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TPS60400QDBVRQ1 Texas Instruments Automotive Unregulated 60mA Charge Pump Voltage Inverter 5-SOT-23 -40 to 125 visit Texas Instruments Buy
TPS60400DBVT Texas Instruments 60mA Charge Pump Voltage Inverter with Variable Switching Frequency 5-SOT-23 -40 to 85 visit Texas Instruments Buy
TPS60402DBVT Texas Instruments 60mA Charge Pump Voltage Inverter with Fixed 50kHz Operation 5-SOT-23 -40 to 85 visit Texas Instruments Buy
TPS60400DBVTG4 Texas Instruments 60mA Charge Pump Voltage Inverter with Variable Switching Frequency 5-SOT-23 -40 to 85 visit Texas Instruments
TPS60402DBVTG4 Texas Instruments 60mA Charge Pump Voltage Inverter with Fixed 50kHz Operation 5-SOT-23 -40 to 85 visit Texas Instruments
TPS60402QDBVRQ1 Texas Instruments Automotive Unregulated 60mA Charge Pump Voltage Inverter with 50kHz Fixed Frequency 5-SOT-23 -40 to 125 visit Texas Instruments Buy

Step-up 1.2V to 3V 60mA SOT-23

Catalog Datasheet MFG & Type PDF Document Tags

LA5617

Abstract: LV51116LF ) TSSOP36(275mil) 1.8V to 11V Programmable 3ch externally External TSSOP36(275mil) 3V to 15V Programmable 6ch externally (Step up 2, down 4) External TQFP48J(7×7) 17 3V to 15V Programmable 3ch externally (Step up 1, down 2) External SSOP24(225mil) 18 3V to , ) MFP8(225mil) LV5606LP ± Charge pump step-up 3V to 3.45V Programmable externally 2ch Built in VQLP32(4.0×4.0) LV5606V ± Charge pump step-up 3V to 3.45V Programmable
SANYO Electric
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LA5617 LV51116LF LA5664 LA5772 5A 28v regulator LV51111 LV5217GP VCT16 EP91G

cb 7300-12

Abstract: 30mV, corresponding to an ESR of 60mâ"¦. Figure 5 shows the circuit with an OS-CON unit. ESR is now , APPLICATIO S 1.5V to 3V Step-Up Converter L1â'  120µH 1N5818 1.5V CELL VIN L1â'  120µH 3V OUTPUT 20mA AT VBATTERY = 1V 220â"¦ ILIM 1.5V to 9V Step-Up Converter ILIM 536k , 1N5818 3V to 5V Step-Up Converter L1â'  68µH 12V OUTPUT 5mA AT VBATTERY = 1V 16mA AT VBATTERY , GOWANDA GA10-682k OR CADDELL-BURNS 7300-11 3V to 12V Step-Up Converter 3V to 15V Step-Up Converter
Linear Technology
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cb 7300-12 LT1073 LT1073-5 LT1307 LT1316 LT1317 LT1610

LTAHG

Abstract: Step-up 12V to 36V 300mA (MAX): ± 34V, IQ: 20µA, ISD: , 3MHz Switching Frequency High Output Voltage: Up to 38V 300mA Integrated Switch 12V at 70mA from 5V Input 5V at 115mA from 3.3V Input Wide Input Range: 2.5V to 16V Uses Small Surface Mount Components Low Shutdown Current: , converter footprint. The constant frequency results in low, predictable output noise that is easy to filter
Linear Technology
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LMK212BJ105 LTAHG Step-up 12V to 36V 300mA Step-up 1.2V to 3.2V 60mA 5v stepup converter MO-193 footprint LT3461A LT3461 LMK212BJ474 CMSSH-35-LTN LQH32CN-100

Murata LQH3C100K24

Abstract: LQH3C100K24 1.5V to 3V input voltage range. Switching waveforms with an input voltage of 2.8V and a 60mA load , DESIGN FEATURES Micropower 5-Lead SOT-23 Switching Regulators Extend Battery Life in Space-Sensitive Applications by Bryan Legates Introduction L1 4.7µH VIN 1.5V TO 3V The LT1615 and , converter can deliver up to 1.32W (40mA at 33V) of power at an efficiency of 85%, all from a tiny SOT-23 , tiny SOT-23 packages, along with small external components, combine to minimize footprint and cost
Linear Technology
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LT1617 LT1613 LT1611 Murata LQH3C100K24 LQH3C100K24 EMK316BJ475 5v Step-up 12V LQH3C100

