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A Temperature Compensated Crystal Oscillator, abbreviated as TCXO, is a crucial electronic component used for precise frequency control. Temperature has a significant impact on the stability of the crystal oscillator frequency, and a TCXO is a solution that can provide highly stable frequency output under varying temperature conditions.
High Stability
TCXO Temperature compensated crystal oscillators can provide stable frequency output over a wide range of temperatures, reducing the impact of temperature changes on equipment performance.
Low Phase Noise
Temperature compensated crystal oscillators have low phase noise levels, making them suitable for applications that require high frequency accuracy and signal quality.
Small Size and Low Power Consumption
Temperature compensated crystal oscillators have a small size and low power consumption, making them ideal for mobile and portable applications such as mobile satellite communications, base stations, radars, beacons and rescue systems, WLAN, testing, and instrumentation.
From ensuring accurate navigation in GPS systems to operating aerospace instruments under extreme conditions, the reliability and accuracy of temperature compensated crystal oscillators have become synonymous with uncompromised performance. Temperature compensated crystal oscillators play a key role in various industries. Their ability to maintain frequency stability, especially under temperature fluctuations, not only fosters technological advancements but also sets standards in many aspects.
As one of the professional TCXO manufacturers, XtalTQ's 100MHz TCXO offers excellent frequency stability and high precision, making it very suitable for high-frequency applications such as telecommunications and RF systems.
The 100MHz TCXO is meticulously designed to operate stably and reliably under different temperatures, ensuring accurate and consistent timing, thereby enhancing the overall performance of the system.
The 100MHz TCXO is suitable for applications requiring precise timing and synchronization, thus reducing timing errors and ensuring the consistency of system performance.
