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Parts by Number for Clock Time Top

Part # Distributor Manufacturer Product Category Description
24309DS12887 REAL TIME CLOCK National Microchip Not Provided Not Provided Not Provided
DS12887 REAL TIME CLOCK PUL National Microchip DALLAS Not Provided Not Provided
REAL TIME CLOCK PC B ASAP Semiconductor AVX Not Provided ASSY500242
dsPIC33FJ128GP710A Microchip Technology, Inc. Microchip Technology, Inc. Not Provided between clock sources in real time. Idle, Sleep and Doze modes with fast wake-up. Timers/Capture/Compare/PWM: Timer/Counters, up to nine 16-bit timers: - Can pair up to make four 32-bit timers - 1 timer runs as Real-Time Clock with external 32.768 kHz oscillator - Programmable prescaler. Input Capture...
PIC24HJ64GP204 Microchip Technology, Inc. Microchip Technology, Inc. Not Provided as a Real-Time Clock with an external 32.768 kHz oscillator. - Programmable prescaler. . Input Capture (up to four channels): - Capture on up, down or both edges. - 16-bit capture input functions. - 4-deep FIFO on each capture. . Output Compare (up to four channels): - Single or Dual 16-bit Compare mode...
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Conduct Research Top

  • Clock Design Using Low Power/Cost Techniques
    . Author: John Day. A 32.768 kHz crystal was chosen for the clock due to. Sr., Field Application Engineer, Boston. the low power and cost requirements of this design. The. four internal phases of this input clock create an inter-. INTRODUCTION. nal instruction cycle. Therefore, the instruction time
  • Low-Power Real Time Clock
    This application note uses the Timer1 module, from a mid-range PIC16CXXX microcontroller, to control a low-power real-time clock. Timer1 was chosen because it has its own crystal which allows the module to operate during sleep. The two events that will wake the device from sleep
  • Implementing a Realtime Clock
    The purpose of this note is to provide an example of how to add a real-time clock (RTC) feature to a C8051F00x or C8051F01x device. Example software is included at the end of this note. an108rev1_2.fm AN108. IMPLEMENTING A REALTIME CLOCK. Relevant Devices. This application note describes how
  • Yet Another Clock Featuring the PIC16C924
    . PICmicro™. 2k. PIC16C92X. 2k. 2k. 250k. LED. LCD. TIMER1. Currently, the Timer1 module exists in all the. PIC16CXXX devices with 28 or more pins. This module. can be used to easily implement a real-time clock. Instead of an external real-time clock device, an inex-. pensive 32.768 kHz watch crystal
  • PCI Express Clock Generator Considerations
    . As the data rate and bandwidth capabilities have scaled from Gen1 to Gen2 to Gen3, clock generator performance has become increasingly important as well. Learn more about the latest developments in the PCIe market and how new PCIe clock generators are improving performance, while reducing
  • Using Timer 1 in Asynchronous Clock Mode
    This application note discusses the use of the PIC16CXXX Timer1 module as an asynchronous clock. The Timer1 module has it own oscillator circuitry, which allows the timer to keep real-time, even when the device is in SLEEP mode. When the device is in sleep, the oscillator will continue to increment
  • Using Timer 1 in Asynchronous Clock Mode
    This application note discusses the use of the PIC16CXXX Timer1 module as an asynchronous clock. The Timer1 module has it own oscillator circuitry, which allows the timer to keep real-time, even when the device is in SLEEP mode. When the device is in sleep, the oscillator will continue to increment
  • Consolidating Frequency Sources Using Oscillators and Clock Generators
    to the reduced. crystal matching effort and improved reliability mentioned above, advanced clock generators typical y. offer several features that benefit system performance. The output frequency can be changed in real. time, which is useful when systems must adapt to various standards around the world

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