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Part Manufacturer Description Datasheet BUY
LTC1064-4 Linear Technology IC SWITCHED CAPACITOR FILTER, BUTTERWORTH, LOWPASS, PDIP14, Active Filter visit Linear Technology - Now Part of Analog Devices
LTC1060MJ/883 Linear Technology IC DUAL SWITCHED CAPACITOR FILTER, RESISTOR PROGRAMMABLE, UNIVERSAL, CDIP20, CERDIP-20, Active Filter visit Linear Technology - Now Part of Analog Devices
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LTC1064-4MJ/883B Linear Technology IC SWITCHED CAPACITOR FILTER, BUTTERWORTH, LOWPASS, CDIP14, CERDIP-14, Active Filter visit Linear Technology - Now Part of Analog Devices
LTC1064-7MJ#TRPBF Linear Technology IC SWITCHED CAPACITOR FILTER, BESSEL, LOWPASS, CDIP14, LEAD FREE, CERDIP-14, Active Filter visit Linear Technology - Now Part of Analog Devices

CAPACITOR 33uF 150D

Catalog Datasheet MFG & Type PDF Document Tags

GRM033R60J104

Abstract: C02E10 at 120 to 150D for 1 minute. Immerse the capacitor in a eutectic solder solution at 270T5D for 10T0.5 , ±10% 22µF ±10% 1.0µF ±10% 1.5µF ±10% 2.2µF ±10% 2.2µF ±10% 2.2µF ±10% 2.2µF ±10% 2.2µF ±10% 3.3µF ±10% 3.3µF ±10% 4.7µF ±10% 4.7µF ±10% 4.7µF ±10% 4.7µF ±10% 10µF ±10% 15000pF ±10% 22000pF ±10% 33000pF ±10% , 6.3 Capacitance 10µF ±10% 10µF ±10% 10µF ±20% 10µF +10/-20% 22µF ±20% 22µF ±20% 22µF ±10% 33µF ±10% , applied continuously to the capacitor. When AC voltage is superimposed on DC voltage, VP-P or VO-P
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C02E10 GRM033R60J104 GRM033R60J104KE19 GRM033 GRM155 GRM185 GRM188 GRM216

GRM32ER71A226ME20

Abstract: GRM033R60J333KE01 solution for 2T0.5 seconds at 230T5D. Preheat the capacitor at 120 to 150D for 1 minute. Immerse the , 0.85 GRM219R61A335KE19 X5R (EIA) 10 3.3µF ±10% 2.00 1.25 0.85 GRM316R61A335KE19 X5R (EIA) 10 3.3µF ±10% 3.20 1.60 0.60 GRM219R61A475KE19 X5R (EIA) 10 4.7µF , X5R (EIA) 6.3 33µF ±10% 3.20 2.50 2.00 GRM32ER60J476ME20 5 TC Code (Standard , is defined as the maximum voltage which may be applied continuously to the capacitor. When AC
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GRM219 GRM21B GRM32ER71A226ME20 GRM033R60J333KE01 GRM188R61C105KE93 GRM43SR60J107ME20 GRM155R60J474KE19 GRM316 GRM319 GRM31M GRM31C

GRM185

Abstract: GRM319R61A106KA19 max. More than 50 · F Test Method Preheat the capacitor at 120 to 150D for 1 minute. Immerse the , 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 4.7µF ±10% 10µF ±10% 22µF ±10% 0.47µF ±10% 1.0µF ±10% 1.0µF ±10% 1.0µF ±10% 2.2µF ±10% 2.2µF ±10% 2.2µF ±10% 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 4.7µF ±10% 22µF ±10% 22µF ±10% , 3.3µF ±10% 3.3µF ±10% 3.3µF ±10% 4.7µF ±10% Length L (mm) 1.60 1.60 2.00 2.00 2.00 2.00 2.00 3.20 3.20 , 10µF ±10% 10µF ±10% 15µF ±10% 22µF ±20% 22µF ±10% 22µF ±20% 22µF ±10% 33µF ±10% 33µF ±10% 47µF ±20%
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GRM319R61A106KA19 GRM43ER61A476KE19 GRM32C GRM32D GRM32E GRM43D GRM43E GRM43S

