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5605861 Phoenix Contact VLC-IRF-RTM
09130540LXN Littelfuse Inc TERMINAL/ TYPE 539
RNC55H5390BSB14 Vishay Dale ERC-55 539 .1% T-2 RNC55H5390B

irf 539 Datasheets Context Search

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2007 - C4840

Abstract: tennelec ortec 457 tennelec tc-454 irf 539 ortec TAC ortec 454 E3059-500 Hamamatsu microchannel plates irf 539 DATA
Text: % (-64) GHigh Speed Rise Time: 200 ps (-61), 180 ps (-63/-64) IRF A (Instrument Response Function , Dark Count E Rise Time F Time Fall Time G Response IRF (FWHM) A Min. 400 - 1 × 105 - - , NOTE: A IRF stands for Instrument Response Function which is a convolution of the pulse function (H(t) of the measuring system and the excitation function (E(t) of a laser. The IRF is given by the following formula: IRF = H(t) × E(t) We specify the IRF as an FWHM of the time distribution taken by using


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PDF R3809U-61/-63/-64 SE-171-41 TPMH1295E03 C4840 tennelec ortec 457 tennelec tc-454 irf 539 ortec TAC ortec 454 E3059-500 Hamamatsu microchannel plates irf 539 DATA
2015 - ortec 457

Abstract: No abstract text available
Text: QE: 12 % (-61), 36 % (-63), 40 % (-64) GHigh Speed Rise Time: 200 ps (-61), 180 ps (-63/-64) IRF A , ) Rise Time G Time Fall Time H Response IRF (FWHM) A Cathode Sensitivity Min. 400 — — 1 , ps NOTE: A IRF stands for Instrument Response Function which is a convolution of the δ pulse function (H(t) of the measuring system and the excitation function (E(t) of a laser. The IRF is given by the following formula: IRF = H(t) × E(t) We specify the IRF as an FWHM of the time distribution


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PDF R3809U-61/-63/-64 TPMHB0756EA TPMHB0179EB R3809U-64 R3809U-61 SE-164 TPMH1295E07 B1201 ortec 457
2008 - tennelec tc-454

Abstract: 10-32 UNC-2B ortec 454 TACCA0278EB Dewar ortec TAC R3809U
Text: amplitude points on the tailing edge of the output waveform for full cathode illumination. G I.R.F . stands , system and the excitation function (E(t) of a laser. The I.R.F . is given by the following formula: I.R.F . = H(t) × E(t) We specify the I.R.F . as an FWHM of the time distribution taken by using the measuring system in Figure 6 that is Hamamatsu standard I.R.F . measurement. It can be temporary estimated by the following equation: ( I.R.F . (FWHM)2 = (T.T.S.)2 + (Tw)2 + (Tj)2 where Tw is the pulse width of the laser


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PDF H10840-68/-69 R3809U-68/-69) TPMHF0499 TACCF0194 TPMOB0198EB TPMHB0179EA R10840-69 SE-171-41 TPMH1312E01 tennelec tc-454 10-32 UNC-2B ortec 454 TACCA0278EB Dewar ortec TAC R3809U
2009 - tennelec tc-454

Abstract: tennelec ortec TAC Tektronix 11802 C4725 ortec TC-454 R3809U
Text: amplitude points on the tailing edge of the output waveform for full cathode illumination. G I.R.F . stands , system and the excitation function (E(t) of a laser. The I.R.F . is given by the following formula: I.R.F . = H(t) × E(t) We specify the I.R.F . as an FWHM of the time distribution taken by using the measuring system in Figure 6 that is Hamamatsu standard I.R.F . measurement. It can be temporary estimated by the following equation: ( I.R.F . (FWHM)2 = (T.T.S.)2 + (Tw)2 + (Tj)2 where Tw is the pulse width of the laser


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PDF H10840-68/-69 TACCF0194 LH10840-68/-69 TPMHF0499 R3809U-68/-69 H10840-68-69 TPMOB0198EC TPMHB0179EA H10840-69 H10840-68 tennelec tc-454 tennelec ortec TAC Tektronix 11802 C4725 ortec TC-454 R3809U
2015 - tennelec tc-454

Abstract: ortec 454 E3059-500 ortec 457
Text: Time: 160 ps IRF (Instrument Response Function) A: 55 ps (FWHM) GLow Noise GCompact Profile Useful , at -3000 V Anode Dark Counts at -3000 V Time Response Rise Time G Fall Time H I.R.F . (FWHM) I , illumination. I I.R.F . stands for Instrument Response Function which is a convolution of the δ pulse function (H(t) of the measuring system and the excitation function (E(t) of a laser. The I.R.F . is given by the following formula: I.R.F . = H(t) × E(t) J We specify the I.R.F . as an FWHM of the time


