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Part Manufacturer Description Datasheet Download Buy Part
2-796658-3 TE Connectivity Ltd 4DB-P108-14-102
BBT3420-SN Intersil Corporation SPECIALTY TELECOM CIRCUIT, PBGA289, 19 X 19 MM, MO-102, HSBGA-289
16KB2LF037 TE Connectivity (16KB2LF037) Madison Spec 102-0945 Rev. 4
16KD2LF039 TE Connectivity (16KD2LF039) Madison Spec 102-0377 Rev. 4
1-2191021-1 TE Connectivity (1-2191021-1) HVCB-ENN-102
16KF2LF041 TE Connectivity (16KF2LF041) Madison Spec 102-1119 Rev. 2

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4.7 MF 50v CAPACITOR

Abstract: ceramic capacitor 103 103 TANTALUM capacitor 0.1uF 50V X7R PCH 7900 ERJ resistor capacitor 103 TL1431CD transistor 603 capacitor 1000 MF 25v
Text: TL5001EVM-101/ 102 /103 Assembly File Effective Date: 02/12/99 Current EVM Rev: D TEXAS INSTRUMENTS TL5001EVM-101/ 102 /103 Assembly File Table of Contents Introduction , . 10 2 TL5001EVM-101/ 102 /103 Assembly File Introduction This document is intended to assist in the fabrication of the TL5001EVM-101/ 102 /103 evaluation modules from Texas Instruments. EVM # TL5001EVM-101 TL5001EVM- 102 TL5001EVM-103 Description 5-V to 3.3-V, 3-A Voltage-mode buck converter 5


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PDF TL5001EVM-101/102/103 TL5001EVM-101/102/103 4.7 MF 50v CAPACITOR ceramic capacitor 103 103 TANTALUM capacitor 0.1uF 50V X7R PCH 7900 ERJ resistor capacitor 103 TL1431CD transistor 603 capacitor 1000 MF 25v
2001 - 12V FAN CONTROL BY USING THERMISTOR

Abstract: PWM generator based microcontroller pic TC648VOA TC648 TC642EV TC642DEMO MPS2222A MPS2222 microcontroller based temperature control fan heat sensor with fan cooling working
Text: +5V OVER-TEMP INTERRUPT Q1 RBASE TC648 R3 3 VOUT 7 VAS CB 0.01µF 5 , transistor for modulating power to the fan. This is shown as " Q1 " in Figures 1, 7, 8, and 10. The VOUT pin , work equally as well as those listed. The only critical issues when choosing a device to use as Q1 , in: R1 = R2 x VDD ­ VAS 5 ­ 1.53 = R2 x VAS 1.53 Table 1. Transistors for Q1 Device , . Temperature Sensing Circuit VDD VDD VDD FAN FAN FAN RBASE VOUT Q1 RBASE VOUT Q2


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PDF TC648 TC648 DS21448A TC648-2 12V FAN CONTROL BY USING THERMISTOR PWM generator based microcontroller pic TC648VOA TC642EV TC642DEMO MPS2222A MPS2222 microcontroller based temperature control fan heat sensor with fan cooling working
2006 - m51996afp

Abstract: M51978
Text: 0.5 Ta = 25°C VCC = 18 V VCC = 5 V 10-2 3 10-1 3 100 3 101 0 10-3 3 10-2 3 10-1 3 100 3 101 Source Current IOH (A) Sink Current IOL (A , /B Terminal Input Current 30 25 20 15 10 5 0 102 3 ON Duty (%) 103 3 35 30 20 10 , Frequency vs. CF Terminal Capacitance 103 3 102 3 RON = 22 k ROFF = 12 k RON = 36 k ROFF = 6.2 k , 3 101 3 102 3 103 3 104 Ambient Temperature Ta (°C) CF Terminal


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PDF M51996AP/AFP REJ03D0836-0200 M51996A M51978 500kHz m51996afp
2001 - 12V FAN CONTROL BY USING THERMISTOR

