Modelling and analysis of vector and vector vortex beams reflection for optical sensing
Modelling and analysis of vector and vector vortex beams reflection for optical sensing
Light Detection and Ranging (LiDAR) sensors can precisely determine object distances using the pulsed time of flight (TOF) or amplitude-modulated continuous wave (AMCW) TOF methods and velocity using the frequency-modulated continuous wave (FMCW) approach. In this paper, we focus on modelling and analysing the reflection of vector beams (VBs) and vector vortex beams (VVBs) for optical sensing in LiDAR applications. Unlike traditional TOF and FMCW methods, this novel approach uses VBs and VVBs as detection signals to measure the orientation of reflecting surfaces. A key component of this sensing scheme is understanding the relationship between the characteristics of the reflected optical fields and the orientation of the reflecting surface. To this end, we develop a computational model for the reflection of VBs and VVBs. This model allows us to investigate critical aspects of the reflected field, such as intensity distribution, intensity centroid offset, reflectance, and the variation of the intensity range measured along the azimuthal direction. By thoroughly analysing these characteristics, we aim to enhance the functionality of LiDAR sensors in detecting the orientation of reflecting surfaces.
light detection and ranging (LiDAR), deflection angle detection;, light beams reflection processes computational model;, vector beams (VB), vector vortex beam (VVB)
Yu, Wangke
c5688b04-647c-4189-a3b0-ac87aa883bbf
Yan, Jize
786dc090-843b-435d-adbe-1d35e8fc5828
4 August 2024
Yu, Wangke
c5688b04-647c-4189-a3b0-ac87aa883bbf
Yan, Jize
786dc090-843b-435d-adbe-1d35e8fc5828
Yu, Wangke and Yan, Jize
(2024)
Modelling and analysis of vector and vector vortex beams reflection for optical sensing.
Photonics, 11 (8), [729].
(doi:10.3390/photonics11080729).
Abstract
Light Detection and Ranging (LiDAR) sensors can precisely determine object distances using the pulsed time of flight (TOF) or amplitude-modulated continuous wave (AMCW) TOF methods and velocity using the frequency-modulated continuous wave (FMCW) approach. In this paper, we focus on modelling and analysing the reflection of vector beams (VBs) and vector vortex beams (VVBs) for optical sensing in LiDAR applications. Unlike traditional TOF and FMCW methods, this novel approach uses VBs and VVBs as detection signals to measure the orientation of reflecting surfaces. A key component of this sensing scheme is understanding the relationship between the characteristics of the reflected optical fields and the orientation of the reflecting surface. To this end, we develop a computational model for the reflection of VBs and VVBs. This model allows us to investigate critical aspects of the reflected field, such as intensity distribution, intensity centroid offset, reflectance, and the variation of the intensity range measured along the azimuthal direction. By thoroughly analysing these characteristics, we aim to enhance the functionality of LiDAR sensors in detecting the orientation of reflecting surfaces.
Text
photonics-11-00729
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More information
Accepted/In Press date: 30 July 2024
Published date: 4 August 2024
Keywords:
light detection and ranging (LiDAR), deflection angle detection;, light beams reflection processes computational model;, vector beams (VB), vector vortex beam (VVB)
Identifiers
Local EPrints ID: 493184
URI: http://eprints.soton.ac.uk/id/eprint/493184
ISSN: 2304-6732
PURE UUID: 9f331b89-25ac-4739-8783-66eb5947cf5d
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Date deposited: 27 Aug 2024 16:49
Last modified: 28 Aug 2024 01:48
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Author:
Wangke Yu
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