NEW DATABASE - 350 MILLION DATASHEETS FROM 8500 MANUFACTURERS
NEW DATABASE - 350 MILLION DATASHEETS FROM 8500 MANUFACTURERS
| Catalog Datasheet Results | Type | Document Tags |
| Abstract: 1540 < 15.0 (200 mT, 100 kHz, 100 癈) B66293G0000X187 B66293G0000X187 Calculation factors (for formulas, see "E cores: general information") EELP 58: Material Validity range: Calculation of saturation current , ) Calculation factors (for formulas, see "E cores: general information") EILP 58: Material Validity range: Calculation of saturation current K1 (25 癈) N87 Relationship between air gap � AL value K2 (25 癈 , warnings Mechanical stress and mounting Ferrite cores have to meet mechanical requirements during ... | Original |
5 pages, |
ferrite n87 transformer B66293P0000X187 B66293G0000X187 B66293 Al value of ferrite core ferrite TRANSFORMER calculation B66293G B66293P B66293G abstract |
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| Abstract: < 26.0 (200 mT, 100 kHz, 100 癈) B66295G0000X187 B66295G0000X187 Calculation factors (for formulas, see "E cores: general information") EELP 64: Material Validity range: Calculation of saturation current K1 , ) B66295P0000X187 B66295P0000X187 (I core) Calculation factors (for formulas, see "E cores: general information") EILP 64: Material Validity range: Calculation of saturation current K1 (25 癈) N87 Relationship between , Ferrites and accessories Cautions and warnings Mechanical stress and mounting Ferrite cores have to meet ... | Original |
5 pages, |
B66295P0000X187 B66295P0000X149 B66295G0000X187 B66295G0000X149 B66295 ferrite n87 ferrite TRANSFORMER calculation Epcos N87 ferrite B66295G B66295P B66295G abstract |
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| Abstract: the differential termination on the secondary of the transformer. As the calculation shows, below 251 , ideal 1:4 impedance ratio transformer. To start the calculation, use the return loss number at the , example of a calculation for the secondary termination of the transformer. The return loss is found as , order to perform signal processing in the digital domain. However, designing the transformer front end , 3. Determine the ADC baseline performance. 4. Select transformer and passive components to ... | Original |
8 pages, |
AD9215 AD9235 AD9236 AD9237 ADT1-1WT AN-742 AN-827 AN-835 AN-935 injection transformer step up transformer 12 AD9246 Intermediate frequency transformer AD9226 transformer calculation AN-935 abstract |
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| Abstract: The amplifier exhibited low efficiency, hot ferrite in the output transformer balun, and poor , aperture ferrite bead was chosen for the input transformer. Brass tubing was used for the secondary and the primary was wound inside the brass tubes to provide a very broadband balanced transformer design , ferrite cores evaluated. It is inexpensive and easy to reproduce. The input transformer design was , under the patent rights of APT or others. 1 Figure 1 Input Match Calculation The typical HF ... | Original |
8 pages, |
"class AB Linear" 50mhz ARF448 amidon APT448A 300w amplifier T942 schematic rf Power supply 500w plasma 300w mosfet ferrite TRANSFORMER calculation hf class AB power amplifier mosfet 1000 watt ferrite transformer APT9702 amidon toroid core APT9802 APT9802 abstract |
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| Abstract: CCFL Transformer Application Note Cold Cathode Fluorescent Lamps (CCFLs) are used to illuminate , voltage DC source of 5-12V. The DC to AC power supply needs a transformer to change low DC input voltage , Diagram Transformer Selection The CCFL lamp manufacturer supplies the following lamp characteristics , ) 5. Current (Ilamp) The first step is to select the transformer according to the power requirement , commonly used to power the CCFL transformer. This topology accommodates a wide input voltage and consists ... | Original |
4 pages, |
toroidal transformer ccfl CTX110652-R CTX210655 CTX210607 CTX110605 CTX210659-R transformer 220 12v schematic 20 pin lcd laptop 14 Royer CTX110659-R ccfl transformer CTX110600 transformer calculation formula datasheet abstract |
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| Abstract: APPLICATION INDUCTOR Introduction Inductors and ferrite are dual element of capacitors. They , of Z S , Z L at the calculation frequency, if these are not pure resistances. SAMWHA ELECTRONICS , Unaffected, not driven into magnetic core saturation, by the through current. Ferrite Inductor Introduction Ferrite inductors has been regarded as the miracle remedies that the EMC magician pulls out of , 0.1 to 0.2 tesla Fig. 2. Basic parameters of a ferrite core. The most interesting characteristic ... | Original |
