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Part Manufacturer Description Datasheet BUY
LT1681ESW#PBF Linear Technology LT1681 - Dual Transistor Synchronous Forward Controller; Package: SO; Pins: 20; Temperature Range: -40°C to 85°C visit Linear Technology - Now Part of Analog Devices Buy
LT1681ISW#TRPBF Linear Technology LT1681 - Dual Transistor Synchronous Forward Controller; Package: SO; Pins: 20; Temperature Range: -40°C to 85°C visit Linear Technology - Now Part of Analog Devices Buy
LT1681ISW#PBF Linear Technology LT1681 - Dual Transistor Synchronous Forward Controller; Package: SO; Pins: 20; Temperature Range: -40°C to 85°C visit Linear Technology - Now Part of Analog Devices Buy
LT1681ESW#TRPBF Linear Technology LT1681 - Dual Transistor Synchronous Forward Controller; Package: SO; Pins: 20; Temperature Range: -40°C to 85°C visit Linear Technology - Now Part of Analog Devices Buy
LT1681ISW Linear Technology LT1681 - Dual Transistor Synchronous Forward Controller; Package: SO; Pins: 20; Temperature Range: -40°C to 85°C visit Linear Technology - Now Part of Analog Devices Buy
LT1681ESW Linear Technology LT1681 - Dual Transistor Synchronous Forward Controller; Package: SO; Pins: 20; Temperature Range: -40°C to 85°C visit Linear Technology - Now Part of Analog Devices Buy

Transistor 169k

Catalog Datasheet MFG & Type PDF Document Tags

Transistor 169k

Abstract: Standalone Thermal Regulation Integrated Transistor 1.69k Linear ThinSOT Linear DFN , Current Input Voltage Onboard Charge Termination Integrated Pass Transistor End-ofCharge , Regulation Integrated Transistor Package USB Power Managers and Li-Ion Linear Battery Chargers with , Transistor Monitor End-ofCharge Signal AC Present Signal Thermal Reg. Thermistor , Transistor Package USB Power Managers and Li-Ion Linear Battery Chargers with PowerPath Control
Linear Technology
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LTC4006

Abstract: LTC1759 Charge Termination Method Thermal Regulation Integrated Transistor 1.69k Charger Type , Input Voltage Onboard Charge Termination Integrated Pass Transistor End-ofCharge Signal , Transistor Package USB Power Managers and Li-Ion Linear Battery Chargers with PowerPath Control , Voltage Charge Integrated Termination Pass Method Transistor AC Present Signal Thermal Reg , Termination GND Li-Ion Battery Thermal Regulation Integrated Transistor I I I QFN
Linear Technology
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NTC 2.2K

Abstract: LTC4054L Transistor 1.69k Charger Type Package Coin Cell Li-Ion Battery Chargers I LTC4054L 10 ­ , Current Input Voltage Onboard Charge Termination Integrated Pass Transistor End-ofCharge , UVLO Standalone Onboard Charge Termination Thermal Regulation Integrated Transistor , Pass Method Transistor AC Present Signal Thermal Reg. Thermistor Interface Package , Onboard Charge Thermal Termination Regulation Integrated Transistor Package USB Power
Linear Technology
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NTC 2.2K 16.8v 2a li-ion Lead Acid Battery Charger Switchmode LTC4069 DFN10 thermal resistance DFN-16 D-85737 D-59387 D-73230 I-20156 SE-164 BB110520K

circuit diagram for 48v automatic battery charger

Abstract: circuit diagram for 24V automatic battery charger Charge Termination Method Thermal Regulation Integrated Transistor 1.69k Charger Type , Input Voltage Onboard Charge Termination Integrated Pass Transistor End-ofCharge Signal , Transistor Package USB Power Managers and Li-Ion Linear Battery Chargers with PowerPath Control , Voltage Charge Integrated Termination Pass Method Transistor AC Present Signal Thermal Reg , Termination GND Li-Ion Battery Thermal Regulation Integrated Transistor I I I QFN
Linear Technology
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circuit diagram for 48v automatic battery charger circuit diagram for 24V automatic battery charger High Current Voltage Regulator mosfet 7805 7805 12v to 5v 3a 7805 12v to 5v 1a 7805 12v to 5v 2a BP10217 I-20041 BB0207OL

