NEW DATABASE - 350 MILLION DATASHEETS FROM 8500 MANUFACTURERS
NEW DATABASE - 350 MILLION DATASHEETS FROM 8500 MANUFACTURERS
| Catalog Datasheet Results | Type | Document Tags |
| Abstract: the voltage sine wave. This increases the RMS value of current, which limits the current that PWM , PIC17C756A PIC17C756A Market: Power Management Control Power Factor Correction Application Brief VLINE VSET (output) VOUT L O A D PIC 756 17C A AC Mains (100 kHz) Current Sense APPLICATION DESCRIPTION Power Factor Correction (PFC) comes into play when designing for high power , Switching Power Supplies · UPS (Front-end) · AC Motor Drive · Lighting PIC17C756A PIC17C756A ... | Original |
2 pages, |
PIC17C75X PIC17C756A microchip application notes for pfc DC MOTOR SPEED CONtrol pwm pic sine wave pwm pic power factor correction microchip sine wave ups designing PIC17C756A abstract |
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| Abstract: Inverters • UPS • DC to DC Converters Regulated Power Supply • Induction Heaters • High Frequency FOR SINE , 600 C444/C445M C444/C445M 600 600 720 1 Half sine wave waveform, 10 ms max. pulse width. Peak One Cycle Surge , tConsult factory for maximum turn-off time. SINE WAVE CURRENT RATING DATA 10,000 1,000 1,000 , ) 1,000 V, fc »400 6A,.25>if Tj « I29°C VN» «400V NOTES: (Pertaining to Sine and Trapezoidal Wave , ) capability and other speed characteristics. When designing for speed, the parameter trade offs must be ... | OCR Scan |
7 pages, |
C358 C388 C395 C398 C444 C445 GE SCR 1000 GE SCR 1000 AMP IC444 SCR TN 22 1500 square wave UPS inverter sine wave ups designing datasheet abstract |
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| Abstract: Frequency Rectification I UPS FEATURES I Double side cooling I High surge capability I Low recovery , Cooled IF(AV) Mean forward current Half wave resistive load, Tcase = 65oC 1490 A IF(RMS , A 995 A IF Single Side Cooled (Anode side) IF(AV) Mean forward current Half wave , Conditions Surge (non-repetitive) forward current 10ms half sine; with 0% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward current 10ms half sine; with 50% VRRM, Tj = 150oC I2t for fusing ... | Original |
7 pages, |
DF051 sine wave ups designing DS4147-5 DS4147-6 DF051 abstract |
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| Abstract: Frequency Rectification I UPS VOLTAGE RATINGS Type Number DF451 DF451 16 DF451 DF451 14 DF451 DF451 12 DF451 DF451 , Cooled IF(AV) Mean forward current Half wave resistive load, Tcase = 65oC 295 A IF(RMS , A IF Single Side Cooled (Anode side) IF(AV) Mean forward current Half wave resistive , (non-repetitive) forward current Units A2s 10ms half sine; with 0% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward current 10ms half sine; with 50% VRRM, Tj = 150oC I2t for fusing ... | Original |
7 pages, |
sine wave ups designing M771 DF451 DS4142-5 DS4143-6 DF451 abstract |
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| Abstract: s UPS FEATURES s Double Side Cooling s High Surge Capability s Low Recovery Charge VOLTAGE , Half wave resistive load, Tcase = 65oC IF(RMS) RMS value Tcase = 65oC 1360 A , (AV) Mean forward current Half wave resistive load, Tcase = 65oC 515 A IF(RMS) RMS , (non-repetitive) forward current Units A2s 10ms half sine; with 0% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward current 10ms half sine; with 50% VRRM, Tj = 150oC I2t for fusing Surge ... | Original |
9 pages, |
sine wave ups designing DF754 AN4853 AN4839 AN4506 DS4216-3 DS4216-4 DF754 abstract |
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| Abstract: High Frequency Rectification I UPS FEATURES I Double Side Cooling I High Surge Capability I Low , Half wave resistive load, Tcase = 65oC 365 A IF(RMS) RMS value Tcase = 65oC 575 A , (AV) Mean forward current Half wave resistive load, Tcase = 65oC 242 A IF(RMS) RMS , ) forward current Units A2s 10ms half sine; with 0% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward current 10ms half sine; with 50% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive ... | Original |
7 pages, |
sine wave ups designing M771 DFS454 DS4145-4 DS4145-5 DFS454 abstract |
