Behavior of Signal from Optical Circuit of Quantum Rotation Sensor Based on Nuclear Magnetic Resonance.

The paper considers a common operation principle of a quantum rotation sensor based on nuclear magnetic resonance, giving a semiclassical description of processes in the sensor circuit, that enables the analytical representation to be obtained for a signal at the optical circuit output. The principles of numerical calculation are briefly presented for an optical signal of the rotation sensor based on a one-dimensional quantum model. The comparison of calculations according to classical model and more strict quantum model has shown that the sensor signal has a more complicated structure than that following from the classical description which shows only some

properties of dynamic processes in the circuit. The results are important for development of methods of demodulating the quantum rotation sensor optical signal and for estimation of expected characteristics of practical devices.

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