Step-up 12V to 36V 300mA

Abstract: CMOD4448 s s s s s s 1.3MHz Switching Frequency High Output Voltage: Up to 36V 300mA Integrated Switch 12V at 70mA from 5V Input 5V at 60mA from 3.3V Input Wide Input Range: 2.5V to 16V Uses Small , 90 L1 10µH VIN 2.7V TO 4.2V Efficiency 84 VIN = 3.6V 82 VIN = 3V 80 VIN , rights. 11 LT3460 U TYPICAL APPLICATIO S 5V to 5V SEPIC VIN 3V TO 10V C1 1µF VIN , Step-Up DC/DC Converter VIN: 3V to 25V, VOUT(MAX) = 35V, IQ = 0.9mA, ISD
Linear Technology
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CMOD4448 FZ 76 capacitor 1000 6.3V 12V DC to 36V dC converter circuit diagram Step-up 1.2V to 3V 60mA TA07A lt1615 marking LT1945 LT1961 LTC3400/LTC3400B LTC3401/LTC3402 LT3461/LT3461A LT3464

MQE001-902

Abstract: murata MQE001-902 s s s s s s s Switching Frequencies Up to 900kHz = Smaller Capacitors Tiny SOT-23, MSOP , -3.3 Regulated Charge Pumps with Shutdown in SOT-23 Regulated 5V Output from a 2.7V to 5.5V Input VOUT = 5V ± 4 , Inductorless DC/DC Converters LTC1986 3V/5V SIM Power Supply in SOT-23 VOUT = 5V OR VIN 1 2.2µF 3/5 , CONTROLLER 3V 1 2 3 4 5 VCC 6 7 8 CIN CLK RIN RST DATA s VIN 2.7V TO , ID Module (SIM) Cards in Cellular Phones Step-Up/Step-Down Circuit Charge Pump Generates 5V 3V to
Linear Technology
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LTC1682-5 LTC1503-2 LTC1682 LTC1754 MQE001-902 murata MQE001-902 murata mqe001 MQE001 MQE-001-902 Step-up 1.2V to 3V 60mA SOT-23 LTC1502-3 125IN2

36V DC to 12V dC converter circuit diagram

Abstract: MO-193 footprint BSC S6 TSOT-23 0302 3461i 7 LT3461 TYPICAL APPLICATIO S Efficiency 5V to 36V Step-Up , 1.3MHz Switching Frequency High Output Voltage: Up to 38V 300mA Integrated Switch 12V at 70mA from 5V Input 5V at 115mA from 3.3V Input Wide Input Range: 2.5V to 16V Uses Small Surface Mount Components Low Shutdown Current: , converter footprint. The constant frequency results in low, predictable output noise that is easy to filter
Linear Technology
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36V DC to 12V dC converter circuit diagram 3461 EMK316BJ105 GRM42-6X7R474K50 LQH32CN470 LT1615/LT1615-1 LT1944/LT1944-1 LTC3401

Step-up 12V to 36V 300mA

Abstract: 12V DC to 36V dC converter circuit diagram s s s s s s s s s 1.3MHz Switching Frequency High Output Voltage: Up to 36V 300mA Integrated Switch 12V at 70mA from 5V Input 5V at 60mA from 3.3V Input Wide Input Range: 2.5V to 16V Uses , APPLICATIO S 5V to 5V SEPIC C3 0.22µF L1 22µH VIN 3V TO 10V C1 1µF VIN SW D1 VOUT , inductors. The constant frequency results in low, predictable output noise that is easy to filter. The high voltage switch in the LT3460 is rated at 38V, making the device ideal for boost converters up to
Linear Technology
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LMK107BJ105 Step-up 12V to 36V EMK212BJ105 LQH32CN220 TA02b making 2a sc70 LMK107BJ224 MBR0520 LQH32CN-220 LTC3402
Abstract: -8327J50 Connection to VDD pin 2VVCC , conditions with the capability of automatically controlling the duty ratio from 0% to 83% (78% for 250kHz model) according to each applied load. A step-up switching regulator is constructed by externally connecting only a coil, a capacitor and a diode to the S-8323 Series. This feature, along with its small Seiko Instruments
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G20 6-pin

