery, nuclear-reactor controller, fuel-controller other safety device). ROHM shall bear responsibility Products above special purposes. Product intended used such special purpose, please contact ROHM sales representative before purchasing. intend export ship overseas Product technology specified herein that controlled under Foreign Exchange Foreign Trade Law, will required obtain license permit under Law.
Thank your accessing ROHM product informations. More detail product informations catalogs available, please contact
ROHM Customer Support System
http://www.rohm.com/contact/
www.rohm.com 2009 ROHM Co., Ltd. rights reserved.
R0039A
Other recent searches
VFP10TM - VFP10TM VFP10TM Datasheet
TEA6848H - TEA6848H TEA6848H Datasheet
MK05-1A66C-220W - MK05-1A66C-220W MK05-1A66C-220W Datasheet
MK05-1A71C-220W - MK05-1A71C-220W MK05-1A71C-220W Datasheet
MAX4366 - MAX4366 MAX4366 Datasheet
MAX4367 - MAX4367 MAX4367 Datasheet
MAX4368 - MAX4368 MAX4368 Datasheet
MAX4364 - MAX4364 MAX4364 Datasheet
MAX4365 - MAX4365 MAX4365 Datasheet
HYB25DC256160C - HYB25DC256160C HYB25DC256160C Datasheet
HYB25DC256800C - HYB25DC256800C HYB25DC256800C Datasheet
FST3253 - FST3253 FST3253 Datasheet
DG9431 - DG9431 DG9431 Datasheet
DE475-102N21A - DE475-102N21A DE475-102N21A Datasheet
AN545 - AN545 AN545 Datasheet
Privacy Policy | Disclaimer
© 2012 Datasheet Archive
