The Datasheet Archive

Top Results (6)

Part Manufacturer Description Datasheet Download Buy Part
MSP430-3P-CORE-I2C-ANALYZER Texas Instruments CAS-1000-I2C
148-13 Coilcraft Inc Variable Inductor, Air-Core, 7528
148-11 Coilcraft Inc Variable Inductor, Air-Core, 7528
PCH-27X-683KLT Coilcraft Inc General Purpose Inductor, 68uH, 10%, Ferrite-Core,
PCH-27X-225KLT Coilcraft Inc General Purpose Inductor, 2200uH, 10%, Ferrite-Core,
164-08L Coilcraft Inc Variable Inductor, Air-Core, Unshielded, 2020

MPP core Datasheets Context Search

Catalog Datasheet MFG & Type PDF Document Tags
AIC1578CS

Abstract: AIC1578 IRF9Z34 1N4148 1N5820 AIC1578CN MPP core
Text: + C4 C2 R2 1M 1M Control *Sumida MPP CORE VIN CS+ DUTY CS - SHDN DRI , + C1 6.4 ~ 20V 90 VIN=6.4 V 85 VIN=9V VIN=16 V 80 10 R1 *:Sumida MPP Core , =3.3V *:Sumida MPP Core 10 10 Load Current (mA) 1000 Fig. 2 3.3V Step-Down Converter 5 + , AIC1761/1766 R12 *:Sumida MPP Core RS =0.1, charge current =0.5A ±10%, VIN>VBATT +3.5V RS =0.05


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PDF AIC1578 AIC1578 AIC1578CS IRF9Z34 1N4148 1N5820 AIC1578CN MPP core
78l05 so8

Abstract: SOP8 PNP Transistor Package GS 78L05 GS -L 0.1uF Capacitor CEM4435 AIC1576XXXX AIC1576PSTR AIC1576CSTR SS32 78l05 sop8
Text: =16V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 *VIN>15V, R7=15 *VIN15V, R7=0 100 1000 , >15V, R7=15 *VIN15V, R7=0 Efficiency vs. Load Current 95 *:Sumida MPP Core VOUT + 90 , *:Sumida MPP Core RS =0.1, charge current =0.5A ±10%, VIN>VBATT +3.5V RS =0.05, charge current =1A±10% , AIC1576 *VIN>15V, R7=15 *VIN15V, R7=0 *:Sumida MPP Core Fig. 12 Step-Down Converter 11 12


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PDF AIC1576 AIC1576 90KHz 280KHz 78l05 so8 SOP8 PNP Transistor Package GS 78L05 GS -L 0.1uF Capacitor CEM4435 AIC1576XXXX AIC1576PSTR AIC1576CSTR SS32 78l05 sop8
AIC1576

Abstract: transistor cs 9014 GS 78L05 78l05 sop8 35V still r70 pnp 9014 pin out aic1576ps GS -L 0.1uF Capacitor CEM4435 transistor so-8 AIC1576CSTR
Text: 85 R2 47K VIN=16V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 *VIN>15V, R7 , MPP Core VOUT + 90 Efficiency (%) NC + 3.3V/2A VIN C2 100µF 0.1µF , VOUT GND + C13 10µF *:Sumida MPP Core RS =0.1, charge current =0.5A ±10%, VIN>VBATT +3.5V , 680pF R2 10.5K *R7 5 AIC1576 *VIN>15V, R7=15 *VIN15V, R7=0 *:Sumida MPP Core Fig


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PDF AIC1576 90KHz 280KHz AIC1576 transistor cs 9014 GS 78L05 78l05 sop8 35V still r70 pnp 9014 pin out aic1576ps GS -L 0.1uF Capacitor CEM4435 transistor so-8 AIC1576CSTR
MCR-2A

Abstract: 0.033f 5.5v AIC1628 AN97001 2SK1463 1N5820 2SK94 CDR105 PFM design DC 12V To DC 5V converter
Text: ) MOSFET with an MPP core can deliver 2A output current and efficiency can exceed 92% at 1A loading , ) * MPP Core (a) (b) Fig. 5 5V to 3.3V Step-Down Converter (a) Application Circuit (b) Efficiency


