Yang Xiangzhou

Real-time microwave frequency variation (MFV) measurement is crucial for a wide range of applications. However, current solutions often fall short in terms of resolution, speed and range. We present a novel technique that leverages the sine-cosine encoder principle, enabled by a photonic delay line (PhDL), to detect rapid MFV in real-time with ultra-high resolution.

Real-time microwave frequency variation (MFV) measurement is crucial for a wide range of applications. However, current solutions often fall short in terms of resolution, speed and range. We present a novel technique that leverages the sine-cosine encoder principle, enabled by a photonic delay line (PhDL), to detect rapid MFV in real-time with ultra-high resolution.

Real-time microwave frequency variation (MFV) measurement is crucial for a wide range of applications. However, current solutions often fall short in terms of resolution, speed and range. We present a novel technique that leverages the sine-cosine encoder principle, enabled by a photonic delay line (PhDL), to detect rapid MFV in real-time with ultra-high resolution.

Real-time microwave frequency variation (MFV) measurement is crucial for a wide range of applications. However, current solutions often fall short in terms of resolution, speed and range. We present a novel technique that leverages the sine-cosine encoder principle, enabled by a photonic delay line (PhDL), to detect rapid MFV in real-time with ultra-high resolution.