CD54-100MC

Abstract: Transistor 169k · 20µH* 1/2 CTX20-1 90 VOUT 3.3V 200mA 169k 1% + PGND 1 IOUT = 200mA , VOLTAGE (V) Figure 1. 3-Cell to 3.3V SEPIC 10µF* 35V ON 3 CELLS 4 LT1372 16.9k 1 , emitter just high enough to maintain the desired output voltage-the transistor is saturated. For V IN , develop the base current necessary to support any load current. In this condition the transistor serves , LBO OFF 3 LT1303 FB SHDN LBI SGND ON 2 169k 1% + 4 5 220µF* +
Linear Technology
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ZTX788B CD54-100MC MBRS130T3 Transistor 169k CD54-100M LT1303 LT1372 mosfet dc to dc boost converter sanyo oscon DN109 1-800-4-LINEAR

CTX02-16030

Abstract: coiltronics 15835 5 6 680pF 7 16.9k COL B SYNC CT RSL RT GND 10 PGND C1 47µF 6.3V · · , °C. VIN = 5V; RT = 16.9k; CT = 680pF; RSL = 16.9k; COL A, COL B, SHDN pins open, unless otherwise noted , 85 3439 G01 0.6 RT = 16.9k 115 CT = 680pF 1.28 0 25 50 75 100 125 150 TEMPERATURE , discharge currents of the oscillator capacitor. The nominal value is 16.9k. The resistance can be adjusted , the RT pin to set the oscillator frequency. For RT = 16.9k, CT can be calculated as follows: VIN
Linear Technology
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CTX02-16030 coiltronics 15835 ctx02-16076 CTX02 coiltronics CTX02-13664 CTX02-13834 LT3439 LT1764/LT1764A LT1962 LT1963/LT1963A LT1964

ctx02-16076

Abstract: CTX02 16.9K Co l A 3 Col B 14 D1 MMBD914 9 2 3 C2 10µF 8 4 6 CT C11 470p F , 16.9K Q1 FMMT551 D3 MMBD914 9 2 3 4 7 T2 CTX02- 16076 Supertex inc. R39 100k , 16.9K FB R4 M1 DN3525 40.2 7 2 C11 470pF 5 SYNC 10 GND 1,16 PGND 8 4 R10 , R27 14.3k 12 RESET Q1 FMMT551 7 RT R2 16.9K 12V 8 4 11 SHUTDOWN D1 , , 100V 1210 Any - R1, 2 16.9k, Chip Resistor 805 Any - R3, 9 12.1, Chip
Supertex
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HV738DB1 HV748DB1 CTX02 CTX02 16076 ultrasound TRANSFORMER pwm lm2903 P-Channel Depletion Mosfets logic SOT-23 Depletion Mode mosfet AN-H59 AN-H59DB1 LM2903DR DN3525N8-G

ctx02-16076

Abstract: CTX02 40.2 R3 12.1 Vin =12V 13 VIN 11 C1 10µF SHUTDOWN 4 RSL R1 16.9K Co l A 3 , ,16 PGND L T3439 R42 1.5K 7 D2 T1 CTX02- 16076 MMBD914 7 RT R2 16.9K Q1 , 13 2 C14 1.0nF 2 COMP 14 4 RSL R1 16.9K FB R4 M1 DN3525 40.2 7 2 , FMMT551 7 RT R2 16.9K 12V 8 4 11 SHUTDOWN D1 MMBD914 9 3 Col B 14 R25 , - C16, 23 Chip Capacitor, 2.2µF, 100V 1210 Any - R1, 2 16.9k, Chip Resistor
Supertex
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HV758DB1 T1521 p-channel 250V power mosfet ultrasound HV748 SOT R23 depletion mode current limiter J1 TRANSISTOR DIODE SOT-23 TN2510N8 TP2104K1 TN2106K1 TP2510N8