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PDF R3809U-50 TPMHB0178EB R3809U-50 SE-164 TPMH1067E11 B1201 tennelec tc-454 ortec 454 E3059-500 ortec 457
2007 - gas solenoid valve

Abstract: tennelec ortec 457 R3809U irf 539 tektronix 454 tennelec tc-454 ortec 454 c4840 ortec
Text: IRF stands for Instrument Response Function which is a convolution of the pulse function (H(t) of the measuring system and the excitation function (E(t) of a laser. The IRF is given by the following formula: IRF = H(t) × E(t) We specify the IRF as an FWHM of the time distribution taken by using the measuring system in Figure 6 that is Hamamatsu standard IRF measurement. It can be temporary estimated by the following equation: ( IRF (FWHM)2 = (TTS)2 + (Tw)2 + (Tj)2 where Tw is the pulse width of the


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PDF R3809U-68/-69 C10221 LR3809U-68/-69 TPMHF0499 LC10221 TACCF0194 TPMOB0198EA SE-171-41 TPMH1293E03 gas solenoid valve tennelec ortec 457 R3809U irf 539 tektronix 454 tennelec tc-454 ortec 454 c4840 ortec
2002 - ortec 457

Abstract: Photocathode S-25 ortec 454 NAIG E511 TC-454 tennelec R3809U-50 E3059-500 tennelec tc454 pc9801 nec
Text: ) I.R.F . (FWHM)7) s-1 75 Anode Dark Counts at ­3000 V Time Response Max. Unit Min , points on the tailing edge of the output waveform for full cathode illumination. 7) I.R.F . stands for , the excitation function (E(t) of a 8) 9) 10) 11) laser. The I.R.F . is given by the following formula: I.R.F . = H(t) × E(t) We specify the I.R.F . as an FWHM of the time distribution taken by using the measuring system in Figure 13 that is Hamamatsu standard I.R.F . measurement. It can be temporary


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PDF R3809U-50 TPMHF0034 TPMHB0178EB SE-171-41 TPMH1067E07 ortec 457 Photocathode S-25 ortec 454 NAIG E511 TC-454 tennelec E3059-500 tennelec tc454 pc9801 nec
IRF 1640

Abstract: GD4049B IRF 1640 G GAL16V8-20LNC gal22cv10 HA2-2725-5 HA2-2655-5 HA2-2650-2 irf 2030 GAL22CV10-10LVC
Text: FDC92C39TP SMC 24827 FDC92C81P SMC 473 FDC9793UATTP SMC 116 FDC9793UP SMC 539 FDC9793P SMC 4 FDC9797CD SMC 1 FDC9797LJP SMC 346 FDC9797P SMC 340 FSA3295M.02 NSC 16 G1829HEX IRF 30 G1849HEX IRF 329 G18S6HEX IRF 316 G1992HEX IRF 15 G202CK HAD 88 G2032HEX IRF 30 G2Û87HEX IRF 40 G20V8Q25B1NNC NSC 1152 G2QV8S15BCMQVC NSC 2357 G20V8S25BCRA.VI NSC 690 G2289HEX IRF 86 G 22V10L15BCIWC NSC 1765 G22V10U5BHR/W NSC 139 G2301HEX IRF 1504 G94-2403 IRF 60 G94-2418 IRF 20 GAL16V8-20LNC NSC 1188 GAL16V8-20LVC NSC


OCR Scan
PDF FDC92C36BP FDC92C36P FDC92C38BP FDC92C33BT FDC92C39BUP FDC92C39BTBI FDC92C39BTCD FDC92C39BTLJP FDC92C39BTP FDC92C39LJP IRF 1640 GD4049B IRF 1640 G GAL16V8-20LNC gal22cv10 HA2-2725-5 HA2-2655-5 HA2-2650-2 irf 2030 GAL22CV10-10LVC
1998 - ortec 457

Abstract: PLP-01 canberra preamplifier TC-454 irf 2205 shg 850 R5916U-50 LIDAR radar IRF 715 Light Detector laser
Text: Time 700 I.R.F . (FWHM)8) T.T.S. (FWHM) 959) ps 9010) ps Value Unit -3400 , tailing edge of the output waveform under full photocathode illumination. 8) IRF stands for Instrument , exciation function (E(t) of a laser. The IRF is given by the following formula: IRF = H(t) E(t) 9) We specity the IRF as an FWHM of the time distribution taken by using the measuring apparatus in Figure 7 that is Hamamatsu standard IRF measuring set-up. It can be estimated by the following equation: ( IRF