8 pages, |
samwha RP smps troubleshooting High voltage ferrite inductor circuits smps capacitors samwha ferrite core selection TESLA Manufacturer EMC Ferrite core samwha capacitor smps inductor ferrite toroid ferrite smps inductor SAMWHA FERRITE EMC datasheet abstract |
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| Abstract: 0.095 0.175 0.0638 0.02 0 0 0.066 PWM IC AND OPTOCOUPLERS Transformer & Line Filter Ferrite , Switching Power Supply/Adaptor MTBF Report CSS65 CSS65 Part No. : Description : 2 X 4 Medical series Date : 2009.04.02 MTBF Model . The calculation is based on MIL-HDBK-217F MIL-HDBK-217F, Notice 1, Appendix A: Parts Count Reliability The prediction were performed with the power supply operating in a , , Linear,1-100 Transistors) Inductive Device (Low power Pulse Transformer) Electronic Filter ... | Original |
1 pages, |
0638 MIL-HDBK-217F regulator mtbf transistor MTBF generic failure rate generic failure rate electronic device Zener Diode tl431 transformer mtbf ferrite TRANSFORMER calculation TL431 zener CSS65 CSS65 abstract |
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| Abstract: 0.475 0.21 0.2552 0.02 0 0 0.066 PWM IC AND OPTOCOUPLERS Transformer & Line Filter Ferrite , Switching Power Supply/Adaptor MTBF Report CSS150 CSS150 SERIES Part No. : Description : 12Vdc/12.5Amp(Sample) Date : 2009.09.21 MTBF Model . The calculation is based on MIL-HDBK-217F MIL-HDBK-217F, Notice 1, Appendix A: Parts Count Reliability The prediction were performed with the power supply operating in a , , Linear,1-100 Transistors) Inductive Device (Low power Pulse Transformer) Electronic Filter ... | Original |
1 pages, |
Zener Diode tl431 transistor TL431 mosfet MTBF generic failure rate general purpose bridge rectifier CSS150 transformer calculation transformer mtbf ferrite TRANSFORMER calculation MIL-HDBK-217F CSS150 abstract |
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| Abstract: one gapped core (dimension g > 0). Calculation factors (for formulas, see "E cores: general information") Material Validity range: Calculation of saturation current K1 (25 °C) N27 , Ferrite cores have to meet mechanical requirements during assembling and for a growing number of , load. As valid for any ceramic material, ferrite cores are brittle and sensitive to any shock, fast , cyclic loads can cause cracks or failure of the ferrite cores. For detailed information see Data Book ... | Original |
4 pages, |
ferrite TRANSFORMER calculation B66377G1000X127 B66377G0000X127 B66377 B66377 abstract |
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| Abstract: Calculation factors (for formulas, see "E cores: general information") Material Relationship between air gap � AL value Calculation of saturation current K1 (25 癈) K2 (25 癈) K3 (25 癈) K4 (25 癈 , mounting Ferrite cores have to meet mechanical requirements during assembling and for a growing number of , load. As valid for any ceramic material, ferrite cores are brittle and sensitive to any shock, fast , cyclic loads can cause cracks or failure of the ferrite cores. For detailed information see Data Book ... | Original |
4 pages, |
B66379G0000X187 B66379G0000X130 B66379G0000X127 B66379F0000X146 B66379 ferrite TRANSFORMER calculation B66379 abstract |
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| Abstract | Saved from | Date Saved | File Size | Type | Download |
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| . Ferrites: Magnetic Design Tool (MDT) The MDT provides material parameters of all available S+M ferrite materials such as hysteresis loop, initial hole for low-distortion and power transformers, low-profile E cores for planar magnetics, EV high-voltage transformers. Preliminary data on the improved materials N87, N30 and T38 are NTC R/T Calculation Program for calculating the R www.datasheetarchive.com/files/siemens/tools/tools.htm |
Siemens | 09/05/1999 | 6.22 Kb | HTM | tools.htm |
| on: #1; This Mathcad file helps the calculation of the external components of a typical discontinuous : #1; #1; #1; Transformer's Efficiency: #1; Maximum Stress on the switching mosfet : - Define the flyback voltage inductance) -The total energy stored in the transformer: Wfly (Energy delivered to the outputs plus the as low as possible because it reduces the efficiency of the transformer and it causes spikes on the % boundary is reached. #1; #1; 11) Transformer Design: The inductor- transformer should be designed to www.datasheetarchive.com/download/1606077-549746ZC/nsc00118.doc |
National | 28/06/2001 | 545.5 Kb | DOC | nsc00118.doc |
