FA-128 37.4000MF10Z-C5

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Crystals are an essential component of numerous electronic systems. Used to create wave forms, modify signals, or filter out noise or unwanted signals in many applications, the FA-128 37.4000MF10Z-C5 crystal is designed to perform a wide array of functions. The following is a brief overview of the types of applications the crystal can be used for, as well as its working principle.

Applications

The FA-128 37.4000MF10Z-C5 crystal is a microprocessor-based oscillator that is used in a wide variety of applications, such as communications, instrumentation, and signal transmission. It can be used as an oscillator to create waveforms, such as square wave, pulse, or sine wave, which can be used for various signal processing purposes. It is also suitable for filter circuits, clock synchronization, low-power applications, and acoustic wave resonators.

The crystal is most commonly used in radio equipment, such as cell phones and wireless communication systems. It is also used in precision watches, adjustable frequency generators, and various medical and industrial equipment. Furthermore, it can be used in automotive electronics and in aerospace and military applications. It is also ideal for accuracy and frequency regulation in power generation operations and power grid monitoring.

Working Principle

The FA-128 37.4000MF10Z-C5 crystal is a fixed-frequency crystal that consists of a thin slice of a crystal, usually quartz, that is mounted on a base plate and connected to two electrodes. When supplied with an electrical signal, the crystal oscillates at its natural resonant frequency. The crystal generates an alternating current signal, which is picked up by the electrodes. This alternating current signal, which has the same frequency as the resonant frequency of the crystal, is then amplified by a transistor before it is sent back to the crystal.

The returned amplification oscillates at the crystal’s resonant frequency and then passes through an amplifier. This allows the crystal to operate as an oscillator and generate the needed waveform or frequency. The output from the amplifier is then fed to the output circuits, depending on the intended application.

The crystal’s resonant frequency is determined by the type of crystal used, the cut of the crystal, and the mass of the electrodes used. Such factors are carefully taken into account when choosing the right crystal for a particular application. The frequency accuracy and stability of the crystal are determined by its temperature coefficient, typically between 10 ppm to 50 ppm. Depending on the cut, the temperature coefficient of the FA-128 37.4000MF10Z-C5 crystal is around 14 ppm.

Conclusion

The FA-128 37.4000MF10Z-C5 crystal is a versatile and reliable oscillator that is used in various communication, instrumentation, and transmission applications. Its resonant frequency is determined by the cut and shape of the crystal, as well as the mass and type of electrodes used. Furthermore, the temperature coefficient of the crystal is typically between 10 ppm to 50 ppm, with an accuracy of around 14 ppm for this specific model. This makes it suitable for a wide range of applications that require precise frequency control or regulation.

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