Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement

Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement

In this article, we investigate effective ways of utilizing crowdworkers in providing various urban services. The task recommendation platform that we design can match tasks to crowdworkers based on workers’ historical trajectories and time budget limits, thus making recommendations personal and eff...

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Main Authors: CHENG, Shih-Fen, CHEN, Cen, KANDAPPU, Thivya, LAU, Hoong Chuin, MISRA, Archan, JAIMAN, Nikita, DARATAN, Randy Tandriansyah, KOH, Desmond
Format: text
Language:English
Published: Institutional Knowledge at Singapore Management University 2018
Subjects:
participatory sensing
Mobile crowdsourcing
uncertainty modeling
context-aware
empirical study
spatial crowdsourcing
user behavior
Artificial Intelligence and Robotics
Computer Sciences
Operations Research, Systems Engineering and Industrial Engineering
Online Access:https://ink.library.smu.edu.sg/sis_research/3888
https://ink.library.smu.edu.sg/context/sis_research/article/4890/viewcontent/ScalableUrbanMobileCrowd__tist_final_web.pdf
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Institution: Singapore Management University
Language: English
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spelling sg-smu-ink.sis_research-48902021-03-26T04:57:28Z Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement CHENG, Shih-Fen CHEN, Cen KANDAPPU, Thivya LAU, Hoong Chuin MISRA, Archan JAIMAN, Nikita DARATAN, Randy Tandriansyah KOH, Desmond In this article, we investigate effective ways of utilizing crowdworkers in providing various urban services. The task recommendation platform that we design can match tasks to crowdworkers based on workers’ historical trajectories and time budget limits, thus making recommendations personal and efficient. One major challenge we manage to address is the handling of crowdworker’s trajectory uncertainties. In this article, we explicitly allow multiple routine routes to be probabilistically associated with each worker. We formulate this problem as an integer linear program whose goal is to maximize the expected total utility achieved by all workers. We further exploit the separable structures of the formulation and apply the Lagrangian relaxation technique to scale up computation. Numerical experiments have been performed over the instances generated using the realistic public transit dataset in Singapore. The results show that we can find significantly better solutions than the deterministic formulation, and in most cases we can find solutions that are very close to the theoretical performance limit. To demonstrate the practicality of our approach, we deployed our recommendation engine to a campus-scale field trial, and we demonstrate that workers receiving our recommendations incur fewer detours and complete more tasks, and are more efficient against workers relying on their own planning (25% more for top workers who receive recommendations). This is achieved despite having highly uncertain worker trajectories. We also demonstrate how to further improve the robustness of the system by using a simple multi-coverage mechanism. 2018-02-01T08:00:00Z text application/pdf https://ink.library.smu.edu.sg/sis_research/3888 info:doi/10.1145/3078842 https://ink.library.smu.edu.sg/context/sis_research/article/4890/viewcontent/ScalableUrbanMobileCrowd__tist_final_web.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 participatory sensing Mobile crowdsourcing uncertainty modeling context-aware empirical study spatial crowdsourcing user behavior Artificial Intelligence and Robotics Computer Sciences Operations Research, Systems Engineering and Industrial Engineering
institution Singapore Management University
building SMU Libraries
continent Asia
country Singapore
Singapore
content_provider SMU Libraries
collection InK@SMU
language English
topic participatory sensing
Mobile crowdsourcing
uncertainty modeling
context-aware
empirical study
spatial crowdsourcing
user behavior
Artificial Intelligence and Robotics
Computer Sciences
Operations Research, Systems Engineering and Industrial Engineering
spellingShingle participatory sensing
Mobile crowdsourcing
uncertainty modeling
context-aware
empirical study
spatial crowdsourcing
user behavior
Artificial Intelligence and Robotics
Computer Sciences
Operations Research, Systems Engineering and Industrial Engineering
CHENG, Shih-Fen
CHEN, Cen
KANDAPPU, Thivya
LAU, Hoong Chuin
MISRA, Archan
JAIMAN, Nikita
DARATAN, Randy Tandriansyah
KOH, Desmond
Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement
description In this article, we investigate effective ways of utilizing crowdworkers in providing various urban services. The task recommendation platform that we design can match tasks to crowdworkers based on workers’ historical trajectories and time budget limits, thus making recommendations personal and efficient. One major challenge we manage to address is the handling of crowdworker’s trajectory uncertainties. In this article, we explicitly allow multiple routine routes to be probabilistically associated with each worker. We formulate this problem as an integer linear program whose goal is to maximize the expected total utility achieved by all workers. We further exploit the separable structures of the formulation and apply the Lagrangian relaxation technique to scale up computation. Numerical experiments have been performed over the instances generated using the realistic public transit dataset in Singapore. The results show that we can find significantly better solutions than the deterministic formulation, and in most cases we can find solutions that are very close to the theoretical performance limit. To demonstrate the practicality of our approach, we deployed our recommendation engine to a campus-scale field trial, and we demonstrate that workers receiving our recommendations incur fewer detours and complete more tasks, and are more efficient against workers relying on their own planning (25% more for top workers who receive recommendations). This is achieved despite having highly uncertain worker trajectories. We also demonstrate how to further improve the robustness of the system by using a simple multi-coverage mechanism.
format text
author CHENG, Shih-Fen
CHEN, Cen
KANDAPPU, Thivya
LAU, Hoong Chuin
MISRA, Archan
JAIMAN, Nikita
DARATAN, Randy Tandriansyah
KOH, Desmond
author_facet CHENG, Shih-Fen
CHEN, Cen
KANDAPPU, Thivya
LAU, Hoong Chuin
MISRA, Archan
JAIMAN, Nikita
DARATAN, Randy Tandriansyah
KOH, Desmond
author_sort CHENG, Shih-Fen
title Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement
title_short Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement
title_full Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement
title_fullStr Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement
title_full_unstemmed Scalable urban mobile crowdsourcing: Handling uncertainty in worker movement
title_sort scalable urban mobile crowdsourcing: handling uncertainty in worker movement
publisher Institutional Knowledge at Singapore Management University
publishDate 2018
url https://ink.library.smu.edu.sg/sis_research/3888
https://ink.library.smu.edu.sg/context/sis_research/article/4890/viewcontent/ScalableUrbanMobileCrowd__tist_final_web.pdf
_version_ 1770573872557457408

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