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PDF R5916U-50 TPMHB0244EA TPMHB0245EB 20mV/div. -3000V S-164-40 TPMH1102E05 ortec 457 PLP-01 canberra preamplifier TC-454 irf 2205 shg 850 LIDAR radar IRF 715 Light Detector laser
2015 - IRF 501

Abstract: No abstract text available
Text: I I.R.F . (FWHM) J Min. 100 — 1 × 105 — — — — — Typ. 150 52 3 × 105 , edge of the output waveform under full photocathode illumination. J I.R.F . stands for Instrument , exciation function (E(t) of a laser. The I.R.F . is given by the following formula: I.R.F . = H(t)∗ E(t) K We specity the I.R.F . as an FWHM of the time distribution taken by using the measuring apparatus in Figure 7 that is Hamamatsu standard I.R.F . measuring set-up. It can be estimated by the


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PDF R5916U-50 R5916U-50) TPMHB0244EA TPMHB0245EB SE-164 TPMH1102E10 B1201 IRF 501
MD8402

Abstract: IRF 5310 MD8412 MD8402 equivalent irf 648 MD8413 010B IEEE1212 P1394
Text: .25 3-2-16 ITF/ IRF Data Register . 26 3-2-17 IRF Data Register , . 51 Figure 5-3-9 Register Operation (ARF) for 8-Bit Width DMA Access , .61 Figure 5-7-5 IRF Reception Flow , : Little-endian bit (RW- Initial value: 0b) 0 1 Bit 29~28 = Data of ATF, ARF, ITF, IRF buffer are handled


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PDF MD8412 MD8402 IRF 5310 MD8412 MD8402 equivalent irf 648 MD8413 010B IEEE1212 P1394
MD8404

Abstract: irf 648 8412b IEEE1212 MD8402 MD8412B P1394 IRF 534
Text: . 25 3-2-16 ITF/ IRF Data Register . 26 3-2-17 IRF Data Register , . 72 Figure 5-3-9 Register Operation (ARF) for 8-Bit Width DMA Access , ="1") .86 Figure 5-7-8 IRF Reception Flow (auto-mode & SyncEn , ) .52 Table 4-7-6 viii IRF Reception Flow


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PDF MD8412B 16-bit 32-bit 64-bit P1394-1995 P1394a MD8404 irf 648 8412b IEEE1212 MD8402 MD8412B P1394 IRF 534
2013 - A1060

Abstract: No abstract text available
Text: IRF www.vishay.com Vishay Dale Inductors, Epoxy Conformal Coated, Uniform Roll Coated , : IRF -1 = 0.3 g maximum IRF -3 = 0.6 g maximum (1) ENVIRONMENTAL PERFORMANCE TEST CONDITIONS , ] Max. C Max. B Max. A (MAX.) B (MAX.) C (MAX.) D IRF -1 0.260 [6.60] 0.120 [3.05] 0.330 [8.38] 0.0200 ± 0.0015 [0.508 ± 0.038] IRF -3 0.385 [9.78] 0.170 [4.32 , FREQUENCY L AND Q SRF MIN. TOL. Q MODEL (μH) (%) MIN. (MHz) (MHz) (1) IRF -1 0.10 ± 20 40


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PDF RS/296 MIL-STD-202, 2002/95/EC 2002/95/EC. 2002/95/EC 2011/65/EU. JS709A 02-Oct-12 A1060
2009 - irf 940

Abstract: IRF 470 irf 560 irf 145 a IRF 47 IRF 860 transistor IRF 630 irf 480 IRF 640 IRF1
Text: IRF Vishay Dale Inductors, Epoxy Conformal Coated, Uniform Roll Coated, Axial Leaded FEATURES , Lead: Tinned copper Core: Ferrite D MODEL MECHANICAL SPECIFICATIONS IRF -1 Terminal Strenght: 5 pounds pull per MIL-STD-202, method 211, test condition A Weight: IRF -1 = 0.3 g maximum IRF , megacycle meter, model 59 · Whearstone bridge Note (1) Test procedures per MIL-PRF-15305 IRF -3 C , MODEL IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF


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PDF RS/296 2002/95/EC MIL-STD-202, 63lectual 18-Jul-08 irf 940 IRF 470 irf 560 irf 145 a IRF 47 IRF 860 transistor IRF 630 irf 480 IRF 640 IRF1
2008 - IRF 470

