CA-301 18.4320M-C

Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us:   sales@allicdata.com

Crystals play a crucial role in modern electronics and communication, from the tiny quartz oscillators used in wristwatches to the vast array of crystals used in radio communications. At the heart of this technology is the CA-30118.4320M-C crystal, a precise and reliable crystal oscillator that can be used for a variety of applications. In this article, we will look at the various applications for this crystal and explain its working principle.

Application Fields

The CA-30118.4320M-C is a high-precision frequency crystal controlling oscillator and can be used in a wide range of applications. It is particularly well-suited to radio and TV broadcasting, as it has good performance over a wide frequency range and is very stable in terms of frequency and temperature. It can also be used in frequency synthesis, as well as in ultra-wideband communication systems.

The crystal can also be used in medical equipment and other precision instrumentation. It is particularly suitable for ECG and EEG measurement machines, as it has a low level of noise and excellent accuracy over a temperature range from -20 to 70°C. It is also used in frequency discriminators, signal generator circuits, and other timing circuits.

Finally, the CA-30118.4320M-C crystal is also suitable for cellular base station applications. It is used in GSM and CDMA base stations, providing reliable frequency control for these systems. The crystal can also be used in GPS receivers, providing a highly reliable reference signal.

Working Principle

The CA-30118.4320M-C crystal is a quartz-based crystal oscillator. Quartz crystals are piezoelectric, meaning they vibrate at a precise frequency when a voltage is applied. The crystal consists of two quartz plates with electrodes on each plate. When a voltage is applied to the crystal, the quartz plates vibrate, creating a precise alternating current with a frequency determined by the size of the crystal. The frequency can be adjusted by varying the voltage applied to the crystal.

The frequency at which the crystal vibrates is determined by the ratio of thickness to width of the quartz plates. Each plate contains electrodes that form an electrical circuit, and this circuit is used to detect the resonance of the crystal. The resonant frequency is then used to control the oscillation frequency of the crystal, which is used to generate a precise and stable signal.

The CA-30118.4320M-C crystal is a high-performance oscillator with excellent frequency stability and low jitter. This is achieved by using a temperature-compensated crystal oscillator circuit to ensure that the frequency remains accurate over a wide temperature range. The frequency can also be adjusted over a wide range without sacrificing performance.

Conclusion

The CA-30118.4320M-C crystal is a high-performance oscillator used in a wide range of applications. Its high-precision frequency control and low jitter make it ideal for radio and TV broadcasting, frequency synthesis, and cellular base station applications. The crystal works by vibrating at a precise frequency when a voltage is applied, and this frequency is controlled by the ratio of thickness to width of the quartz plates. It is temperature-compensated to ensure the frequency remains accurate over a wide temperature range.

The specific data is subject to PDF, and the above content is for reference