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PDF AN97-001 AIC1628 AIC1628 1N5819 2SK1463 1N5820 MCR-2A 0.033f 5.5v AN97001 2SK1463 1N5820 2SK94 CDR105 PFM design DC 12V To DC 5V converter
2SK940

Abstract: 2SK1463 buss 2A MCR-2A 1N5819 1N5820 AIC1628 CDR105 AN001 converter circuit dc to Dc 2V to 24V
Text: RDS(ON) (VGS =5V) step-down a MOSFET with an MPP core can deliver 2A output conversion , 1000 Load Current (mA) * MPP Core (a) (b) Fig. 5 5V to 3.3V Step-Down Converter (a


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PDF AN001 AIC1628 AIC1628 1N5819 2SK1463 1N5820 2SK940 2SK1463 buss 2A MCR-2A 1N5819 1N5820 CDR105 AN001 converter circuit dc to Dc 2V to 24V
XF0506-S3

Abstract: S3 63 A XFMRS 1416
Text: XFMRS XFSMD3 SERIES INDUCTORS · · · · · · TRUE SURFACE MOUNT DESIGN ECONOMICAL, LOW COST SOLUTION TO YOUR POWER REQUIREMENTS CUSTOM VERSIONS AVAILABLE AT NO EXTRA COST TAPE AND REEL PACKAGING AVAILABLE LOW LOSS MPP CORE OR POWDERED IRON VERSIONS, BOTH STANDARD VERSATILE DUAL WINDING DESIGN, USE AS HIGH CURRENT CHOKE OR ONE (1) TO ONE (1) TRANSFORMER · CONSTANT INDUCTANCE UP TO 1.0 MHz PARALLEL , AT NO EXTRA COST TAPE AND REEL PACKAGING AVAILABLE LOW LOSS MPP CORE OR POWDERED IRON VERSIONS


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PDF 6XF4709-S3 6XF6809-S3 6XF0016-S3 6XF0026-S3 6XF0056-S3 6XF0086-S3 6XF0106-S3 6XF0156-S3 6XF0206-S3 6XF0256-S3 XF0506-S3 S3 63 A XFMRS 1416
2006 - Not Available

Abstract: No abstract text available
Text: =9V *:Sumida MPP Core 80 10 VIN>15V, R7=15Ω VIN≤15V, R7=0Ω 100 1000 Load Current (mA , GND FB VIN C1 12 ~ 18V *:Sumida MPP Core VOUT + 90 Efficiency (%) DUTY 5V , 470K Q2 MMBT2222A U3 + VIN C12 1µF NOTE: 78L05 VOUT GND *:Sumida MPP Core + C13


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PDF AIC1578 90KHz 280KHz AIC1578
2004 - Not Available

Abstract: No abstract text available
Text: 85 R2 47K VIN=16V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 VIN>15V, R7 , SS32 D1 AIC1578 R2 R1 27.4K 47K 330µF C3 *:Sumida MPP Core VOUT + 90 , 1µF NOTE: 78L05 VOUT GND *:Sumida MPP Core + C13 10µF VIN>15V, R7=15Ω VINâ


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PDF AIC1578 AIC1578 90KHz 280KHz
TAF200

Abstract: sendust tdk ferrite cores for smps iron eddy current hysteresis loss micrometals Arnold Magnetics 75-TAF200 75H-TAF200 iron core transformer dimmer chokes
Text: presents some general guidelines for the optimum choice of powder core materials ( MPP , Sendust/Kool Mu1 , magnetization or DC bias condition.The saturation flux density of MPP core is approximately 8000 gauss ( 800 mT) Compared to other materials, MPP cores are the costliest, but highest quality in terms of core , Features of MPP Core : Lowest core loss among all the powder materials. Low hysteristics loss resulting in , significantly lower losses than iron powder cores, but have higher core losses than MPP cores. Compared to iron


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PDF 75-TAF200 TAF200 sendust tdk ferrite cores for smps iron eddy current hysteresis loss micrometals Arnold Magnetics 75H-TAF200 iron core transformer dimmer chokes
2004 - Not Available

Abstract: No abstract text available
Text: VIN=16V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 VIN>15V, R7=15Ω VIN≤15V, R7 , =0Ω Efficiency vs. Load Current 95 RS GND FB VIN C1 12 ~ 18V *:Sumida MPP Core VOUT + , *:Sumida MPP Core + C13 10µF VIN>15V, R7=15Ω VIN≤15V, R7=0Ω RS =0.1Ω, charge current