Abstract: irf 940 irf 560 irf 480 IRF 830 equivalent
Text: IRF Vishay Dale Inductors Epoxy Conformal Coated Uniform Roll Coated FEATURES · , Coating: Epoxy-uniform roll coated Lead: Tinned copper Core: Ferrite MODEL IRF -1 MECHANICAL SPECIFICATIONS Terminal Strenght: 5 pounds pull per MIL-STD-202, Method 211, Test Condition A Weight: IRF -1 = 0.3 gram maximum IRF -3 = 0.6 gram maximum IRF -3 C Max. A (Max.) 0.260 [6.60] 0.385 , . MAXIMUM (MHz) (MHz) (Ohms) IRF -1 0.10 ± 20 % 40 25.0 400.0 0.06 IRF -1 0.12 ± 20 % 40 25.0


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PDF RS/296 MIL-STD-202, 18-Jul-08 IRF 470 irf 940 irf 560 irf 480 IRF 830 equivalent
2012 - irf 940

Abstract: irf 540 irf 560
Text: IRF www.vishay.com Vishay Dale Inductors, Epoxy Conformal Coated, Uniform Roll Coated, Axial , Weight: IRF -1 = 0.3 g maximum IRF -3 = 0.6 g maximum ENVIRONMENTAL PERFORMANCE TEST CONDITIONS A , C Max. B Max. Resistance to Soldering Heat Resistance to Solvents MODEL IRF -1 IRF -3 A , SPECIFICATIONS IND. TEST FREQUENCY L AND Q SRF MIN. TOL. Q MODEL (H) (%) MIN. (MHz) (MHz) (1) IRF -1 0.10 ± 20 40 25.0 400.0 IRF -1 0.12 ± 20 40 25.0 400.0 IRF -1 0.15 ± 20 40 25.0 400.0 IRF -1 0.18 ± 20 40 25.0 400.0


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PDF MIL-STD-202, RS/296 2002/95/EC 2011/65/EU 2002/95/EC. 2002/95/EC 2011/65/EU. 12-Mar-12 irf 940 irf 540 irf 560
2012 - irf 480

Abstract: IRF 024 IRF 47
Text: IRF -36 Vishay Dale Inductors, Epoxy Conformal Coated, Axial Leaded FEATURES · High , Temperature Rise: + 20 °C MODEL IRF -36 A (MAX.) 0.236 [6.0] 0.157 [4.0] B (MAX.) C (MAX.) 0.551 [14.0] D (MAX.) 0.026 [0.65] STANDARD ELECTRICAL SPECIFICATIONS MODEL IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IND. (H) 0.10 0.12 0.15 0.18 0.22 0.27 0.33 0.39 0.47 0.56 0.68 0.82 1.0


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PDF IRF-36 11-Mar-11 irf 480 IRF 024 IRF 47
2014 - Not Available

Abstract: No abstract text available
Text: IRF -24 www.vishay.com Vishay Dale Inductors, Epoxy Conformal Coated, Axial Leaded FEATURES , 4th 2nd 3rd ENVIRONMENTAL SPECIFICATIONS MODEL Maximum Temperature Rise: + 20 °C IRF , ] 0.020 ± 0.002 [0.50 ± 0.05] STANDARD ELECTRICAL SPECIFICATIONS MODEL IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IND. (μH) 0.10 0.12 0.15 0.18 0.22


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PDF IRF-24 2002/95/EC. 2002/95/EC 2011/65/EU. JS709A 02-Oct-12
2012 - Not Available

Abstract: No abstract text available
Text: IRF -36 Vishay Dale Inductors, Epoxy Conformal Coated, Axial Leaded FEATURES • High , ] 0.026 [0.65] IRF -36 STANDARD ELECTRICAL SPECIFICATIONS MODEL IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IND. (μH) 0.10 0.12 0.15 0.18 0.22 , 670 640 620 590 550 530 www.vishay.com 1 IRF -36 Inductors, Epoxy Conformal Coated, Axial


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PDF IRF-36 2002/95/EC. 2002/95/EC 2011/65/EU. JS709A 02-Oct-12
2013 - Not Available

Abstract: No abstract text available
Text: IRF -36 www.vishay.com Vishay Dale Inductors, Epoxy Conformal Coated, Axial Leaded FEATURES , ] 0.026 [0.65] IRF -36 STANDARD ELECTRICAL SPECIFICATIONS MODEL IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IRF -36 IND. (μH) 0.10 0.12 0.15 0.18 0.22 , ?91000 IRF -36 www.vishay.com Vishay Dale STANDARD ELECTRICAL SPECIFICATIONS IND. (μH) 10 12 15