0-9v 500ma transformer

Abstract: coiltronics 15835 5 6 680pF 7 16.9k COL B SYNC CT RSL RT GND 10 PGND C1 47µF 6.3V · · , the full operating temperature range, otherwise specifications are at TA = 25°C. VIN = 5V; RT = 16.9k; CT = 680pF; RSL = 16.9k; COL A, COL B, SHDN pins open, unless otherwise noted. SYMBOL PARAMETER , 85 3439 G01 0.6 RT = 16.9k 115 CT = 680pF 1.28 0 25 50 75 100 125 150 TEMPERATURE , and discharge currents of the oscillator capacitor. The nominal value is 16.9k. The resistance can be
Linear Technology
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0-9v 500ma transformer ctx02-13713 transformer less power supply 12 volt 3A transformer 12V 500mA ct center tapped transformer 12v 3A coiltronics ctx02-13664
Abstract: Transformer 5V Output Noise OPTIONAL VIN 5V D1 T1 CIN 22µF 10V 13 11 5 6 680pF 7 16.9k , = 5V; RT = 16.9k; CT = 680pF; RSL = 16.9k; COL A, COL B, SHDN pins open, unless otherwise noted , Switch Voltage Drop vs Switch Current 0.6 110 85 3439 G01 0.8 RT = 16.9k 115 CT = , currents of the oscillator capacitor. The nominal value is 16.9k. The resistance can be adjusted between , the RT pin to set the oscillator frequency. For RT = 16.9k, CT can be calculated as follows: CT(nF Linear Technology
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pwm led driver circuit diagram

Abstract: GRM21BR71H104KA01B TG CTRL FB VC C4 0.1µF RT SS RT 16.9k ONE WIRE CONNECTION FOR LED STRING. THE , typical PMOS disconnect switch driver consists of an NMOS transistor and a level shift resistor network , PVIN 24V RT 16.9k 1MHz C5 0.1µF C1: KEMET C0805C225K4RAC C2: MURATA GRM31MR71E225KA93 C3
Linear Technology
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LT3518 pwm led driver circuit diagram GRM21BR71H104KA01B C1206C225K2RAC C0806C225K4RAC PMOS driver nmos pmos array

723V

Abstract: IRF1310NS . Using an external N-channel pass transistor, the negative Hot Swap circuit of the LTC4261 allows a , transistor in all operating conditions. Turning the device on or off can be either autonomous or controlled , sequence two power good outputs, detect insertion of a board and turn off the pass transistor if an , RELEASE AT 43V 7 8 9 10 11 19 20 26 2 25 24 R2 16.9k 1% OV = 72.3V OV RELEASE AT , , the SENSE pin voltage is used to measure current flowing through the pass transistor. This voltage
Linear Technology
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LTC4304 LTC4303 LTC4300A-1 723V IRF1310NS LTC4261CGN
Abstract: 169k RFREQ = 100k RFREQ = 340k RFREQ = 100k DPWM Chopping Frequency DPWM Input Low Voltage DPWM Input , = 2V -0.3 2.1 70 +0.3 RFREQ = 169k RFREQ = 340k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = GND, FREQ = VCC SYNC = VCC, FREQ = VCC -0.3 , Threshold 2.1 3.95 4.20 2.1 20 100 0.8 RFREQ = 169k RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = GND, FREQ = VCC SYNC = VCC, FREQ = VCC 2.1 3.0 3.0 0.8 0.5V < VCOMP < 4V IFB/rising 0 Maxim Integrated Products
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MAX8722C E24-1

panasonic fc

Abstract: ELECTROLYTIC CAPACITOR 330uF 63V voltage is used to give the lowest power dissipation of the LDO pass transistor. In this case the 3.3V , 66.5K C29 470pF R1 3.57K R27 2.2M C8 330µF / 6.3V R2 1.69K C28 0.33µF C20 1.5nF , current limit setting resistor. One will have to select a NMOSFET transistor with a higher current , , 1.69K, 1/16W Resistor, 1.18K, 1/16W Resistor, 0 Ohm Jumper Resistor, 100K 1/16W Resistor, 66.5K, 1
Microsemi
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LX1675 ECJ-1VB1A224K ERJ-3EKF2204V panasonic fc ELECTROLYTIC CAPACITOR 330uF 63V SCHEMATIC DIAGRAM POWER SUPPLY 12v 10A TP45-TP47 transistor k31 fairchild ECJ-DV50J106M ECJ-2FB1E105K ECJ-1VB0J105K ERJ-3EKF3571V
Abstract: to the LDO output voltage is used to give the lowest power dissipation of the LDO pass transistor , 2.2M C8 330µF / 6.3V R2 1.69K C28 0.33µF C20 1.5nF R9 12.4K C3 1µF 25V TP16 , select a NMOSFET transistor with a higher current rating for the new application. The supply voltage , -1VC1H471J 0603 0603 1 Resistor, 3.57K, 1/16W Resistor, 1.69K, 1/16W Resistor, 1.18K, 1/16W Resistor, 0 -
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ECJ-1VB1C104K EEU-FC1C471 ECJ-4YB1E106M EEU-FM0J331 ERJ-3EKF1691V ERJ-3EKF1181V