Abstract: PWM generator based microcontroller pic driver fan TEMPERATURE DEPENDENT DC FAN SPEED CONTROL TC642DEMO MPS2222 PWM IC 8-PIN DIP PWM fan speed control features of TEMPERATURE DEPENDENT DC FAN SPEED CONTROL USING 8 lead soic-n package (R8)
Text: . See the Applications section for more details. 8 1 FAN VDD VIN FAULT 6 1 0 Q1 , FAN VDD 0.01 CB R2 6 FAULT FAN FAULT SHUTDOWN Q1 RBASE Normal Operation is , Circuit VDD VDD FAN FAN RBASE VOH = 80% VDD RBASE +V RBASE VOUT Q1 ­ , GND Figure 6. Circuit for Determining RBASE TC647-2 12/05/00 Q1 Figure 7. SENSE Network , FanSenseTM* TC647 VDD VDD VDD FAN FAN FAN RBASE RBASE VOUT VOUT Q1 Q1


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PDF TC647 TC647 DS21447A TC647-2 12V FAN CONTROL BY USING THERMISTOR PWM generator based microcontroller pic driver fan TEMPERATURE DEPENDENT DC FAN SPEED CONTROL TC642DEMO MPS2222 PWM IC 8-PIN DIP PWM fan speed control features of TEMPERATURE DEPENDENT DC FAN SPEED CONTROL USING 8 lead soic-n package (R8)
2001 - transistor tic 2260

Abstract: tic 2260 temperature dependent dc fan speed control by using thermistor heat sensor 12V FAN CONTROL BY USING THERMISTOR TC642 PWM IC 8-PIN DIP missing pulse detector highway speed sensing heat sensor with fan cooling working 2N2222A plastic
Text: 8 1 VIN FAN VDD FAULT 6 1 0 Q1 Fault Detected +5V R3 TC642 VOUT , VIN FAN VDD 0.01 CB R2 6 FAULT THERMAL SHUTDOWN Q1 RBASE TC642 R3 3 , Circuit VDD VDD FAN FAN RBASE VOH = 80% VDD RBASE +V RBASE VOUT Q1 ­ , GND Figure 6. Circuit for Determining RBASE TC642-2 12/05/00 Q1 Figure 7. SENSE Network , VDD FAN RBASE RBASE VOUT VOUT Q1 Q1 Q1 VOUT Q2 RSENSE RSENSE RSENSE


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PDF TC642 TC642 DS21444A TC642-2 transistor tic 2260 tic 2260 temperature dependent dc fan speed control by using thermistor heat sensor 12V FAN CONTROL BY USING THERMISTOR PWM IC 8-PIN DIP missing pulse detector highway speed sensing heat sensor with fan cooling working 2N2222A plastic
2001 - Not Available

Abstract: No abstract text available
Text: FAULT 6 1 0 Q1 Fault Detected +5V R3 TC642 VOUT RBASE 7 3 V MIN R1 From , FAULT THERMAL SHUTDOWN Q1 RBASE TC642 R3 3 0.01 CB SHUTDOWN 5 SENSE 2 CF , FAN FAN RBASE VOH = 80% VDD RBASE +V RBASE VOUT Q1 – +V BE(SAT) â , . Circuit for Determining RBASE TC642-2 12/05/00 Q1 Figure 7. SENSE Network 8 © 2001 , FAN VDD FAN RBASE RBASE VOUT VOUT Q1 Q1 Q1 VOUT Q2 RSENSE RSENSE


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PDF TC642 TC642 DS21444A TC642-2
2001 - AUTOMATIC FAN CONTROL ACCORDING TEMP

Abstract: fault fan TEMPERATURE DEPENDENT DC FAN SPEED CONTROL transistor tic 2260 microcontroller based automatic fan speed control TEMPERATURE CONTROL IC 4570 NTC 50-9 brushless dc motor speed control simple circuit automatic fan speed control by room temperature application of one automatic fan controller
Text: * VIN FAN VDD CB 0.01µF R2 6 FAULT FAN FAULT SHUTDOWN +5V Q1 RBASE , Circuit VDD VDD FAN FAN RBASE RBASE VOH = 80% VDD +V RBASE VOUT Q1 ­ + VBE(SAT)­ SENSE CSENSE (0.1µF Typ.) + VRSENSE Q1 RSENSE RSENSE ­ GND , power to the fan. This is shown as " Q1 " in Figures 1, 5, 6, 8, 9, and 11. The VOUT pin has a minimum , those listed. The only critical issues when choosing a device to use as Q1 are: (1) the breakdown