GRM55FR60J107KA01

Abstract: Murata GRM188R71H103KA01 · F (Whichever is smaller) Dielectric Strength Preheat the capacitor at 120 to 150D for 1 , No defects Test Method Preheat the capacitor at 120 to 150D for 1 minute. Immerse the capacitor , X5R (EIA) 6.3 3.3µF ±10% 2.0 1.25 1.25 GRM21BR60J475KA11 X5R (EIA) 6.3 , 0.90 GRM31XR61A335KC12 X5R (EIA) 10 3.3µF ±10% 3.2 1.6 1.30 GRM31CR61A475KA01 , 3.3µF ±10% 3.2 2.5 1.35 GRM32RR71C475KC01 X7R (EIA) 16 4.7µF ±10% 3.2 2.5
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GRM155R61A683KA01 GRM55FR60J107KA01 Murata GRM188R71H103KA01 Diode T3D 57 T3D 43 diode T3D 45 diode T3D 46 diode 3/16/25/50V GRM155R61A104KA01 GRM188R61A334KA61 GRM188R61A474KA61 GRM188R61A684KA61

grm033r70j103ka01

Abstract: GRM033R71C101KD01 150D for 1 minute. Immerse the capacitor in an eutectic solder solution at 270T5D for 10T0.5 seconds , 2.2µF ±10% 2.00 1.25 1.25 GRM21BR60J335KA11 X5R (EIA) 6.3 3.3µF ±10% 2.00 , 3.3µF ±10% 3.20 1.60 1.30 GRM32ER61A106KC01 X5R (EIA) 10 10µF ±10% 3.20 2.50 , 1.60 GRM31CR71E335KA88 X7R (EIA) 25 3.3µF ±10% 3.20 1.60 1.60 GRM31CR71E475KA88 , 0.68µF ±10% 3.20 2.50 1.35 GRM32NR71C335KC01 X7R (EIA) 16 3.3µF ±10% 3.20 2.50
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GRM033R61A152KA01 GRM033R61A332KA01 grm033r70j103ka01 GRM033R71C101KD01 GRM219 X7R GRM43RR GRM55ER72A475KA01 GRM21BR71E105KA99 GRM21A GRM033R61A222KA01 GRM033R61A472KA01 GRM033R61A682KA01

GRP155R71E

Abstract: GRP155F51A474ZD02 .0µF) : 0.09max. (C U1.0µF) W.V. : 10Vmax. : 0.125max. Preheat the capacitor at 120 to 150D for 1 minute , 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 4.7µF ±10% 10µF ±10% 10µF ±20% 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 4.7µF , 0.68µF±10% 1µF ±10% 2.2µF ±10% 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 2.2µF ±10% 1µF ±10% 1.5µF ±10% 2200pF +80% , maximum voltage which may be applied continuously to the capacitor. When AC voltage is superimposed on DC , Method High Dielectric Type Solder the capacitor to the test jig (glass epoxy board) shown in Fig.1 using
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GRP155R71E GRP155F51A474ZD02 grp155 GRP155R71H331K GRP155R61A104K GRM319R71C105KC11 GRP155 GRP155R61A683KA01 GRP155R61A104KA01 GRM155R60J154KE01 GRM155R60J224KE01 GRM155R60J334KE01

GRM55FR60J107KA01

Abstract: GRM43RR .0µF) : 0.09max. (C U1.0µF) W.V. : 10Vmax. : 0.125max. Preheat the capacitor at 120 to 150D for 1 minute , ±10% 3.3µF ±10% 4.7µF ±10% 4.7µF ±10% 10µF ±10% 10µF ±20% 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 4.7µF ±10% , 0.68µF±10% 1µF ±10% 2.2µF ±10% 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 2.2µF ±10% 1µF ±10% 1.5µF ±10% 2200pF +80% , capacitor. When AC voltage is superimposed on DC voltage, VP-P or VO-P, whichever is larger, shall be , Compensating Type Test Method High Dielectric Type Solder the capacitor to the test jig (glass epoxy board
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GRM55DR61H106KA01 GRM21BR71H683K GRM55RR GRM219R71H333K 10n 500V capacitor GRM21BF51H224Z GRM188R61A105KA61 GRM188R60J105KA01 GRM188R60J225KE01 GRM219R61A105KC01 GRM21BR61A225KA01 GRM219R60J155KC01

CD54-220M

Abstract: CD54-470K 500mA in all cases. Figure 1 shows a Sprague 501D, 25V aluminum capacitor. VOUT jumps by over 120mV when the switch turns off, followed by a drop in voltage as the inductor dumps into the capacitor. This works out to be an ESR of over 0.24. Figure 2 shows the same circuit, but with a Sprague 150D, 20V tantalum capacitor replacing the aluminum unit. Output jump is now about 35mV, corresponding to , LT1111 · F02 Figure 2. Tantalum Selecting the right output capacitor is almost as important as
Linear Technology
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CD54-220M CD54-470K CD75-470K LT11 LT1110 LT1111C LT1172/LT1172HV LT1307/LT1307B LT1317/LT1317B LT1370/LT1370HV LT1371/LT1371HV