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PDF AIC1578 90KHz 280KHz AIC1578
AIC1578

Abstract: transistor cs 9014 pnp 9014 pin out GS 78L05 SI2306 GS 78L05 N datasheet transistor 9014 transistor 9014 TRANSISTOR c 9014 C 9014 transistor
Text: 33µH *:Sumida MPP Core 90 VOUT + Efficiency (%) DUTY 5V CS+ + 3.3V/2A VIN , VIN C12 1µF NOTE: 78L05 VOUT GND *:Sumida MPP Core + C13 10µF VIN>15V, R7 , ~ 18V 90 V IN=6.4 V 85 R2 R1 15.4K 47K V IN =9V VIN =16 V *:Sumida MPP Core 80 10 V IN >15V, R7=15 V IN 15V, R7=0 100 1000 Load Current (mA) CS- SHDN


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PDF AIC1578 AIC1578 90KHz 280KHz transistor cs 9014 pnp 9014 pin out GS 78L05 SI2306 GS 78L05 N datasheet transistor 9014 transistor 9014 TRANSISTOR c 9014 C 9014 transistor
transistor cs 9014

Abstract: pnp 9014 pin out GS 78L05 AIC1578 SS32 CEM4435 BATTERY CHARGE CIRCUIT thermistor battery 9014 transistor replacement AIC1578CSTR
Text: =16V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 VIN>15V, R7=15 VIN15V, R7=0 100 1000 , Current 95 RS GND FB VIN C1 12 ~ 18V *:Sumida MPP Core VOUT + 90 Efficiency , R13 470K Q2 MMBT2222A U3 + VIN C12 1µF NOTE: 78L05 VOUT GND *:Sumida MPP Core


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PDF AIC1578 AIC1578 90KHz 280KHz transistor cs 9014 pnp 9014 pin out GS 78L05 SS32 CEM4435 BATTERY CHARGE CIRCUIT thermistor battery 9014 transistor replacement AIC1578CSTR
2002 - GS 78L05

Abstract: transistor cs 9014 SS657 pnp 9014 pin out GS 78L05 N SS32 SS6578CSTR still r70 SS32R6 R765
Text: VIN=16 V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 VIN>15V, R7=15 100 VIN15V, R7 , R1 47K VOUT 33µH *:Sumida MPP Core + 90 Efficiency (%) CS- SHDN 5V CS , R13 470K Q2 MMBT2222A U3 78L05 + C12 1µF NOTE: *:Sumida MPP Core VOUT VIN


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PDF SS6578 SS6578 90KHz 280KHz GS 78L05 transistor cs 9014 SS657 pnp 9014 pin out GS 78L05 N SS32 SS6578CSTR still r70 SS32R6 R765
AIC1578Ps

Abstract: aic1578p AIC1578PSTR pnp 9014 pin out GS 78L05 AIC1578 LL4148 SS32 78l05 sop8 DS-1578G-01
Text: 47K VIN=16V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 VIN>15V, R7=15 VIN15V, R7 , =0 Efficiency vs. Load Current 95 RS GND FB VIN C1 12 ~ 18V *:Sumida MPP Core VOUT + , GND *:Sumida MPP Core + C13 10µF VIN>15V, R7=15 VIN15V, R7=0 RS =0.1, charge current


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PDF AIC1578 AIC1578 90KHz 280KHz AIC1578Ps aic1578p AIC1578PSTR pnp 9014 pin out GS 78L05 LL4148 SS32 78l05 sop8 DS-1578G-01
2005 - AIC1578Ps

Abstract: AIC1578CSTR
Text: VIN=16V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 VIN>15V, R7=15Ω VIN≤15V, R7 , =0Ω Efficiency vs. Load Current 95 RS GND FB VIN C1 12 ~ 18V *:Sumida MPP Core VOUT + , *:Sumida MPP Core + C13 10µF VIN>15V, R7=15Ω VIN≤15V, R7=0Ω RS =0.1Ω, charge current


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PDF AIC1578 90KHz 280KHz AIC1578 AIC1578Ps AIC1578CSTR
DIODE 1n5819