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PDF TC649 TC649 DS21449A TC649-2 AUTOMATIC FAN CONTROL ACCORDING TEMP fault fan TEMPERATURE DEPENDENT DC FAN SPEED CONTROL transistor tic 2260 microcontroller based automatic fan speed control TEMPERATURE CONTROL IC 4570 NTC 50-9 brushless dc motor speed control simple circuit automatic fan speed control by room temperature application of one automatic fan controller
1999 - PTC 1k thermistor conversion

Abstract: 2N4401 NPN Transistor
Text: FAULT SHUTDOWN RBASE Q1 R3 3 TC649 VAS VOUT 7 CB 0.01µF 2 5 SENSE CF CSENSE , BASE ­ RBASE Q1 VOUT SENSE CSENSE (0.1µF Typ.) Q1 + VBE(SAT)­ + VRSENSE ­ RSENSE , shown as " Q1 " in Figures 1, 5, 6, 8, 9, and 11. The VOUT pin has a minimum source current of 5mA and a , when choosing a device to use as Q1 are: (1) the breakdown voltage, VCE(BR), must be large enough to , RBASE VOUT Q1 RBASE VOUT Q1 Q2 VOUT Q1 RSENSE RSENSE RSENSE GND a) Single Bipolar


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PDF TC649 TC649 TC649-1 D-82152 PTC 1k thermistor conversion 2N4401 NPN Transistor
1999 - Not Available

Abstract: No abstract text available
Text: System Shutdown Controller R1 R4 (OPTIONAL) +12V TC647 Reset FAN 8 1 VIN VDD FAULT 6 1 0 Q1 , PWM. (1) Reset the Missing Pulse Detector R2 Q1 R3 3 0.01 CB SHUTDOWN (OPTIONAL) R4 CF 1µF , RBASE VOH = 80% VDD + VR BASE ­ SAT) ­ RBASE Q1 VOUT SENSE Q1 + VBE( + VRSENSE ­ , VDD VDD VDD FAN FAN FAN RBASE VOUT Q1 RBASE VOUT Q1 Q2 VOUT Q1 RSENSE RSENSE , TC647 is designed to drive an external transistor for modulating power to the fan. This is shown as " Q1


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PDF TC647 TC647 TC647-1 D-82152
2001 - temperature based fan speed control

Abstract: heat sensor with fan cooling zener diode TC646VPA TC642DEMO MPS2222 simple temperature controlled dc fan microcontroller based temperature control fan heat sensor with fan cooling working automatic fan speed control by room temperature AUTOMATIC fan control
Text: R2 6 FAULT THERMAL SHUTDOWN +5V Q1 RBASE TC646 VOUT R3 3 7 VAS CB , VDD FAN FAN RBASE RBASE VOH = 80% VDD +V RBASE VOUT Q1 ­ + VBE(SAT)­ SENSE CSENSE (0.1µF Typ.) + VRSENSE Q1 RSENSE RSENSE ­ GND GND Figure 6 , modulating power to the fan. This is shown as " Q1 " in Figures 1, 5, 6, 8, 9, and 11. The VOUT pin has a , those listed. The only critical issues when choosing a device to use as Q1 are: (1) the breakdown


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PDF TC646 TC646 TC646-2 DS21446A temperature based fan speed control heat sensor with fan cooling zener diode TC646VPA TC642DEMO MPS2222 simple temperature controlled dc fan microcontroller based temperature control fan heat sensor with fan cooling working automatic fan speed control by room temperature AUTOMATIC fan control
2000 - Not Available

Abstract: No abstract text available
Text: 1 0 TC647 Reset +12V FAN Q1 Fault Detected RBASE TC647 VOUT 7 RSENSE FAULT , PWM. (1) Reset the Missing Pulse Detector R2 Q1 R3 3 0.01 CB SHUTDOWN (OPTIONAL) R4 CF 1µF , RBASE VOH = 80% VDD +V RBASE ­ ­ RBASE Q1 VOUT SENSE Q1 +V BE(SAT) + VRSENSE ­ , VDD VDD VDD FAN FAN FAN RBASE VOUT Q1 RBASE VOUT Q1 Q2 VOUT Q1 RSENSE RSENSE , TC647 is designed to drive an external transistor for modulating power to the fan. This is shown as " Q1


