Abstract: A signal conditioning circuit reduces an interferrometric fiber optic gyro (IFOG) noise, the IFOG including a light source, Integrated Optics Chips (IOC) and a coupler to output an optical power signal corresponding to a rotation-induced phase shift in a fiber coil of the IFOG. The signal conditioning circuit includes a photodiode that converts the optical power signal to a corresponding electrical compensation signal and one or more switched integrators that receive and process the electrical compensation signal by selectively switching between a plurality of modes of each one of the one or more switched integrators. A method of signal conditioning in the IFOG to reduce IFOG noise includes the steps of converting the optical power signal to a corresponding electrical compensation signal and selectively integrating a current of the electrical compensation signal using at least one switched integrator.

Abstract: A noise reducing thermal-electrically cooled photodetector for an Interferrometric Fiber Optic Gyro (IFOG) includes a photodiode that converts an optical power signal received from a coupler of the IFOG to an electrical compensation signal. The photodiode is in mechanical contact with one or more thermoelectric coolers (TEC) to lower an operating temperature of the photodiode. The photodetector also includes an amplifier circuit to amplify the electrical compensation signal. The amplifier circuit includes an operational amplifier having an input and an output, with a feedback resistor interposed between the input and output. The feedback resistor is also in mechanical contact with a TEC to lower an operating temperature of the feedback resistor. By reducing the operating temperature of the feedback resistor and the photodiode the thermal noise of the IFOG is reduced.

Abstract: A system for minimizing non-linearity in an Interferometric Fiber Optic Gyro (IFOG) that includes a light source, an Integrated Optics Chip (IOC) with first and second optical modulators, and a coupler to output an optical power signal corresponding to a rotation-induced phase shift in a fiber coil of the IFOG to processing electronics of the IFOG. The processing electronics include signal processing means to produce a digital signal corresponding to the optical power signal. A first digital-to-analog converter (DAC) receives the digital signal and provides a corresponding first modulation signal to the first optical modulator via a first amplifier. However, the first DAC and first optical modulator inherently introduce non-linearities into the first modulation signal. A second DAC receives the digital signal and provides a corresponding second modulation signal to the second optical modulator via a second amplifier.

Abstract: A noise reducing thermal-electrically cooled photodetector for an Interferrometric Fiber Optic Gyro (IFOG) includes a photodiode that converts an optical power signal received from a coupler of the IFOG to an electrical compensation signal. The photodiode is in mechanical contact with one or more thermoelectric coolers (TEC) to lower an operating temperature of the photodiode. The photodetector also includes an amplifier circuit to amplify the electrical compensation signal. The amplifier circuit includes an operational amplifier having an input and an output, with a feedback resistor interposed between the input and output. The feedback resistor is also in mechanical contact with a TEC to lower an operating temperature of the feedback resistor. By reducing the operating temperature of the feedback resistor and the photodiode the thermal noise of the IFOG is reduced.

Abstract: A signal conditioning circuit reduces an interferrometric fiber optic gyro (IFOG) noise, the IFOG including a light source, Integrated Optics Chips (IOC) and a coupler to output an optical power signal corresponding to a rotation-induced phase shift in a fiber coil of the IFOG. The signal conditioning circuit includes a photodiode that converts the optical power signal to a corresponding electrical compensation signal and one or more switched integrators that receive and process the electrical compensation signal by selectively switching between a plurality of modes of each one of the one or more switched integrators. A method of signal conditioning in the IFOG to reduce IFOG noise includes the steps of converting the optical power signal to a corresponding electrical compensation signal and selectively integrating a current of the electrical compensation signal using at least one switched integrator.