| internal resistor across the transformer and the transformer's core and wire size. When used as power splitter, the core of the transformer may saturate at the lower frequency end of the operating band if the increased, and limited by the wire size of the transformer. Q. Suppose my application requires a power splitter is caused by saturation of the transformer, usually a toroidal type. With the present state of transformer technology, distortion is insignificant except at the low end of the specified frequency range www.datasheetarchive.com/files/mini-circuits/html/pwr2-4.htm |
Mini-Circuits | 18/02/2002 | 13.23 Kb | HTM | pwr2-4.htm |
| -Def : 14V, 12V 10W - V5 for heater : 6.3V, 4W 1-1. Transformer Calculation duty cycle ,dc : 50 P = V imin V T V dc L P = 100 V 32 V 0.5 425 = 3.76 A The transformer turn 90 = 0.567 A popular ferrite core as the EER424215 EER424215 EER424215 EER424215 with 1mm air gap has been chosen. A L @ 0 following table is represented the final spec of the transformer, in which all the turns wind - ings SUPPLY , device supply voltage provided by the power transformer after turn-on , in normal conditions www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/4929.htm |
STMicroelectronics | 20/10/2000 | 27.03 Kb | HTM | 4929.htm |
| -Def : +14V, -12V 10W - V5 for Heater : 6.3V, 5W 3-1. Transformer calculation duty cycle, dc : 80V, 12W - V3, -V4 for V-Def : 14V, 12V 10W - V5 for heater : 6.3V, 4W 1-1. Transformer Calculation duty cycle ,dc : 50% max. at minimum mains and nominal output power condition. efficiency h : 0 transformer turn ratio between primary and secondary is: N = N s 1 N P = V o 1 + V Df V R = 50 + 1 90 = 0.567 A popular ferrite core as the EER424215 EER424215 EER424215 EER424215 with 1mm air gap has been chosen. A L @ 0.28 m H/Np 2 www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/4929-v2.htm |
STMicroelectronics | 14/06/1999 | 23.43 Kb | HTM | 4929-v2.htm |
| -Def : +14V, -12V 10W - V5 for Heater : 6.3V, 5W 3-1. Transformer calculation duty cycle, dc : 80V, 12W - V3, -V4 for V-Def : 14V, 12V 10W - V5 for heater : 6.3V, 4W 1-1. Transformer Calculation duty cycle ,dc : 50% max. at minimum mains and nominal output power condition. efficiency h : 0 transformer turn ratio between primary and secondary is: N = N s 1 N P = V o 1 + V Df V R = 50 + 1 90 = 0.567 A popular ferrite core as the EER424215 EER424215 EER424215 EER424215 with 1mm air gap has been chosen. A L @ 0.28 m H/Np 2 www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/4929-v1.htm |
STMicroelectronics | 02/04/1999 | 23.46 Kb | HTM | 4929-v1.htm |
| - V5 for heater : 6.3V, 4W 1-1. Transformer Calculation duty cycle ,dc : 50% max. at Heater : 6.3V, 5W 3-1. Transformer calculation duty cycle, dc : 50% max. at min. mains transformer turn ratio between primary and secondary is: N = N s 1 N P = V o 1 + V Df V R = 50 + 1 90 = 0.567 A popular ferrite core as the EER424215 EER424215 EER424215 EER424215 with 1mm air . In the following table is represented the final spec of the transformer, in which all the turns www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/4929-v3.htm |
STMicroelectronics | 25/05/2000 | 25.35 Kb | HTM | 4929-v3.htm |
| . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 III.2 CALCULATION OF EXTERNAL COMPONENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 III.2.1 Transformer calculation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 III.2.1.1 Transformer specification .1 - Transformer calculation The following important features must be consid- ered to calculate the . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 III.2.2.1 Current limit calculation www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/1614.htm |
STMicroelectronics | 20/10/2000 | 55.18 Kb | HTM | 1614.htm |
| CALCULATION OF EXTERNAL COMPONENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 III.2.1 Transformer calculation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 III.2.1.1 Transformer specification specifications HIGH PERFORMANCE DRIVER CIRCUITS FOR S.M.P.S 20/33 III.2.1 - Transformer calculation The . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 III.2.2.1 Current limit calculation www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/1614-v1.htm |
STMicroelectronics | 02/04/1999 | 49.57 Kb | HTM | 1614-v1.htm |
| CALCULATION OF EXTERNAL COMPONENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 III.2.1 Transformer calculation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 III.2.1.1 Transformer specification specifications HIGH PERFORMANCE DRIVER CIRCUITS FOR S.M.P.S 20/33 III.2.1 - Transformer calculation The . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 III.2.2.1 Current limit calculation www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/1614-v2.htm |
STMicroelectronics | 14/06/1999 | 49.53 Kb | HTM | 1614-v2.htm |