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PDF TC647 TC647 TC647-1 D-82152
1999 - Not Available

Abstract: No abstract text available
Text: VDD CB 0.01µF R2 6 FAULT FAN FAULT SHUTDOWN +5V Q1 RBASE TC649 R3 3 , VOUT Q1 – + VBE(SAT)– SENSE CSENSE (0.1µF Typ.) + VRSENSE Q1 RSENSE , those listed. The only critical issues when choosing a device to use as Q1 are: (1) the breakdown , VDD FAN FAN FAN RBASE RBASE VOUT VOUT Q1 Q1 Q1 VOUT Q2 RSENSE , at the anode of D1 increases by VOH, causing Q1 to turn ON. Operation is otherwise the same as in


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PDF TC649 TC649 TC649-1 D-82152
2001 - Not Available

Abstract: No abstract text available
Text: R2 6 FAULT THERMAL SHUTDOWN +5V Q1 RBASE TC646 VOUT R3 3 7 VAS CB , RBASE RBASE VOH = 80% VDD +V RBASE VOUT Q1 – + VBE(SAT)– SENSE CSENSE (0.1µF Typ.) + VRSENSE Q1 RSENSE RSENSE – GND GND Figure 6. SENSE Network , use as Q1 are: (1) the breakdown voltage, VCE(BR), must be large enough to stand off the highest , Q1 Q1 Q1 VOUT Q2 RSENSE RSENSE RSENSE GND a) Single Bipolar Transistor b


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PDF TC646 TC646 TC646-2 DS21446A
2002 - temperature dependent dc fan speed control by using thermistor heat sensor

Abstract: thermistor ntc 10k technical characteristics
Text: +5V 1k 1µF +12V TC647 RESET Fan 6 1 0 Q1 Fault Detected VOUT 7 From Temp Sensor +5V 8 1 , RBASE Fan R2 Q1 TC647 R3 3 0.01µF CB R4 (Optional) CF 1µF VMIN VOUT 7 5 2 CF GND 4 , . FIGURE 5-4: SENSE NETWORK VDD FAN 5.3 Operations at Low Duty Cycle VOUT SENSE RBASE Q1 , will work as well as those listed. The critical issues when choosing a device to use as Q1 are: (1) the , to drive an external transistor for modulating power to the fan. This is shown as " Q1 " in Figures 3-1


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PDF TC647 TC647 DS21447B* DS21447B-page temperature dependent dc fan speed control by using thermistor heat sensor thermistor ntc 10k technical characteristics
2001 - Not Available

Abstract: No abstract text available
Text: section for more details. 8 1 FAN VDD VIN FAULT 6 1 0 Q1 Fault Detected +5V , 6 FAULT FAN FAULT SHUTDOWN Q1 RBASE Normal Operation is an endless loop which may only , FAN FAN RBASE VOH = 80% VDD RBASE +V RBASE VOUT Q1 – +V BE(SAT) â , . Circuit for Determining RBASE TC647-2 12/05/00 Q1 Figure 7. SENSE Network 8 © 2001 , „¢* TC647 VDD VDD VDD FAN FAN FAN RBASE RBASE VOUT VOUT Q1 Q1 Q1 VOUT


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PDF TC647 TC647 DS21447A TC647-2
2006 - MC14526

Abstract: MC14526BCPG MC14526B MC14526BCP MC14526BDW MC14526BDWG MC14526BDWR2 MC14526BDWR2G SOIC-16WB
Text: 10 RESET 8 9 VSS Q1 Figure 1. Pin Assignment X = Don't Care NOTES: * Output , inputs. data inputs. P0 is the LSB. Q0, Q1 , Q2, Q3 (Pins 7, 9, 15, 1) - These are the Reset (Pin 10) - A high level on Reset asynchronously forces Q0, Q1 , Q2, and Q3 low and, if Cascade Feedback is , positive power supply potential. (Q0 = Q1 = Q2 = Q3 = low) if Cascade Feedback is high and VDD may range , P0 P1 P2 P3 RESET INHIBIT CLOCK CF PE P0 P1 P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2


