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3.3V voltage controlled oscillator features surface mount package of 7 x 5mm, wide pullability with low phase noise.
3.3V or 5V voltage controlled oscillator features surface mount package of 9 x 14mm.
It is available at high frequencies of up to 122.88MHz and features LVDS, and LVPECL output.
The voltage controlled oscillator features surface mount package of 9 x 14mm.
It is available at high frequencies of up to 122.88MHz and features cmos, and Sinewave output. It has wide pulling range and low phase noise.
The voltage controlled oscillator features DIP14. It is available at high frequencies of up to 122.88MHz and features cmos, and Sinewave output. It has wide pulling range and low phase noise.
Ultra Low Phase Noise VCXO (Voltage-Controlled Crystal Oscillator) is essential for enhancing signal integrity in high-performance electronic systems. These oscillators provide exceptional frequency stability and minimal phase noise, which are critical for maintaining the clarity and accuracy of signals in advanced communication, radar, and instrumentation applications.
In communication systems, Ultra Low Phase Noise VCXOs ensure that transmitted and received signals remain clean and free from jitter, thereby improving data integrity and reducing error rates. This is particularly important in high-speed data transmission and wireless communication, where even minor signal distortions can lead to significant performance degradation.
In radar and defense systems, the low phase noise characteristics of these VCXOs enhance target detection and tracking accuracy by minimizing signal interference and noise. This results in clearer and more reliable radar images and data.
Moreover, in test and measurement equipment, Ultra Low Phase Noise VCXOs provide stable reference signals, ensuring precise measurements and calibration. Their superior performance under varying environmental conditions makes them ideal for demanding applications where signal integrity is paramount.
Improved Signal Clarity: In communication systems, low phase noise reduces interference, preserving signal integrity and minimizing data errors during high-speed transmissions.
Higher Resolution in Radar Systems: Low phase noise enhances a radar’s ability to detect and differentiate small or distant objects by improving range and resolution.
Accurate Frequency Synthesis: For systems relying on precise frequency generation, like frequency synthesizers or clocks, low phase noise prevents frequency instability, ensuring consistent, reliable timing.
Better Performance in Test Equipment: Instruments like spectrum analyzers and signal generators need low phase noise to make accurate, noise-free measurements, especially when analyzing weak signals.
Stable Timing in Critical Systems: In applications like satellite communications, GPS, and telecom networks, low phase noise ensures synchronization, preventing timing errors that could disrupt operations.