ccfl BACKLIGHT LAMP

Abstract: sumida ccfl inverter 6 pin RFREQ = 169k 515 RFREQ = 100k s 159 RFREQ = 340k DPWM Chopping Frequency RFREQ = 100k 343 RFREQ = 169k DPWM Input Low Voltage SYNC = VCC, RFREQ = 169k DPWM Input Hysteresis SYNC = VCC, RFREQ = 169k DPWM Input Bias Current SYNC = VCC, RFREQ = 169k Hz V 106 SYNC = VCC, RFREQ = 169k DPWM Input High Voltage 210 215 0.8 205 RFREQ = 340k 2.1 V , Threshold 2.2 2.4 V VFB Undervoltage Threshold 340 520 mV RFREQ = 169k 230 290
Maxim Integrated Products
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ccfl BACKLIGHT LAMP sumida ccfl inverter 6 pin BAW56W C3225X7R1E475M CMSD2836 CCFL BACKLIGHT INVERTER RoHS

ctx02-16076

Abstract: AN-H59 3: Adjustable VPF and VNF Power Supply R3 12.1 VIN = 12V 13 11 C1 10µF R1 16.9k R2 16.9k 4 7 6 VIN COLA SHUTDOWN RSL COLB 14 2 9 3 3 8 4 D1 , Any - R1, 2 16.9k, Chip Resistor 805 Any - R3, 9 12.1, Chip Resistor , Q1, 2, 3, 5 PNP, 60V, Bipolar Transistor SOT-23 Zetex Inc FMMT551TA Q4 NPN, 120V, Bipolar Transistor SOT-23 Zetex Inc FMMT494TA U1 IC, Low Noise Transformer Driver 16
Supertex
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Mosfet 2903 r19 2903 HV9910NG sot 89 2903 capacitor 22uf 100V 1.0K 250V X2

2n2222 -331 transistor

Abstract: 2n2222 -331 . Achieving this performance means the output device must be either a PNP bipolar transistor or a MOSFET , 95.3k R1 VOUT = 1.235V (1+ ) R2 Figure 3-32. PNP Transistor Boosts Current Output From MIC2951 , 1.235V reference. Figs. 3-28 & 29 (V = 1.240V) REF Voltage R1 R2 1.5 80.6k 16.9k 1.8 237k 107k 2.85 287k , The 150mA MIC2951 gets a capacity boost to several amperes by using an external PNP transistor. Figure 3-32 shows the MIC2951 driving a DH45H8 or equivalent PNP transistor to achieve a 3A output. This
Micrel Semiconductor
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2n2222 -331 transistor 2n2222 -331 application irfz44 IN 12V TO 120V CONVERTER Intel 486 computer schematic MIC29151 MIC29752 MIC5156/57/58 MIC29712 MIC29512

adc 555

Abstract: Guaranteed monotonic VSYNC = 2V -0.3 10 0.20 1.9 -0.1 5 0.23 2.0 2.1 100 +0.3 50 0.26 2.1 +0.1 RFREQ = 169k RFREQ = 340k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = GND, FREQ = VCC SYNC = VCC, FREQ = VCC -0.3 2.1 100 +0.3 2.4 2.4 0.8 204 0 < VISEC , Threshold 2.1 VCC 0.35 3.95 4.20 VSYNC = 2V 2.1 -0.3 10 0.20 1.9 +0.3 50 0.26 2.1 0.8 RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = GND, FREQ = VCC SYNC = VCC, FREQ = VCC 2.1 2.4 2.4
Maxim Integrated Products
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adc 555 MAX8722A

MAX8722A

Abstract: T912MG-1018 Guaranteed monotonic VSYNC = 2V -0.3 10 0.20 1.9 -0.1 5 0.23 2.0 2.1 100 +0.3 50 0.26 2.1 +0.1 RFREQ = 169k RFREQ = 340k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = GND, FREQ = VCC SYNC = VCC, FREQ = VCC -0.3 2.1 100 +0.3 2.4 2.4 0.8 204 0 < VISEC , Threshold 2.1 VCC 0.35 3.95 4.20 VSYNC = 2V 2.1 -0.3 10 0.20 1.9 +0.3 50 0.26 2.1 0.8 RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = VCC, RFREQ = 169k SYNC = GND, FREQ = VCC SYNC = VCC, FREQ = VCC 2.1 2.4 2.4
Maxim Integrated Products
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T912MG-1018 sumida backlight inverter 12 ccfl mosfets
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