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PDF MC14526B MC14526B MC14526B/D MC14526 MC14526BCPG MC14526BCP MC14526BDW MC14526BDWG MC14526BDWR2 MC14526BDWR2G SOIC-16WB
2000 - mc14526bcp

Abstract: MC14526 MC14526B MC14526BDW MC14526BDWR2 MC14526BF
Text: 10 RESET 8 9 VSS Q1 FUNCTION TABLE Inputs Output Clock Reset Inhibit , P1 P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 IOH Q3 0" EXTERNAL POWER SUPPLY VSS VOL VDD = VGS Q0 Q1 Q2 IOL Q3 0" EXTERNAL POWER SUPPLY VSS Figure 1. Typical , Circuit VDD CF PE P0 P1 P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 Q3 0" VSS PULSE , . Q0, Q1 , Q2, Q3 (Pins 7, 9, 15, 1) - These are the synchronous counter outputs. Q0 is the LSB. VSS


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PDF MC14526B MC14526B r14525 MC14526B/D mc14526bcp MC14526 MC14526BDW MC14526BDWR2 MC14526BF
2000 - MC14526B

Abstract: MC14526BCP MC14526BDW MC14526BDWR2 MC14526BF
Text: VSS Q1 FUNCTION TABLE Inputs Output Resulting Function Clock Reset Inhibit , RESET INHIBIT CLOCK CF PE P0 P1 P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 IOH Q3 "0" EXTERNAL POWER SUPPLY VSS Q0 Q1 Q2 IOL Q3 "0" EXTERNAL POWER SUPPLY VSS Figure 1 , Circuit VDD CF PE P0 P1 P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 20 ns CLOCK TEST POINT , . Q0, Q1 , Q2, Q3 (Pins 7, 9, 15, 1) - These are the synchronous counter outputs. Q0 is the LSB. VSS


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PDF MC14526B MC14526B r14525 MC14526B/D MC14526BCP MC14526BDW MC14526BDWR2 MC14526BF
1996 - MC14522B

Abstract: MC14526B MC14XXXBCL MC14XXXBCP MC14XXXBDW
Text: Q1 Resulting Function Preset Enable H Cascade Feedback 3 VSS FUNCTION TABLE , P3 RESET INHIBIT CLOCK Q0 Q1 Q2 IOH Q3 "0" EXTERNAL POWER SUPPLY VSS Figure 1 , Q1 Q2 IOL Q3 "0" EXTERNAL POWER SUPPLY VSS Figure 2. Typical Output Sink Characteristics Test Circuit VDD CF PE P0 P1 P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 CL Q3 CL , forces Q0, Q1 , Q2, and Q3 low and, if Cascade Feedback is high, causes the "0" output to go high. "0"


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PDF MC14522B MC14526B MC14522B MC14526B MC14522B/D* MC14522B/D MC14XXXBCL MC14XXXBCP MC14XXXBDW
2002 - NTC thermistor 100K

Abstract: No abstract text available
Text: 1µF CF GND SENSE CSENSE RSENSE Q1 TC649 R3 Notes: *See cautions regarding Latchup , Current (mA) 50 100 150 200 250 Q1 Fan RBASE VOUT SENSE CSENSE (0.1µF Typ.) RSENSE 300 350 400 , as " Q1 " in Figures 5-1, 5-4, 5-6, 5-7, 5-8 and 5-9. The VOUT pin has a minimum source current of 5mA , issues when choosing a device to use as Q1 are: (1) the breakdown voltage, V(BR)CEO or VDS (MOSFET), must , Q1 RBASE VOUT Q1 Q2 VOUT Q1 RSENSE RSENSE RSENSE GND a) Single Bipolar Transistor


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PDF TC649 TC649 us200 DS21449B* DS21449B-page NTC thermistor 100K
2011 - Not Available

Abstract: No abstract text available
Text: inputs. P0 is the LSB. requirements on the other inputs. Q0, Q1 , Q2, Q3 (Pins 7, 9, 15, 1) — These , the LSB. forces Q0, Q1 , Q2, and Q3 low and, if Cascade Feedback is VSS (Pin 8) — The most negative , reaches terminal count VDD (Pin 16) — The most positive power supply potential. (Q0 = Q1 = Q2 = Q3 = , RESET INHIBIT CLOCK Q0 Q1 Q2 IOH Q3 “0” EXTERNAL POWER SUPPLY VSS Q0 Q1 Q2 , P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 20 ns CLOCK TEST POINT CL CL “0” VSS