Abstract: marking 3221 OmA TO 25mA; VIN >1.8V IOUT = OmA TO 60mA; VIN >2V REGULATED 5V OUTPUT FROM 2.7V TO 5.5V INPUT VOUT = 5V ±4% IOUT = OmA TO 25mA; VIN >2.7V IOUT = OmA TO 60mA; VIN >3V NO-LOAD INPUT CURRENT (µA , -5 with VIN = 3V, IOUT = 60mA and VOUT regulating to 5V, has a measured efficiency of 82% which is in , Range: 1.8V to 4.4V (LTC3221-3.3) 2.7V to 5.5V (LTC3221-5) Output Current: Up to 60mA No Inductors , charge pump DC/DC converters that produce a regulated output at up to 60mA. The input voltage range is
Linear Technology
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LTC3221 LTC3240-3 G20 6-pin marking 3221 6pin lccp LBQP LTC3221-3.3 LTC3221/ 3/LTC3221-5 LTC1516 LTC1517-5/LTC1517-3 LTC1522
Abstract: = OmA TO 60mA; VIN >3V NO-LOAD INPUT CURRENT (µA) 2 14 12 10 8 6 TA = 90°C TA = , -5) Output Current: Up to 60mA No Inductors Needed Very Low Shutdown Current: , regulated output at up to 60mA. The input voltage range is 1.8V to 5.5V. Extremely low operating current , OUTPUT FROM 1.8V TO 4.4V INPUT VOUT = 3.3V ±4% IOUT = OmA TO 25mA; VIN >1.8V IOUT = OmA TO 60mA; VIN , Supply Current 2.7V ≤ VIN ≤ 5.5V, IOUT < 25mA 3V ≤ VIN ≤ 5.5V, IOUT < 60mA IOUT = 0mA VR Linear Technology
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LTC1555/LTC1556 LTC1751-3 3/LTC1751-5 LTC1754-3 3/LTC1754-5 LTC1755
Abstract: 10µA 10ms/DIV VIN = 1.3V VOUT = 3.3V IOUT = 60mA TO 10µA L = 6.8µH COUT = 4.7µF 3400 G08 , Cell AA Cell to ±3V Synchronous Boost Converter C3 1µF L1 4.7µH + SINGLE AA CELL C1 , TSOT-23 0302 3400fa Information furnished by Linear Technology Corporation is believed to be , switch and PMOS synchronous rectifier. Up to 92% Efficiency Generates 3.3V at 100mA from a Single AA , 2.5V to 5V Output Range Automatic Burst Mode® Operation (LTC3400) Continuous Switching at Light Linear Technology
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3400/LTC3400B LTC3400B LTC1872 LT1930/LT1930A LT1932 LT1946/LT1946A

ctx10052-1

Abstract: LT1073-12 , NY 11729 800-645-5828 RL1283 RL1284 U TYPICAL APPLICATIO S 1.5V to 3V Step-Up Converter , 100µF LT1073-5 SENSE SENSE GND 1N5818 100 VIN ILIM 1.5V CELL 1N5818 3V to 5V , SW2 L1 = GOWANDA GA10-682k OR CADDELL-BURNS 7300-11 3V to 12V Step-Up Converter 3V to 15V , FILM L1 = GOWANDA GA10-822k OR CADDELL-BURNS 7300-12 9V to 5V Step-Down Converter 9V to 3V , TYPICAL APPLICATIO S 1.5V to 5V Low Noise Step-Up Converter 3V to 5V Step-Up Converter with
Linear Technology
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ctx10052-1 LT1073-12 501d sprague 473k capacitor Caddell-Burns 6860 GA10-682K LT1173 LT1931/LT1931A

LTC1700EMS

Abstract: Step-up 1.2V to 3V 60mA SOT-23 duration, the soft-start function has no effect on the internal 60mA current limit. Therefore to fully , takes VOUT to reach 2.3V upon powering up is given by: tPOWER-UP = C OUT (2.3 ­ VIN ­ VD ) 260(L , -Cells to 5V at 20mA, SOT-23 Package, 6µA IQ LT1610 1.7MHz Single Cell Micropower Step-Up Regulator , RSENSE, Programmable Frequency 50kHz to 1MHz; 10-Lead MSOP LTC1872 SOT-23, 550kHz Step-Up , wide range of load currents. High Efficiency: Up to 95% No Current Sense Resistor Required
Linear Technology
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LTC1700 LT1517-5 LTC1700EMS linear Regulated Power Supply Schematic Diagram for constant 5V and 2A LTLC 6TPB330M LT1619 LTC1625 LTC1871