501d sprague

Abstract: CD54-470K dumps into the capacitor. This works out to be an ESR of over 0.24. Figure 2 shows the same circuit, but with a Sprague 150D, 20V tantalum capacitor replacing the aluminum unit. Output jump is now , peak switch current is 500mA in all cases. Figure 1 shows a Sprague 501D, 25V aluminum capacitor , inductor will work. 5µs/DIV Capacitor Selection Figure 2. Tantalum 50mV/DIV Selecting the right output capacitor is almost as important as selecting the right inductor. A poor choice for a
Linear Technology
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501d sprague sprague 501d LT1111-5 CD74-680M LT1111-12 Step-Down, External PNP Saturated Switch

CD74-680M

Abstract: current is 500mA in all cases. Figure 1 shows a Sprague 501D, 25V aluminum capacitor. VOUT jumps by over 120mV when the switch turns off, followed by a drop in voltage as the inductor dumps into the capacitor. This works out to be an ESR of over 0.24â"¦. Figure 2 shows the same circuit, but with a Sprague 150D, 20V tantalum capacitor replacing the aluminum unit. Output jump is now about 35mV, corresponding to , . Tantalum Selecting the right output capacitor is almost as important as selecting the right inductor. A
Linear Technology
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Abstract: 150D for 1 minute. Immerse the capacitor in an eutectic solder solution at 270T5D for 10T0.5 seconds , '¢ F No defects Test Method Preheat the capacitor at 120 to 150D for 1 minute. Immerse the , 1.25 1.25 GRM21BR60J335KA11 X5R (EIA) 6.3 3.3µF ±10% 2.0 1.25 1.25 , 2.2µF ±10% 3.2 1.6 0.90 GRM31XR61A335KC12 X5R (EIA) 10 3.3µF ±10% 3.2 1.6 , ±10% 3.2 2.5 1.15 GRM32NR71C335KC01 X7R (EIA) 16 3.3µF ±10% 3.2 2.5 1.35 muRata
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GRM21BR60J225KA 150W0/Y10D

grm32df51h106

Abstract: GRM43ER72A225KA01 failure Preheat the capacitor at 120 to 150D for 1 minute. Immerse the capacitor in a eutectic solder , (Whichever is smaller) No failure Preheat the capacitor at 120 to 150D for 1 minute. Immerse the capacitor , is suited to flow and reflow soldering. Capacitor terminations are made of metal highly resistant to , maximum voltage which may be applied continuously to the capacitor. When AC voltage is superimposed on DC , Compensating Type Test Method High Dielectric Type Solder the capacitor to the test jig (glass epoxy board
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grm32df51h106 GRM43ER72A225KA01 GRM15X5C1H390JDB4 GRM55ER72A475 GRM15/18/21/31 GRM18 GRM31 GRM15 QU350 QU275

GRM32ER72A105K

Abstract: GRM32DF51H106Z (Whichever is smaller) No failure Preheat the capacitor at 120 to 150D for 1 minute. Immerse the capacitor , Capacitance 10µF ±10% 68000pF ±10% 0.10µF ±10% 1.0µF ±10% 0.68µF ±10% 1.0µF ±10% 2.2µF ±10% 2.2µF ±10% 3.3µF , defined as the maximum voltage which may be applied continuously to the capacitor. When AC voltage is , the capacitor to the test jig (glass epoxy board) shown in Fig. 1 using a eutectic solder. Then apply , .10µF) W.V. : 16V/10V : 0.125max. W.V. : 6.3Vmax. : 0.15max. Solder the capacitor to the test jig (glass
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GRM32ER72A105K GRM32DF51H106Z 450X3 GRM32NR72A104KA01 GRM55ER GRM32/43/55 GRM329 GRM32M QU200 1000T12 Y000T030

U4002

Abstract: C02E10 ,000M or 500 · F (Whichever is smaller) Dielectric Strength Preheat the capacitor at 120 to 150D , ) 0.80(8) 0.85(9) 1.5µF(155) 0.85(9) 2.2µF(225) 1.25(B) 0.85(9) 3.3µF(335) 1.25(B , ) The part numbering code is shown in each ( ). 3.3µF and 4.7µF, 6.3V rated are GRM21 series of L , ) 1.5µF (155) 1.60 (C) 1.15 (M) 2.2µF (225) 1.60 (C) 1.15 (M) 3.3µF (335) 1.60 , rated voltage is defined as the maximum voltage which may be applied continuously to the capacitor
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U4002 Y1000