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PDF MC14526B MC14526B MC14526B/D
2013 - mc14526b

Abstract: No abstract text available
Text: . requirements on the other inputs. Q0, Q1 , Q2, Q3 (Pins 7, 9, 15, 1) - These are the Reset (Pin 10) - A high level on Reset asynchronously synchronous counter outputs. Q0 is the LSB. forces Q0, Q1 , Q2, and Q3 low , supply potential. (Q0 = Q1 = Q2 = Q3 = low) if Cascade Feedback is high and VDD may range from 3.0 to 18 , P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 Q3 "0" EXTERNAL POWER SUPPLY IOH VDD = VGS CF PE P0 P1 P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 Q3 "0" EXTERNAL POWER SUPPLY IOL VOL VSS VSS Figure 1. Typical Output


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PDF MC14526B MC14526B/D
1998 - TO220-7 package

Abstract: transistor 5207 AED01305 AEB01225 Q67006-A9296 Q67000-A9295 AES01570 AES01569 AEP01224 Transistors Diodes smd e2
Text: . Semiconductor Group 1 1998-02-01 TLE 5207 TLE 5207 1 2 3 4 5 6 GND VS EF Q1 , Definitions and Functions Pin Symbol Function 1 Q1 Output of channel 1; short-circuit proof , . Functional Truth Table I1 I2 Q1 Q2 Comments L L Z Z Device in inhibit condition , Diagnosis EF I1 I2 Q1 Q2 Shorted to GND Shorted to VS Overload L L Z Z Q1 , Q2 Q1 , Q2 ­ H L H L H Q2 Q1 X L H L H L Q1 Q2


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PDF P-TO220-7-1 P-TO220-7-8 Q67000-A9295 5207G Q67006-A9296 GPT05108 GPT05874 TO220-7 package transistor 5207 AED01305 AEB01225 Q67006-A9296 Q67000-A9295 AES01570 AES01569 AEP01224 Transistors Diodes smd e2
1998 - transistor smd CF rs

Abstract: 5203 ic E2 SMD Transistor Q67006-A9242 Q67000-A9096 AES01688 AES01228 AES01226 AEP01224 5203 smd transistor
Text: TLE 5203 TLE 5203 1 2 3 4 5 6 GND VS EF Q1 TLE 5203 G 1 2 7 Q2 , Pin Definitions and Functions Pin No. Symbol Function 1 Q1 Output of channel 1 , Q1 Q2 Comments L L H L Motor turns counterclockwise L H L H Motor , set without a delay. Open Load Detection The output Q1 has a 10 k pull-up resistor and the output Q2 , of no load between Q1 and Q2 the output voltage Q1 is VS and Q2 is ground. This state will be


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PDF P-TO220-7-1 P-TO220-7-8 Q67000-A9096 Q67006-A9242 GPT05108 GPT05874 transistor smd CF rs 5203 ic E2 SMD Transistor Q67006-A9242 Q67000-A9096 AES01688 AES01228 AES01226 AEP01224 5203 smd transistor
2011 - MC14526

Abstract: No abstract text available
Text: . requirements on the other inputs. Q0, Q1 , Q2, Q3 (Pins 7, 9, 15, 1) - These are the Reset (Pin 10) - A high level on Reset asynchronously synchronous counter outputs. Q0 is the LSB. forces Q0, Q1 , Q2, and Q3 low , supply potential. (Q0 = Q1 = Q2 = Q3 = low) if Cascade Feedback is high and VDD may range from 3.0 to 18 , P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 Q3 "0" EXTERNAL POWER SUPPLY IOH VDD = VGS CF PE P0 P1 P2 P3 RESET INHIBIT CLOCK Q0 Q1 Q2 Q3 "0" EXTERNAL POWER SUPPLY IOL VOL VSS VSS Figure 1. Typical Output


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PDF MC14526B MC14526B/D MC14526
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