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| Abstract: Welding s High Frequency Rectification s UPS FEATURES s Double Side Cooling s High Surge Capability , Conditions Max. Units Double Side Cooled IF(AV) Mean forward current Half wave resistive load , ) Mean forward current Half wave resistive load, Tcase = 65oC IF(RMS) RMS value Tcase = 65oC , Surge (non-repetitive) forward current 10ms half sine; with 0% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward current 10ms half sine; with 50% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive ... | Original |
8 pages, |
sine wave ups designing DSF20545SF44 DSF20545SF43 DSF20545SF42 DSF20545SF41 DSF20545SF DSF20545SF40 DSF20545SF45 DS4152-3 DS4152-4 DSF20545SF abstract |
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| Abstract: Rectification s UPS FEATURES s Double Side Cooling s High Surge Capability s Low Recovery Charge , Conditions Max. Units Double Side Cooled IF(AV) Mean forward current Half wave resistive load , forward current Half wave resistive load, Tcase = 65oC 242 A IF(RMS) RMS value Tcase = , (non-repetitive) forward current 10ms half sine; with 0% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward current 10ms half sine; with 50% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward ... | Original |
8 pages, |
m771 DFS454 AN4853 AN4839 AN4506 sine wave ups designing DS4145-3 DS4145-4 DFS454 abstract |
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| Abstract: Welding I High Frequency Rectification I UPS FEATURES I Double Side Cooling I High Surge Capability , Parameter Conditions Max. Units Double Side Cooled IF(AV) Mean forward current Half wave , ) IF(AV) Mean forward current Half wave resistive load, Tcase = 65oC IF(RMS) RMS value , current Units A2s 10ms half sine; with 0% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward current 10ms half sine; with 50% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward ... | Original |
7 pages, |
DSF20545SF45 DSF20545SF44 DSF20545SF43 DSF20545SF42 DSF20545SF41 DSF20545SF40 DSF20545SF DS4152-4 DS4152-5 DSF20545SF abstract |
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| Abstract: Frequency Rectification s UPS FEATURES s Double Side Cooling s High Surge Capability s Low Recovery , Conditions Max. Units Double Side Cooled IF(AV) Mean forward current Half wave resistive load , forward current Half wave resistive load, Tcase = 65oC 242 A IF(RMS) RMS value Tcase = , (non-repetitive) forward current 10ms half sine; with 0% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward current 10ms half sine; with 50% VRRM, Tj = 150oC I2t for fusing Surge (non-repetitive) forward ... | Original |
7 pages, |
M771 DFS454 DS4145-3 DS4145-4 DFS454 abstract |
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| Abstract | Saved from | Date Saved | File Size | Type | Download |
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| in companies designing the next wave of DSP applications, particularly start-ups seeking initial -to-voltage converters Sign on for Sine-On Teamwork TI, Ariel join to develop DSP products -op source for PicoGate logic products App Report Designing low-power applications www.datasheetarchive.com/files/texas-instruments/data/sc/docs/integrat/97oct/venture.htm |
Texas Instruments | 08/02/1999 | 10.85 Kb | HTM | venture.htm |
| . This 8/ 16-bit microcontroller contains a cell dedicated to 3-phase sine wave generation, making it eliminates the need for developing time consuming sine wave generation software by providing ready .5 Hz, centred mode, - CPU Load (sine wave generation only) less than 15%, depending on the output SENSOR AC MOTOR DRIVE 3-PHASE SINE WAVE GENERATION SLIP COMMUNICATION PROTOCOL REGULATION describe the sine wave are loaded from the RAM tables into the IMC peripheral registers. Pointers to the www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/7437.htm |
STMicroelectronics | 16/01/2001 | 143.01 Kb | HTM | 7437.htm |
| to 3-phase sine wave generation, making it suitable for standard single- and three-phase AC motor consuming sine wave generation software by providing ready-to-use func- tions that let the user Hz, variable above 27.5 Hz, centred mode, - CPU Load (sine wave generation only) less than 15%, depending on SPI I C 6 PWM outputs NMI SPEED SENSOR AC MOTOR DRIVE 3-PHASE SINE WAVE GENERATION SLIP routine, the PWM values that describe the sine wave are loaded from the RAM tables into the IMC www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/7437-v1.htm |
