This technical guide examines how Allan Deviation (ADEV) and aging rate impact the performance of low-power OCXOs in seismic monitoring systems. For earthquake detection requiring nanosecond-level timing precision, we analyze key stability metrics including short-term ADEV (

Selecting the right low-power OCXO is critical for seismic monitoring systems that require ultra-stable timing in remote, power-constrained environments. This guide explores seven key factors for choosing optimal OCXOs: frequency stability (±0.1 ppb), power efficiency (100k hours), and compatible po... read more

Modern earthquake monitoring systems require ultra-stable timing solutions to detect seismic activity with precision. Low Power Oven-Controlled Crystal Oscillators (OCXOs) have emerged as a game-changer, delivering exceptional frequency stability and ultra-low phase noise while operating efficiently... read more

Seismology requires ultra-precise timing to detect earthquakes and analyze seismic waves effectively. Low-power Oven-Controlled Crystal Oscillators (OCXOs) provide the perfect solution, delivering exceptional frequency stability and ultra-low phase noise while minimizing energy consumption. These ad... read more

Low Power OCXOs (LP-OCXOs) are transforming earthquake monitoring by delivering atomic-clock precision with unprecedented energy efficiency. These advanced timing solutions overcome the limitations of traditional GPS and standard OCXOs, enabling microsecond synchronization across seismic networks wh... read more