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47 MF CAPACITOR

Catalog Datasheet MFG & Type PDF Document Tags

ic 7495

Abstract: 7495 collector of Q1 while trace B shows the output voltage across the 47 mF capacitor (AC coupled) It can be , form an oscillator The transformer output is rectified and used to charge the 47 mF capacitor When the , by the 100 mF filter capacitors The value of these capacitors will depend directly on the output , capacitor and the 100k feedback resistor The low noise during the blank pulse period affords ideal , oscillating about the trip point the 0 1 mF unit is used to provide hysteresis of response Very low loading
National Semiconductor
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NCP6360 D

Abstract: Switching Frequency Uses 470 nH Inductor and 4.7 mF Capacitor for Optimized Footprint and Solution , 0.47 mH 4.7 â' 33 mF Co Output Capacitor for DCDC Converter (Note 6) F = 6 MHz, L = 0.33 mH 33 â' 220 mF Cin Input Capacitor for DCDC Converter (Note 6) 4.7 , comprising a 470 nH inductor and one 4.7 mF capacitor as described in the basic application schematic , device from over voltage spike and a minimum of 4.7 mF capacitor is required. The input capacitor should
ON Semiconductor
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47 MF CAPACITOR

Abstract: MH400 (MH4001 made by Mitsubishi Rayon). NOTES l A bypass capacitor (0.1 mF) is connected to the lead at a position within 2 mm from the lead end, and a 4.7 mF capacitor is also connected nearby the power supply , input signal at 156 Mbps (Bi-phase signal) *3: A 3 pF capacitor is connected to GND as a capacitive
Hamamatsu
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S7727 L7726 47 MF CAPACITOR MH400 KPICA0029EA

10mH inductor

Abstract: 1N4148 SOT-23 1 C5 4.7 mF Capacitor, Tan, 6.3 V 1206 Multi-Source 8 1 C9 , mF. e. C5, C9 = 4.7 mF. f. All other capacitors as noted. FIGURE 1. Schematics of Si9136 Demo , , Tan, 20 V CDR74B Vishay Sprague 10 1 C11 1 mF Capacitor, Cer 1206 Multi-Source 11 1 C12 120 mF Capacitor, Cer 0805 Multi-Source 12 2 D1, D3 , C8 Q5 Si2304DS DHFY L3, 10 mH FB3 VL LXFY D4, D1FS4 C10 100 mF D5, D1FS4
Vishay Siliconix
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CMPD2836 10mH inductor 1N4148 SOT-23 C12120 Augat N-CHANNEL MOSFET 30V 2A SOT-23 WSL2512-0 9136DB 293D337X96R3E2T 595D336X003RR2T 293D475X9035C2T 595D007X002SR2T
Abstract: '¢ Uses 470 nH Inductor and 4.7 mF Capacitor for â'¢ NCP6361 Bypass Enable BPEN VCON MARKING , 0.47 mH 4.7 â' 33 mF Co Output Capacitor for DCDC Converter (Note 5) F = 6 MHz , ' 220 mF Cin Input Capacitor for DCDC Converter (Note 5) 4.7 10 mH 1 mH mF , comprising a 470 nH inductor and one 4.7 mF capacitor as described in the basic application schematic , voltage spike and a minimum of 4.7 mF capacitor is required. The input capacitor should be located as ON Semiconductor
Original
NCP6361A NCP6361B NCP6361/D
Abstract: '¢ Uses 470 nH Inductor and 4.7 mF Capacitor for â'¢ NCP6361 Bypass Enable BPEN VCON MARKING , DCDC Converter (Note 5) F = 3.429 MHz, L = 1 mH 4.7 â' 33 mF Co Output Capacitor , Capacitor for DCDC Converter (Note 5) 4.7 10 mH 1 mH mF Functional operation above the , optimized for a typical output filter comprising a 470 nH inductor and one 4.7 mF capacitor as described in , the device from over voltage spike and a minimum of 4.7 mF capacitor is required. The input capacitor ON Semiconductor
Original