Abstract: 2SK940 1N5819 1N5820 2SK1463 AIC1628 CDR105
Text: DC/DC converter, providing a conversion 50m RDS(ON) (V GS =5V) MOSFET with an MPP core from 5V , counterpart. Typically, a 10 100 1000 Load Current (mA) * MPP Core (a) (b) Fig. 5 5V to


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PDF AN96-SR01EN AIC1628 AIC1628 2SK1463 1N5820 DIODE 1n5819 2SK940 1N5819 1N5820 2SK1463 CDR105
2003 - Not Available

Abstract: No abstract text available
Text: VIN=16V R1 15.4K VIN=9V *:Sumida MPP Core 80 10 VIN>15V, R7=15Ω VIN≤15V, R7 , =0Ω Efficiency vs. Load Current 95 RS GND FB VIN C1 12 ~ 18V *:Sumida MPP Core VOUT + , *:Sumida MPP Core + C13 10µF VIN>15V, R7=15Ω VIN≤15V, R7=0Ω RS =0.1Ω, charge current


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PDF AIC1578 AIC1578 90KHz 280KHz
2002 - MAX742

Abstract: MAX742CPP MAX742CWP MAX742EPP MAX742EWP MAX742MJP MAX743
Text: -AT2502 ( MPP CORE ), Q2 = TWO IRF9Z30 IN PARALLEL ±15V MODE 200kHz 80 70 60 ±200 ±400 ±600 INDUCTORS = GOWANDA 050-AT1003 ( MPP CORE ) ±50 ±100 ±150 ±200 ±250 MEASURED AT LX-, ±15V , -AT1003 ( MPP CORE ) 50 4 90 EFFICIENCY (%) EFFICIENCY (%) 100kHz MAX742 -6 MAX742 -4 , capability (such as Gowanda #050AT1003), and using higher filter capacitance. Ferrite and MPP inductor , nodes. D. Inductor core losses: Hysteresis losses cause self-heating in some core materials. E. Loop


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PDF MAX742 100kHz 200kHz, MAX742CPP MAX742CWP MAX742EPP MAX742EWP MAX742MJP MAX743
1997 - MTP25N06L

Abstract: MAXL001 MAX743 MAX742MJP MAX742EWP MAX742EPP MAX742CWP MAX742CPP MAX742 mpp film capacitor
Text: -AT2502 ( MPP CORE ), Q2 = TWO IRF9Z30 IN PARALLEL ±15V MODE 200kHz 80 70 60 ±200 ±400 ±600 INDUCTORS = GOWANDA 050-AT1003 ( MPP CORE ) ±50 ±100 ±150 ±200 ±250 MEASURED AT LX-, ±15V , -AT1003 ( MPP CORE ) 50 4 90 EFFICIENCY (%) EFFICIENCY (%) 100kHz MAX742 -6 MAX742 -4 , capability (such as Gowanda #050AT1003), and using higher filter capacitance. Ferrite and MPP inductor , nodes. D. Inductor core losses: Hysteresis losses cause self-heating in some core materials. E. Loop


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PDF MAX742 100kHz 200kHz, MTP25N06L MAXL001 MAX743 MAX742MJP MAX742EWP MAX742EPP MAX742CWP MAX742CPP mpp film capacitor
1995 - 0-15v transformer

Abstract: terminal of inductors Fuji Electric fuji 3 phase diode cc fuji MAX742EWP MTP15 S 170 MOSFET TRANSISTOR MAX742 MAX742CPP
Text: -AT2502 ( MPP CORE ), Q2 = TWO IRF9Z30 IN PARALLEL ±15V MODE 200kHz 80 70 60 ±200 ±400 ±600 INDUCTORS = GOWANDA 050-AT1003 ( MPP CORE ) ±50 ±100 ±150 ±200 ±250 MEASURED AT LX-, ±15V , -AT1003 ( MPP CORE ) 50 4 90 EFFICIENCY (%) EFFICIENCY (%) 100kHz MAX742 -6 MAX742 -4 , capacitance. Ferrite and MPP inductor cores optimize efficiency and size. Iron-power toroids designed for , resistance. Excess capacitance at LX nodes. D. Inductor core losses: Hysteresis losses cause self-heating