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PDF IRF-36 2002/95/EC. 2002/95/EC 2011/65/EU. JS709A 02-Oct-12
2006 - transistor IRF 630

Abstract: irf 560 IRF 470 IRF 830 equivalent irf 940 Equivalent IRF 740 irf 830 datasheet IRf 425 irf 145 a i c irf 740
Text: IRF Vishay Dale Inductors Epoxy Conformal Coated Uniform Roll Coated FEATURES · , Coating: Epoxy-uniform roll coated Lead: Tinned copper Core: Ferrite MODEL IRF -1 MECHANICAL SPECIFICATIONS Terminal Strenght: 5 pounds pull per MIL-STD-202, Method 211, Test Condition A Weight: IRF -1 = 0.3 gram maximum IRF -3 = 0.6 gram maximum IRF -3 C Max. A (Max.) 0.260 [6.60] 0.385 , . MAXIMUM (MHz) (MHz) (Ohms) IRF -1 0.10 ± 20 % 40 25.0 400.0 0.06 IRF -1 0.12 ± 20 % 40 25.0


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PDF RS/296 MIL-STD-202, 08-Apr-05 transistor IRF 630 irf 560 IRF 470 IRF 830 equivalent irf 940 Equivalent IRF 740 irf 830 datasheet IRf 425 irf 145 a i c irf 740
2011 - irf 560

Abstract: No abstract text available
Text: IRF -24 Vishay Dale Inductors, Epoxy Conformal Coated, Axial Leaded FEATURES · High , Temperature Rise: + 20 °C MODEL IRF -24 A (MAX.) 0.157 [4.0] 0.118 [3.0] 0.98 [25.0] Min. 1.22 [31.0] Max , MODEL IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IND. (H) 0.10 0.12 0.15 0.18 , -Feb-11 For technical questions, contact: magnetics@vishay.com IRF -24 Vishay Dale Inductors, Epoxy


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PDF IRF-24 2002/95/EC 11-Mar-11 irf 560
2006 - IRF 504

Abstract: bq 1110 IRF 501 code b15 Q-meter ez 920
Text: IRF Vishay Dale Inductors Epoxy Conformal Coated Uniform Roll Coated FEATURES · , . MATERIAL SPECIFICATIONS Coating: Epoxy-uniform roll coated Lead: Tinned copper Core: Ferrite IRF -1 IRF , , Test Condition A Weight: IRF -1 = 0.3 gram maximum IRF -3 = 0.6 gram maximum ENVIRONMENTAL PERFORMANCE , 950 900 900 815 740 700 655 630 595 575 555 530 500 470 425 370 MODEL IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF -1 IRF


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PDF RS-296 MIL-STD-202, 13-Oct-06 IRF 504 bq 1110 IRF 501 code b15 Q-meter ez 920
2012 - IRF 47

Abstract: IRF 315 irf 740 IRf 425 IRF 470 data irf IRF24
Text: IRF -24 Vishay Dale Inductors, Epoxy Conformal Coated, Axial Leaded FEATURES · High , Temperature Rise: + 20 °C MODEL IRF -24 A (MAX.) 0.157 [4.0] 0.118 [3.0] 0.98 [25.0] Min. 1.22 [31.0] Max , MODEL IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IND. (H) 0.10 0.12 0.15 0.18 , -Feb-11 For technical questions, contact: magnetics@vishay.com IRF -24 Vishay Dale Inductors, Epoxy


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PDF IRF-24 2002/95/EC 2011/65/EU 2002/95/EC. 2002/95/EC 2011/65/EU. 12-Mar-12 IRF 47 IRF 315 irf 740 IRf 425 IRF 470 data irf IRF24
2010 - IRF 470

Abstract: irf 680 irf 560 IRF 950 IRF 47 irf 1150 IRF-24 irf 630 IRF 3315 IRf 425
Text: IRF -24 Vishay Dale Inductors, Epoxy Conformal Coated, Axial Leaded FEATURES · High , [31.0] Max. MODEL IRF -24 A (MAX.) 0.157 [4.0] B (MAX.) 0.118 [3.0] C (MAX.) 0.394 [10.0] D (MAX.) 0.020 [0.5] STANDARD ELECTRICAL SPECIFICATIONS MODEL IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IRF -24 IND. (H) 0.10 0.12 0.15 0.18 0.22 0.27 0.33 0.39 0.47 0.56 0.68 0.82 1.0


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PDF IRF-24 2002/95/EC 18-Jul-08 IRF 470 irf 680 irf 560 IRF 950 IRF 47 irf 1150 IRF-24 irf 630 IRF 3315 IRf 425
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