FA-365 20.0000MB-C3

FA-365 20.0000MB-C3 is a type of quartz crystal. It is used in a wide range of applications such as frequency control, resonator and oscillator. It provides accurate frequency control because of its crystalline properties.

Quartz crystals, such as FA-365 20.0000MB-C3, are composed of silicon dioxide. The silica molecules are arranged in an ordered lattice, held together by strong covalent bonds. This lattice structure is anisotropic, meaning that when a frequency is applied, the crystal will vibrate more in one direction than in another. This property allows quartz crystals to be used as highly accurate resonators and oscillators.

The resonance frequency of a quartz crystal is determined by its size and shape, as well as the cut of the crystal. The cut is the angle at which the crystal is cut, relative to its axis of symmetry, and this determines the orientation of the direction of maximum response, or the "tangential cut", which results in the strongest vibration in the direction of the cut. Crystals with a larger and longer surface area are usually the most precise and stable, but the size can be limited by practical considerations.

Crystals can be cut into a variety of precise shapes and sizes. This makes them useful for frequency control in a wide range of applications. Their precise frequency control also makes them attractive for use in industrial and consumer electronics, such as radios, radios, televisions, and computers. The small size of many of the crystals has made them attractive for use in miniature electronic devices.

The principle of operation of quartz crystal is based on the fact that the physical properties of the crystal lattice are affected by a frequency-dependent electric field applied to the crystal. When an electric field is applied to a quartz crystal at and near its resonant frequency, it induces a piezoelectric effect. This creates an impulse that creates a mechanical wave of vibration within the crystal that is the same frequency as the applied field. This wave of vibration, referred to as a fundamental wave, is used to precisely control frequency.

Quartz crystals are also used in oscillators to generate a periodic waveform with a fixed frequency. The waveform can be adjusted by varying the capacitance of the circuit. At a certain frequency, known as the oscillator\'s resonance frequency, the crystal produces a waveform that is in perfect harmony with the frequency of the circuit. This waveform produces a more stable and consistent signal than other forms of wave production such as mill supply wave, phase locked loops, and frequency divider.

In addition to frequency control, quartz crystals can be used in a wide range of applications such as waveform shaping and timekeeping. For example, quartz crystals are used in radio receivers to filter out unwanted radio signals, and in electron microscopes to maintain a consistent image size. Quartz crystals are also used in frequency counters, clocks, and watches to ensure accurately timed readings.

FA-365 20.0000MB-C3 is an example of a quartz crystal that has a relatively high frequency with low jitter, making it suitable for use in many electronic devices. It is used in a variety of applications such as frequency standards, frequency synthesizers, and communication systems.

In conclusion, quartz crystals, such as FA-365 20.0000MB-C3, are widely used in many electronic devices because of their precise and consistent frequency control. Their physical properties, including the size and shape of the crystal and the angle of the bevel, determine the exact frequency it can generate. They can be used to precisely control frequency, waveform generation, and timekeeping in a variety of applications.