Crystals have been used as essential components in various electronic applications across various disciplines due to their unique properties. 9C16076001 is one such crystal that has been extensively used in applications for frequency control or timing reference because of its superior features. This article provides a comprehensive overview of 9C16076001 applications and working principles.
Application Field
9C16076001 is a type of crystal oscillator used in frequency control and timing applications. It is typically used in conjunction with other devices such as frequency synthesizers and highly integrated (SiP)discrete components. This crystal oscillator provides an oscillator circuit with stable, accurate frequency and excellent aging characteristics. It works over a broad frequency range and its low jitter, low power loss and high stability are some of its main advantages.
The 9C16076001 oscillator is mainly used in the telecom industry, wherein it is employed for frequency synthesizing, channel switching and timing application requirements. It is also employed in consumer electronics, automotive, medical technology, aviation and military equipment applications. Due to its excellent features, this crystal oscillator is the ideal choice for applications that require stable and accurate frequency or timing references such as microcontrollers, wireless communication systems, and audio applications.
Working Principle
9C16076001 works on the principle of mechanical resonance. The basic working principle is based on the piezoelectric effect. The piezoelectric effect refers to the production of electrical charge when a crystal is deformed by pressure. In the 9C16076001 oscillator, two electrodes are connected to the crystal, one on either side. When a voltage is applied to the electrodes, the crystal vibrates at its resonant frequency and generates an electrical signal at the electrodes.
This electrical signal is then amplified and fed back to the crystal, thus creating a cycle that causes the crystal to vibrate continuously at its resonance frequency. The output signal is a steady stream of pulses with a frequency equivalent to the resonant frequency of the crystal. The 9C16076001 oscillator is coupled with a circuit that stabilizes the output frequency produced by the oscillator. This ensures the stability and accuracy of the oscillator’s output frequency over a wide range of temperature and other environmental conditions.
Conclusion
In conclusion, 9C16076001 is a crystal oscillator that is extensively used in applications requiring stable and accurate frequency or timing references. It is based on the piezoelectric effect and works on the principle of mechanical resonance. It provides excellent features such as low jitter, low power loss and high stability. The oscillator is mainly employed in the telecom industry but is also used in other fields such as consumer electronics, automotive, medical technology, aviation and military equipment applications.