TSX-3225 Epson 16.000000MHz quartz crystal resonator X1E000021091300

In electronic circuit systems, frequency is like the metronome that runs the system. The frequency of 16MHz has a wide range of applications in various electronic scenarios. In the field of digital circuits, it can serve as a clock signal to provide stable working cycles for microprocessors, microcontrollers, and other chips, ensuring that data transmission, processing, and storage operations can be carried out according to precise timing. For example, in some simple embedded systems, a 16MHz clock signal can drive a microcontroller to efficiently execute instructions and achieve various functions, such as sensor data acquisition and controlling external devices. In the field of communication, this frequency can participate in the modulation and demodulation process of signals, providing support for the quality and stability of communication signals, and ensuring accurate transmission of information between different devices.

The working principle of quartz crystal resonators based on the piezoelectric effect of quartz crystals. Quartz crystals have a special lattice structure, and when an alternating electric field is applied at both ends, the crystal will produce mechanical vibrations due to the piezoelectric effect. The frequency of this mechanical vibration is closely related to the natural frequency of quartz crystals. For the TSX-3225 model X1E000021091300, through precise design and manufacturing processes, the natural frequency of the quartz crystal has reached 16.0 million MHz.

Resonance produces a stable frequency output mechanism. When the frequency of the external circuit approaches the natural frequency of the quartz crystal, resonance occurs. In the resonant state, the vibration amplitude of the quartz crystal reaches its maximum and can output a stable frequency signal of 16.0 million MHz in the circuit. This stable frequency signal is like a reliable signal source, providing a stable clock source or frequency reference for various circuits in electronic devices, thereby ensuring the normal operation of the equipment. For example, in digital signal processing circuits, the stable frequency signal output by the resonator can provide accurate time references for signal sampling, quantization, and encoding operations, ensuring the accuracy of signal processing.

Epson adopts high-precision manufacturing processes and strict quality control measures in the production process, with the advantage of high-precision frequency output. By precisely controlling multiple aspects such as the cutting angle, dimensional accuracy, and electrode deposition of the quartz crystal, it is ensured that the resonator can output high-precision 16.0 million MHz frequency signals. In application scenarios that require extremely high frequency accuracy, such as high-precision measuring instruments and high-speed communication equipment, this high-precision frequency output can effectively reduce signal distortion and errors, ensuring the accuracy and stability of the equipment.

Excellent frequency stability performance: This quartz crystal resonator can maintain excellent frequency stability in the face of various environmental factors such as temperature changes, humidity changes, and mechanical vibrations. This is mainly due to Epson's selection of high-quality quartz materials and advanced packaging technology. High quality quartz materials themselves have good temperature stability and mechanical stability, while special packaging structures can effectively isolate the influence of external environmental factors on quartz crystals. In complex and ever-changing environments such as industrial automation equipment and outdoor communication base stations, the TSX-3225 model X1E000021091300 can work stably, providing a reliable frequency reference for the system.

The benefit of low equivalent series resistance (ESR) characteristics is that ESR is an important indicator for measuring the performance of quartz crystal resonators. The TSX-3225 model X1E000021091300 has a lower ESR, which means that in the circuit, there is less energy loss when the signal passes through the resonator, which can improve the transmission efficiency of the signal. In high-frequency circuits and applications that require high signal strength, low ESR characteristics can ensure signal integrity, reduce signal attenuation, and enable the quartz crystal resonator to work better with other electronic components, improving the performance of the entire circuit system.