LTWk

Abstract: MARKING LTUN VOUT = 3.3V IOUT = 60mA TO 10µA L = 6.8µH COUT = 4.7µF 3400 G08 100µs/DIV VIN = 1.3V VOUT = , 3400 TA02b 3400fa 9 LTC3400/LTC3400B U TYPICAL APPLICATIO S Single Cell AA Cell to ±3V , S6 TSOT-23 0302 NOTE: 1. DIMENSIONS ARE IN MILLIMETERS 2. DRAWING NOT TO SCALE 3. DIMENSIONS , Cell, VOUT to 34V LT1613 1.4MHz, Single Cell DC/DC Converter in ThinSOT VIN as Low as 1.1V, 3V , synchronous rectifier. Up to 92% Efficiency Generates 3.3V at 100mA from a Single AA Cell Low Start-Up
Linear Technology
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LTWk MARKING LTUN ltun CMD4D06 LTC3400BES6 LTC3400ES6 LT1949 LTC3423 LTC3424 LTC3425

transistor 8323

Abstract: S-8323A25MC-ELF-T2 -8327J25 S-8327J50 Connection to VDD pin 2VVCC , conditions with the capability of automatically controlling the duty ratio from 0% to 83% (78% for 250kHz model) according to each applied load. A step-up switching regulator is constructed by externally connecting only a coil, a capacitor and a diode to the S-8323 Series. This feature, along with its small , Vss-0.3 to 11 11 300 Vss-0.3 to VOUT+0.3 ±50 500 150 -40 to +85 -40 to +125 °C °C Unit V V V mA V mA
Seiko Instruments
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transistor 8323 S-8323A25MC-ELF-T2 S-8323A30MC-ELK-T2 S-8323/8327 S-8327 UP003-A

RB300

Abstract: seiko 100 s chip , and its characteristics when 3V (3V ±10%) and 5V (5V±10%) are used for the applied power. Set VIN to , automatically changes the duty ratio from 0% to 83% according to the current load, offering products of a wide , coil, a capacitor and a diode to the S-8323 Series. This feature, along with its small package and low , pin voltage Unit VOUT VOUT pin voltage Ratings 11 V V ON/OFF Vss - 0.3 to 11 , VEXT Vss - 0.3 to VOUT+0.3 V EXT pin current IEXT ±50 mA SOT-89-3 500 mW
Seiko Instruments
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RB300 seiko 100 s chip S-8323A27MC-ELH-T2 S-8323A33MC-ELN-T2 S-8323A50MC-EME-T2 11S8323002 S-8323/24/27/28 S-8322 S-8327/8 11S8323001

LT1517-5

Abstract: LTC1700 no effect on the internal 60mA current limit. Therefore to fully take advantage of this feature, the , Peak Switch Current 3.3V/200mA From Two Cells; 600kHz Fixed Frequency 3-Cells to 5V at 20mA, SOT-23 , -Lead SOT-23 Package Drives External NMOS; 3.3V to 5V at up to 8A Up to 97% Efficiency; 3.7V VIN 36V , High Efficiency: Up to 95% No Current Sense Resistor Required Constant Frequency 550kHz Operation , , it only draws 10µA. To prevent inductor current runaway, the duty cycle is limited to 90
Linear Technology
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919AS-IR8N

TN200T

Abstract: S-8324 pin to . Step-up 2VVCC , 3-V system drive (3V/200mA) powered by 4 secondary Nicd batteries (3.6 to 4.8V), 2 lithium-ion , when 3V (3V ±10%) and 5V (5V±10%) are used for the applied power. Set VIN to 9V-|VCC| or less. SD , automatically switches the control method according to the current load, offering products of a wide range , capacitor and a diode to the S-8324 Series. This feature, along with its small package and low current
Seiko Instruments
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TN200T MIDORI 8328B t 8328 S-8324A27MC-EOH-T2 S-8324A30MC-EOK-T2

Step-up 1.2V to 3V 60mA

Abstract: 5v Step-up 12V capacitor. These controllers also eliminate the sense resistor to increase efficiency while saving space and cost. Finally, they switch at up to 1MHz, permitting use of a small inductor. SIMPLEST AND SMALLEST BOOST CONTROLLER CIRCUIT ELIMINATES IN-RUSH CURRENT POWER INPUT 1V TO VOUT SOFT-START RESPONSE VCC INPUT 2.5V TO 5.5V VIN = 3V VOUT = 12V RLOAD = 200 ILOAD = 60mA VCC OUTPUT , Current Spikes & RSENSE Resistor Use the MAX1522­MAX1524 DC-DC controllers to build the simplest and
Maxim Integrated Products
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MAX1523 MAX1522-24 simplest softstart in-rush input inrush current circuit
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