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PDF MAX742 100kHz 200kHz, 0-15v transformer terminal of inductors Fuji Electric fuji 3 phase diode cc fuji MAX742EWP MTP15 S 170 MOSFET TRANSISTOR MAX742CPP
Not Available

Abstract: No abstract text available
Text: -AT2502 ( MPP CORE ), Q2 = TWO IRF9Z30 IN PARALLEL ±15V MODE 200kHz 80 70 60 ±400 ±600 INDUCTORS = GOWANDA 050-AT1003 ( MPP CORE ) ±50 ±100 ±150 ±200 ±250 MEASURED AT LX , INDUCTORS = GOWANDA 050-AT1003 ( MPP CORE ) 50 0 90 EFFICIENCY (% ) EFFICIENCY (% ) 100kHz , capability (such as Gowanda #050AT1003), and using higher filter capacitance. Ferrite and MPP inductor , voltage. Inductor has high DC resistance. Excess capacitance at LX nodes. D. Inductor core losses


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PDF MAX742 100kHz 200kHz,
2006 - Not Available

Abstract: No abstract text available
Text: • Frequency range up to 500kHz • MPP core material Applications • PC cards, cellular , performance, low profile, surface mount power 2002/95/EC inductors with a molybdenum permalloy core â , an approximate ∆T of 40°C without core loss. It is recommended that the temperature of the part , V-µS at 300KHz necessary to generate a core loss equal to 10% of the total losses for 40 , % 30% 40% 50% 60% 70% 80% 90% 100% 110% 120% 130% 140% 150% 160% % of I sat Core Loss IRMS


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PDF 2002/95/EC 500kHz MP2A-R47-R MP2A-R68-R
2006 - Not Available

Abstract: No abstract text available
Text: MPP core material Applications · PC cards, cellular telephones, pagers, and disk drives · GPS systems , profile, surface mount power inductors with a molybdenum permalloy core · Small footprint and closed , for an approximate T of 40°C without core loss. It is recommended that the temperature of the part not , core loss equal to 10% of the total losses for 40°C temperature rise. Mechanical Diagrams TOP VIEW , % % of I sat Core Loss IRMS DERATING WITH CORE LOSS 0 % of Losses from Irms (maximum) 20 40


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PDF 500kHz MP2A-R47-R MP2A-R68-R MP2A-100-R MP2A-150-Re
2007 - MP2A-3R3-R

Abstract: mpp schematic mp2a-680-r
Text: range up to 500kHz · MPP core material Applications · PC cards, cellular telephones, pagers, and disk , performance, low profile, surface mount power 2002/95/EC inductors with a molybdenum permalloy core · Small , ) DCR limits 20°C. (3) RMS current for an approximate T of 40°C without core loss. It is recommended , represents the applied V-µS at 300KHz necessary to generate a core loss equal to 10% of the total losses for , Core Loss IRMS DERATING WITH CORE LOSS 40 50 60 0K 10 0K 40 Hz 0K Hz 30 0K Hz 20 0K


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PDF 2002/95/EC 500kHz MP2A-R47-R MP2A-R68-R MP2A-3R3-R mpp schematic mp2a-680-r
1993 - 24V 20A SIEMENS battery charger

Abstract: 48v to 24v buck an5435 an5430 SMP40P06 LT1149 an5424 application note 54 ltc1149 AN5437 UPL1C222MRH
Text: -C1-0R050J Pd = 1W COILTRONICS CTX62-2-MP DCR = 0.040 MPP CORE (THROUGH HOLE) QUIESCENT CURRENT = 180µA , SCHOTTKY VBR = 40V KRL SL-1-C1-0R050J Pd = 1W COILTRONICS CTX50-2-MP DCR = 0.032 MPP CORE (THROUGH HOLE , MOTOROLA SCHOTTKY VBR = 60V KRL NP-1A-C1-0R050J Pd = 1W COILTRONICS CTX62-2-MP DCR = 0.040 MPP CORE , COILTRONICS CTX62-2-MP DCR = 0.040 MPP CORE TRANSITION CURRENT (Burst Mode OPERATION/CONTINUOUS OPERATION) = , SCHOTTKY VBR = 60V KRL NP-1A-C1-0R050J Pd = 1W COILTRONICS CTX50-2-MP DCR = 0.032 MPP CORE QUIESCENT


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