NCP6361 D

Abstract: , L = 0.47 mH 4.7 â' 33 mF Co Output Capacitor for DCDC Converter (Note 5) F = , â' 220 mF Cin Input Capacitor for DCDC Converter (Note 5) 4.7 10 mH 1 , a typical output filter comprising a 470 nH inductor and one 4.7 mF capacitor as described in the , voltage spike and a minimum of 4.7 mF capacitor is required. The input capacitor should be located as , V to 3.50 V) 3.429 / 6 MHz Selectable Switching Frequency Uses 470 nH Inductor and 4.7 mF
ON Semiconductor
Original
NCP6361 D

5C0A

Abstract: AD1585BRTZ loading conditions. With a simple 4.7 mF capacitor attached to the input and a 1 mF capacitor applied to , requirements. For best transient response, add a 0.1 mF capacitor in parallel with the 4.7 mF capacitor. While a 1 mF output capacitor can provide stable performance for all loading conditions, the AD1582 can operate under low (­100 mA < I OUT < +100 mA) current conditions with just a 0.2 mF output capacitor. The 4.7 mF capacitor on the input can be reduced to 1 mF in this condition. Unlike conventional shunt
Analog Devices
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5C0A AD1585BRTZ SOT-23 R2C 3a0a SOT23 transistor R2C transistor R1Z AD158 AD1582/AD1583/AD1584/AD1585 AD1582/ AD1583/ AD1584/ AD1585

an-717 national

Abstract: C1995 supply each device should have a ceramic capacitor in the range 0 1 mF to 0 47 mF or similar In addition there should be a charge storage capacitor electrically close This should be similar to an aluminum electrolytic in the range of 4 7 mF to 15 mF Figure 2 shows a satisfactory 2-layer PC board , mF capacitor C2­C5 e 0 47 mF capacitor FIGURE 2 2-Layer PC Board Layout (Continued) 3
National Semiconductor
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an-717 national C1995 NM27C010N90 national eprom 11059 D-82256

capacitor 2200 mf

Abstract: Dale Resistor , C22 0.1 mF Capacitor 805 VJ0805104KXXAT Vishay Vitramon 4 3 C6, C12, C23 4.7 mF Capacitor 1206 GRM42-2X5R475K16 Murata 5 1 C7 27 pF Capacitor 805 , 1000 mF Capacitor, 1000 mF/10 V Radial-Lead EKE00DD410C00 Vishay Roederstein 1 3 2 , C13 0.47 mF Capacitor 805 VJ0805474KXXAT Vishay Vitramon 9 5 C17, C18, C19 2200 mF Capacitor, 2200 mF/10 V Radial-Lead EKE00FI422C00 Vishay Roederstein 10 4
Vishay Siliconix
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SUD50N03-10 CRCW08053002FRT1 capacitor 2200 mf Dale Resistor capacitor 1000 MF dale resistor code DIFS4 9143DB CRCW08052003FRT1 CRCW080551R0FRT1 CRCW08055100FRT1
Abstract: Protections Stable with a 4.7 mF Ceramic Output Capacitor Available in XDFN8 1.6 x 1.2, 04P 8â'pin package , minimum 4.7 mF ceramic capacitor is needed from this pin to ground to assure stability. IN â , ) Thermal A 4.7 mF capacitor either ceramic or tantalum is recommended and should be connected as close , Input Current VEN = 5.5 V IEN Turnâ'on Time COUT = 4.7 mF, from assertion EN pin to 98 , 2.098 2.096 2.094 2.092 2.090 â'40 â'20 0 VIN = VEN TA = 25°C COUT = 4.7 mF 2.0 ON Semiconductor
Original
NCP706 711AA NCP706/D

SCHEMATIC simple dimmer

Abstract: of the BYPASS pin capacitor. The full power setting is selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The BYPASS pin , the larger devices, the LYT4x11 power gain is not programmable. Use a 47 mF capacitor for the , capacitor value of 47 or 4.7 mF is sufficient for both high frequency decoupling and energy storage. In , bias supply via R17. Capacitor C8 also selects the output power mode (47 mF for reduced power was
Power Integrations
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SCHEMATIC simple dimmer LYT4211-4218/4311-4318 LYT4211-LYT4218 LYT4311-LYT4318 11E/L 12E/L 13E/L
Abstract: of the BYPASS pin capacitor. The full power setting is selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The BYPASS pin , the larger devices, the LYT4x11 power gain is not programmable. Use a 47 mF capacitor for the , capacitor value of 47 or 4.7 mF is sufficient for both high frequency decoupling and energy storage. In , bias supply via R17. Capacitor C8 also selects the output power mode (47 mF for reduced power was Power Integrations
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15E/L 16E/L 17E/L 18E/L 14E/L LYT4221-4228/4321-4328