GRM55DR61H106KA01

Abstract: GRM55ER72A475KA01 ,000M or 500 · F (Whichever is smaller) Dielectric Strength Preheat the capacitor at 120 to 150D , X7R (EIA) 16 3.3µF ±10% 3.20 2.50 1.35 GRM32RR71C475KC01 X7R (EIA) 16 4.7µF , capacitor. When AC voltage is superimposed on DC voltage, VP-P or VO-P, whichever is larger, should be , Test Method Temperature Compensating Type High Dielectric Type Solder the capacitor to the test , the capacitor on the test jig (glass epoxy board) shown in Fig. 2 using a eutectic solder. Then apply
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GRM43N GRM55E GRM55ER71H475KA01 GRM43r GRM55RR71H105KA01 T3D 78 diode GRM43R5C2D122JV01 GRM32N GRM32R GRM43M GRM43R GRM55M

marking code T12 y

Abstract: 2.F 1 marking ) Dielectric Strength Preheat the capacitor at 120 to 150D for 1 minute. Immerse the capacitor in a , ) 1.0µF(105) 1.80(R) 2.2µF(225) 1.15(M) 3.3µF(335) 1.8(R) 1.35(N) 4.7µF(475) 10µF , voltage which may be applied continuously to the capacitor. When AC voltage is superimposed on DC , Compensating Type High Dielectric Type Solder the capacitor to the test jig (glass epoxy board) shown in , : 0.07max. (CF1.0µF) : 0.09max. (CU1.0µF) W.V. : 10Vmax.:0.125max. Solder the capacitor on the test jig
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marking code T12 y 2.F 1 marking 561 6.3v CAPACITOR 1000pf diode T3D 6 GRM43 X7R C02E9 Y000T060 Y150T060 Y220T060 Y330T060 Y470T060

47UF uCapacitor X7R 1206u

Abstract: GRP155 ) Dielectric Strength Preheat the capacitor at 120 to 150D for 1 minute. Immerse the capacitor in a , ) 3.3µF(335) 1.25(B) 1.30(X) 4.7µF(475) 1.25(B) 10µF(106) The part numbering code is shown in each ( ). 3.3µF and 4.7µF for 6.3V is replaced with GRM21B series of L: 2±0.15, W: 1.25±0.15, T: 1.25±0.15. T: 1.25±0.1mm is also available for GRM21 10V 1.0µF type. 3.3µF for 10V rated is replaced with , voltage which may be applied continuously to the capacitor. When AC voltage is superimposed on DC
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47UF uCapacitor X7R 1206u cap 10pF 50V 10% 0603 X7R grm 200 GRM Series Specification and Test Methods 2 marking code T12 marking W30 GRP15/GRM15/18/21/31 GRP15 Y750T120

grm55er71h475ka01

Abstract: CAPACITOR 33uF 150D ) 3.3µF(335) 4.7µF(475) 10µF(106) The part numbering code is shown in each ( ). 3.3µF and 4.7µF, 6.3V , (105) 1.5µF (155) 2.2µF (225) 3.3µF (335) 4.7µF (475) 10µF (106) The part numbering code is shown in , ±10% 0.10µF ±10% 0.68µF ±10% 1.0µF ±10% 1.0µF ±10% 1.5µF ±10% 2.2µF ±10% 0.68µF ±10% 3.3µF ±10% 4.7µF ±10% 1.5µF ±10% 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 2.2µF ±10% 3.3µF ±10% 4.7µF ±10% 10µF ±10% 0.10µF +80
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CAPACITOR 33uF 150D GRM21BR61E105K GRM32DR71H335KA88 GRM55DR72A105KA01 GRM55

capacitor 6s 100 16v

Abstract: C02E10 failure Preheat the capacitor at 120 to 150D for 1 minute. Immerse the capacitor in a eutectic solder , ) 2.2µF(225) 3.3µF(335) 4.7µF(475) 10µF(106) The part numbering code is shown in each ( ). 3.3µF and , (155) 2.2µF (225) 3.3µF (335) 4.7µF (475) 0.50 (5) 0.50 (5) 0.50 (5) 0.80 (8) 0.80 (8) 0.80 (8) 0.80 (8 , continuously to the capacitor. When AC voltage is superimposed on DC voltage, VP-P or VO-P, whichever is larger , Compensating Type Test Method High Dielectric Type Solder the capacitor to the test jig (glass epoxy board
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capacitor 6s 100 16v

SMD MARKING CODE w02

Abstract: T3D DIODE Microchips 39 8 Capacitor Arrays 42 9 for Ultrasonic Sensors 48 10 Low ESL 51 , M Capacitor Array F 3.2 mm LL L Low ESL Wide Width Type M 1.15 mm M , GRM_6C Series 0.5pF­47000pF Capacitor Arrays C0G Char. 0.5pF­47000pF GNM_5C Series 10pF­360pF Temperature Compensation Soldering Electrode for temperature compensation Capacitor , AC250V which meet Japanese Law Capacitor Arrays for temperature compensation Capacitor Arrays
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SMD MARKING CODE w02 T3D DIODE murata 55D ceramic filter SMD Transistor W03 T3D 34 diode GJM1555C1H100JB01 C02E-10 GRM03
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