Kookjin Sung scite author profile

Technical details associated with a novel relative motion sensor system are elaborated in the paper. By utilizing the Doppler effect, the optical sensor system estimates the relative motion rates between the sensor and the moving object equipped with modulating light sources and relatively inexpensive electrical components. A transimpedance amplifier (TIA) sensing circuit is employed to measure the Doppler shift exhibited by the amplitude modulated light sources on the moving platform. Implementation details associated with the amplitude modulation and photo-detection processes are discussed using representative hardware elements. A heterodyne mixing process with a reference signal is shown to improve the signal-to-noise ratios of the Doppler shift estimation processing pipeline. Benchtop prototype experiments are used to demonstrate the utility of the proposed technology for relative motion estimation applications.

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An FPGA framework for Interferometric Vision-Based Navigation (iVisNav)

Bhaskara

Sung

Majji

2022

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An FPGA framework for Interferometric Vision-Based Navigation (iVisNav)

Bhaskara¹,

Sung²,

Majji³

2022

Preprint

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Interferometric Vision-Based Navigation (iVisNav) is a novel optoelectronic sensor for autonomous proximity operations. iVisNav employs laser emitting structured beacons and precisely characterizes six degrees of freedom relative motion rates by measuring changes in the phase of the transmitted laser pulses. iVisNav's embedded package must efficiently process high frequency dynamics for robust sensing and estimation. A new embedded system for least squares-based rate estimation is developed in this paper. The resulting system is capable of interfacing with the photonics and implement the estimation algorithm in a field-programmable gate array. The embedded package is shown to be a hardware/software co-design handling estimation procedure using finite precision arithmetic for highspeed computation. The accuracy of the finite precision FPGA hardware design is compared with the floating-point software evaluation of the algorithm on MATLAB to benchmark its performance and statistical consistency with the error measures. Implementation results demonstrate the utility of FPGA computing capabilities for high-speed proximity navigation using iVisNav.

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An Optical Navigation System for Autonomous Aerospace Systems

et al. 2022

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Kookjin Sung

Interferometric Vision-Based Navigation Sensor for Autonomous Proximity Operation

Doppler Measurement of Modulated Light for High Speed Vehicles

An FPGA framework for Interferometric Vision-Based Navigation (iVisNav)

An FPGA framework for Interferometric Vision-Based Navigation (iVisNav)

An Optical Navigation System for Autonomous Aerospace Systems

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