AK8111 - Asahi Kasei Microdevices
... support, or other hazard related device or systemNote2), and AKEMD assumes no responsibility for such use, except for the use approved with the express written consent by Representative Director of AKEMD. As used here: Note1) A critical component is one whose failure to function or perform may reaso ...
... support, or other hazard related device or systemNote2), and AKEMD assumes no responsibility for such use, except for the use approved with the express written consent by Representative Director of AKEMD. As used here: Note1) A critical component is one whose failure to function or perform may reaso ...
MAX7375 3-Pin Silicon Oscillator General Description Features
... The MAX7375 operates with power-supply voltages in the 2.7V to 5.5V range. Good power-supply decoupling is needed to maintain the power-supply rejection performance of the MAX7375. Use a 0.1µF surface-mount ceramic capacitor connected between V+ and GND and mounted as close to the device as possible ...
... The MAX7375 operates with power-supply voltages in the 2.7V to 5.5V range. Good power-supply decoupling is needed to maintain the power-supply rejection performance of the MAX7375. Use a 0.1µF surface-mount ceramic capacitor connected between V+ and GND and mounted as close to the device as possible ...
example design
... something we encourage you to do, and other thing completely different is to write VHDL code that has to be easily analysed and assessed by your team mates and the instructor in very short time. This is why all the class has to follow a very tight coding conventions or styles. Therefore, to translat ...
... something we encourage you to do, and other thing completely different is to write VHDL code that has to be easily analysed and assessed by your team mates and the instructor in very short time. This is why all the class has to follow a very tight coding conventions or styles. Therefore, to translat ...
paper
... to accommodate a wide range of operation frequencies and voltages. By adjusting the relative phase between two clocks of the same frequency, and using one clock as reference to sample the other after it has been received by the circuit, we can measure the jitter performance of the circuit. As shown ...
... to accommodate a wide range of operation frequencies and voltages. By adjusting the relative phase between two clocks of the same frequency, and using one clock as reference to sample the other after it has been received by the circuit, we can measure the jitter performance of the circuit. As shown ...
SOiid-State oua1-c1ock Generator
... the frequency over a 3.5 to 1 range with a single capacitor, or voltage control the thing with an external 3- to 5-volt de control voltage. The output directly drives TTL, RTL. DTL, or low-threshold MOS integrated circuits, and with a good power supply, the frequency is stable enough for mu sic syn ...
... the frequency over a 3.5 to 1 range with a single capacitor, or voltage control the thing with an external 3- to 5-volt de control voltage. The output directly drives TTL, RTL. DTL, or low-threshold MOS integrated circuits, and with a good power supply, the frequency is stable enough for mu sic syn ...
Example
... A main program should successively call the subroutine sound.asm for each of the notes of the tune to be played, passing to it, as arguments, the frequency corresponding to the note, and the duration in milliseconds that the note is to be played. sound.asm implements the frequencies required by send ...
... A main program should successively call the subroutine sound.asm for each of the notes of the tune to be played, passing to it, as arguments, the frequency corresponding to the note, and the duration in milliseconds that the note is to be played. sound.asm implements the frequencies required by send ...
Problem - UCLA.edu
... Please choose one type decap out of the following candidates that can help you achieve this goal. ...
... Please choose one type decap out of the following candidates that can help you achieve this goal. ...
Time-to-digital converter
In electronic instrumentation and signal processing, a time to digital converter (abbreviated TDC) is a device for recognizing events and providing a digital representation of the time they occurred. For example, a TDC might output the time of arrival for each incoming pulse. Some applications wish to measure the time interval between two events rather than some notion of an absolute time.In electronics time-to-digital converters (TDCs) or time digitizers are devices commonly used to measure a time interval and convert it into digital (binary) output. In some cases interpolating TDCs are also called time counters (TCs).TDCs are used in many different applications, where the time interval between two signal pulses (start and stop pulse) should be determined. Measurement is started and stopped, when either the rising or the falling edge of a signal pulse crosses a set threshold. These requirements are fulfilled in many physical experiments, like time-of-flight and lifetime measurements in atomic and high energy physics, experiments that involve laser ranging and electronic research involving the testing of integrated circuits and high-speed data transfer.