DeLiDAR: Decoupling LiDARs for pervasive spatial computing

DeLiDAR: Decoupling LiDARs for pervasive spatial computing

Unbounded proliferation of LiDAR-equipped pervasive devices generates two challenges: (a) mutual interference among emitters and (b) significantly higher sensing energy overhead. We propose a fundamentally different approach for LiDAR sensing, in indoor spaces, that decouples the sensor’s emitter an...

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Main Authors: KANATTA GAMAGE RAMESH DARSHANA RATHNAYAKE, Sutradhar, Razat, Nishar, Abbaas A. M., Weerakoon Dulaj S., Ashok, Ashwin, MISRA, Archan
Format: text
Language:English
Published: Institutional Knowledge at Singapore Management University 2024
Subjects:
Angle of Arrival estimation
Depth estimation
LiDAR
Software Engineering
Online Access:https://ink.library.smu.edu.sg/sis_research/10122
https://ink.library.smu.edu.sg/context/sis_research/article/11122/viewcontent/mrose24_Delidar_av.pdf
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Institution: Singapore Management University
Language: English
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spelling sg-smu-ink.sis_research-111222025-03-10T04:09:38Z DeLiDAR: Decoupling LiDARs for pervasive spatial computing KANATTA GAMAGE RAMESH DARSHANA RATHNAYAKE, Sutradhar, Razat Nishar, Abbaas A. M. Weerakoon Dulaj S., Ashok, Ashwin MISRA, Archan Unbounded proliferation of LiDAR-equipped pervasive devices generates two challenges: (a) mutual interference among emitters and (b) significantly higher sensing energy overhead. We propose a fundamentally different approach for LiDAR sensing, in indoor spaces, that decouples the sensor’s emitter and receiver components. Our proposed approach, called DeLiDAR, centralizes the emitter functionality in one or more stationary nodes that continually emit pulses; this decoupling allows each mobile LiDAR sensor to be an ultra-low power, pure receiver unit consisting solely of passive multiple photodiodes. We explain how the emitter can utilize VLC-based encoding of its pulses to convey parameter settings that allow a receiver device to infer its own point cloud, without requiring any timing or clock synchronization with the emitter. An initial experimental setup, consisting of a Raspberry Pi and an Arduino-based emitter/2-diode receiver, demonstrates the ability to recover the light pulse’s AoA with a resolution of ±5◦. We also highlight key systems challenges to realize DeLiDAR in practice. 2024-12-01T08:00:00Z text application/pdf https://ink.library.smu.edu.sg/sis_research/10122 https://ink.library.smu.edu.sg/context/sis_research/article/11122/viewcontent/mrose24_Delidar_av.pdf http://creativecommons.org/licenses/by-nc-nd/4.0/ Research Collection School Of Computing and Information Systems eng Institutional Knowledge at Singapore Management University Angle of Arrival estimation Depth estimation LiDAR Software Engineering
institution Singapore Management University
building SMU Libraries
continent Asia
country Singapore
Singapore
content_provider SMU Libraries
collection InK@SMU
language English
topic Angle of Arrival estimation
Depth estimation
LiDAR
Software Engineering
spellingShingle Angle of Arrival estimation
Depth estimation
LiDAR
Software Engineering
KANATTA GAMAGE RAMESH DARSHANA RATHNAYAKE,
Sutradhar, Razat
Nishar, Abbaas A. M.
Weerakoon Dulaj S.,
Ashok, Ashwin
MISRA, Archan
DeLiDAR: Decoupling LiDARs for pervasive spatial computing
description Unbounded proliferation of LiDAR-equipped pervasive devices generates two challenges: (a) mutual interference among emitters and (b) significantly higher sensing energy overhead. We propose a fundamentally different approach for LiDAR sensing, in indoor spaces, that decouples the sensor’s emitter and receiver components. Our proposed approach, called DeLiDAR, centralizes the emitter functionality in one or more stationary nodes that continually emit pulses; this decoupling allows each mobile LiDAR sensor to be an ultra-low power, pure receiver unit consisting solely of passive multiple photodiodes. We explain how the emitter can utilize VLC-based encoding of its pulses to convey parameter settings that allow a receiver device to infer its own point cloud, without requiring any timing or clock synchronization with the emitter. An initial experimental setup, consisting of a Raspberry Pi and an Arduino-based emitter/2-diode receiver, demonstrates the ability to recover the light pulse’s AoA with a resolution of ±5◦. We also highlight key systems challenges to realize DeLiDAR in practice.
format text
author KANATTA GAMAGE RAMESH DARSHANA RATHNAYAKE,
Sutradhar, Razat
Nishar, Abbaas A. M.
Weerakoon Dulaj S.,
Ashok, Ashwin
MISRA, Archan
author_facet KANATTA GAMAGE RAMESH DARSHANA RATHNAYAKE,
Sutradhar, Razat
Nishar, Abbaas A. M.
Weerakoon Dulaj S.,
Ashok, Ashwin
MISRA, Archan
author_sort KANATTA GAMAGE RAMESH DARSHANA RATHNAYAKE,
title DeLiDAR: Decoupling LiDARs for pervasive spatial computing
title_short DeLiDAR: Decoupling LiDARs for pervasive spatial computing
title_full DeLiDAR: Decoupling LiDARs for pervasive spatial computing
title_fullStr DeLiDAR: Decoupling LiDARs for pervasive spatial computing
title_full_unstemmed DeLiDAR: Decoupling LiDARs for pervasive spatial computing
title_sort delidar: decoupling lidars for pervasive spatial computing
publisher Institutional Knowledge at Singapore Management University
publishDate 2024
url https://ink.library.smu.edu.sg/sis_research/10122
https://ink.library.smu.edu.sg/context/sis_research/article/11122/viewcontent/mrose24_Delidar_av.pdf
_version_ 1827070822824542208

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