STMicroelectronics | 30/11/2000 | 140.16 Kb | HTM | 7437-v1.htm |
| . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 12.2.3 Setting Sine Wave Input Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 12.2.4 Setting Square Wave Input Signals /O The I/O pin circuitry offers a range of programmable input and output modes, with program- mable pull-ups . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 3.2 Designing the Application able to open a new scheme and start designing your application. 1 On the File menu, click New project www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/5113-v2.htm |
STMicroelectronics | 14/06/1999 | 229.55 Kb | HTM | 5113-v2.htm |
| . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 12.2.3 Setting Sine Wave Input Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 12.2.4 Setting Square Wave Input Signals /O The I/O pin circuitry offers a range of programmable input and output modes, with program- mable pull-ups . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 3.2 Designing the Application able to open a new scheme and start designing your application. 1 On the File menu, click New project www.datasheetarchive.com/files/stmicroelectronics/stonline/books/ascii/docs/5113.htm |
STMicroelectronics | 02/04/1999 | 229.59 Kb | HTM | 5113.htm |
| them in Charact erization, designing AC Boards etc. - Written interested in an internship dealing with designing ICs, I am also eager to get acquainted with the Tsinghua University as a research assistant, I enjoined the project of designing a four channel CMOS CODEC. My responsibilities covered designing and verifying the circuit and layout of a 16 course work, which was designing a repeat-code detection circuit by using VHDL. Finally, gate www.datasheetarchive.com/files/scenix/htdocs/logs2/resume_log |
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| Motorola MCU Designing for EMC Compatibility with Single-Chip MCUs for more to drive the 68HC908GP20/32 68HC908GP20/32 68HC908GP20/32 68HC908GP20/32? ' answer[21]=' Yes. An external canned oscillator or square wave can be absolute highest value crystal is limited to 100 kHz. Using an external (canned, square wave) oscillator determine the speed at which the timer subsystem can be used. Example: producing a square wave signal using the minimum pulse length that can be produced. This would limit the square wave output to a maximum www.datasheetarchive.com/files/motorola/faq/index.htm |
Motorola | 21/02/2000 | 441.5 Kb | HTM | index.htm |
| Motorola MCU Designing for EMC Compatibility with Single-Chip MCUs for more to drive the 68HC908GP20/32 68HC908GP20/32 68HC908GP20/32 68HC908GP20/32? ' answer[21]=' Yes. An external canned oscillator or square wave can be absolute highest value crystal is limited to 100 kHz. Using an external (canned, square wave) oscillator determine the speed at which the timer subsystem can be used. Example: producing a square wave signal using the minimum pulse length that can be produced. This would limit the square wave output to a maximum www.datasheetarchive.com/files/motorola/faq/index-v1.htm |
Motorola | 21/02/2000 | 441.62 Kb | HTM | index-v1.htm |
| =" , Designing for EMC Compatibility with Single-Chip MCUs for more wave can be used to drive the 68HC908GP20 68HC908GP20 68HC908GP20 68HC908GP20, up to a maximum frequency of 32 MHz externally, with the PLL Hz.Using an external (canned, square wave) oscillator, the fastest speed that can be used with the PLL is determine the speed at which the timer subsystem can be used. Example: producing a square wave signal the minimum pulse length that can be produced. This would limit the square wave output to a maximum www.datasheetarchive.com/files/motorola/faq/mcufaq.txt |
Motorola | 21/02/2000 | 401.87 Kb | TXT | mcufaq.txt |
| show when displaying # of clocks applied before first snapshot Xilinx Answer #856 : ProWave and www.datasheetarchive.com/files/xilinx/docs/wcd00000/wcd00072-v1.htm |
Xilinx | 16/02/1999 | 433.95 Kb | HTM | wcd00072-v1.htm |