LYTSwitch

Abstract: LYT4221-LYT4228 selected with the value of the BYPASS pin capacitor. The full power setting is selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The , ) threshold. Unlike the larger devices, the LYT4x11 power gain is not programmable. Use a 47 mF capacitor , capacitor value of 47 or 4.7 mF is sufficient for both high frequency decoupling and energy storage. In , bias supply via R17. Capacitor C8 also selects the output power mode (47 mF for reduced power was
Power Integrations
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LYT4221-LYT4228 LYTSwitch LYT4321-LYT4328
Abstract: selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The BYPASS pin capacitor sets both the internal power gain as well as the , . Use a 47 mF capacitor for the LYT4x21. FEEDBACK Pin Current Characteristic. The FEEDBACK pin , capacitor value of 47 or 4.7 mF is sufficient for both high frequency decoupling and energy storage. In , provided from the bias supply via R19 and D5. Capacitor C8 also selects the output power mode (47 mF for Power Integrations
Original
EN61000-3-2

LYTSwitch

Abstract: selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The BYPASS pin capacitor sets both the internal power gain as well as the , . Use a 47 mF capacitor for the LYT4x21. FEEDBACK Pin Current Characteristic. The FEEDBACK pin , capacitor value of 47 or 4.7 mF is sufficient for both high frequency decoupling and energy storage. In , provided from the bias supply via R19 and D5. Capacitor C8 also selects the output power mode (47 mF for
Power Integrations
Original

LYT4211

Abstract: LYT4311-LYT4318 the value of the BYPASS pin capacitor. The full power setting is selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The BYPASS pin , the larger devices, the LYT4x11 power gain is not programmable. Use a 47 mF capacitor for the LYT4x11 , current it takes from the DRAIN pin. A bypass capacitor value of 47 or 4.7 mF is sufficient for both high , via R17. Capacitor C8 also selects the output power mode (47 mF for reduced power was selected to
Power Integrations
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LYT4211 Application scr Light Dimmer with Schematic Triac 3 kw dimmer schematic diagram scr dimmer circuit diagram triac mw 131 LYT4311-4318

Phototransistor Til 196

Abstract: selected with the value of the BYPASS pin capacitor. The full power setting is selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The , ) threshold. Unlike the larger devices, the LYT4x11 power gain is not programmable. Use a 47 mF capacitor , capacitor value of 47 or 4.7 mF is sufficient for both high frequency decoupling and energy storage. In , bias supply via R17. Capacitor C8 also selects the output power mode (47 mF for reduced power was
Power Integrations
Original
Phototransistor Til 196

LYTSwitch

Abstract: Triac 3 kw dimmer schematic diagram the BYPASS pin capacitor. The full power setting is selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The BYPASS pin capacitor sets , devices, the LNK4x11 power gain is not programmable. Use a 47 mF capacitor for the LNK4x11. Switching , current it takes from the DRAIN pin. A bypass capacitor value of 47 or 4.7 mF is sufficient for both high , via R17. Capacitor C8 also selects the output power mode (47 mF for reduced power was selected to
Power Integrations
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LYT4317 LYT4317E PI-6841-081512 2.4 kw filter dimmer LNK421 3 phase SCR dimmer LYT4211-4217/4311-4317

LYTSwitch

Abstract: of the BYPASS pin capacitor. The full power setting is selected with a 4.7 mF capacitor and the reduced power setting (for higher efficiency) is selected with a 47 mF capacitor. The BYPASS pin , the larger devices, the LYT4x11 power gain is not programmable. Use a 47 mF capacitor for the , capacitor value of 47 or 4.7 mF is sufficient for both high frequency decoupling and energy storage. In , bias supply via R17. Capacitor C8 also selects the output power mode (47 mF for reduced power was
Power Integrations
Original
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