TY - JOUR
T1 - BlockSC
T2 - A Blockchain Empowered Spatial Crowdsourcing Service in Metaverse while Preserving User Location Privacy
AU - Liu, Yuan
AU - Zhang, Yanan
AU - Su, Shen
AU - Zhang, Lejun
AU - Du, Xiaojiang
AU - Guizani, Mohsen
AU - Tian, Zhihong
N1 - Publisher Copyright:
© 1983-2012 IEEE.
PY - 2024/4/1
Y1 - 2024/4/1
N2 - Spatial crowdsourcing (SC) has become a fundamental and emerging technology in Metaverse, facilitating the creation of immersive experiences through location-based services. In these systems, a central SC server leverages SC workers who physically travel to task locations to gather spatiotemporal environment data. However, conventional SC systems face two significant challenges: (1) the SC server, functioning as a centralized authority, can sometimes be unreliable, either due to intentional or unintentional misconduct, (2) to ensure efficient task assignment and validation, the location privacy of tasks and workers is openly accessible. In this study, we formally define location privacy preserved proof generation and verification problem (LP-PGVP) within an SC task matching scenario, with the aim to the above two challenges. Our proposed solution is a blockchain-based SC system (BlockSC), which provides a decentralized platform for task requesters and workers in the Metaverse context through calling smart contracts. We also introduce a ciphertext-based task matching scheme where task location access is granted only to eligible workers executing a task, benefiting from the design of geographic coordinate transformation and bilinear mapping methodology. To further demonstrate the task matching scheme's operation and impact, we present an easy-to-understand case study. Our evaluation findings confirm that the proposed system effectively maintains location privacy for both SC workers and task requesters, without a considerable sacrifice in task matching efficiency.
AB - Spatial crowdsourcing (SC) has become a fundamental and emerging technology in Metaverse, facilitating the creation of immersive experiences through location-based services. In these systems, a central SC server leverages SC workers who physically travel to task locations to gather spatiotemporal environment data. However, conventional SC systems face two significant challenges: (1) the SC server, functioning as a centralized authority, can sometimes be unreliable, either due to intentional or unintentional misconduct, (2) to ensure efficient task assignment and validation, the location privacy of tasks and workers is openly accessible. In this study, we formally define location privacy preserved proof generation and verification problem (LP-PGVP) within an SC task matching scenario, with the aim to the above two challenges. Our proposed solution is a blockchain-based SC system (BlockSC), which provides a decentralized platform for task requesters and workers in the Metaverse context through calling smart contracts. We also introduce a ciphertext-based task matching scheme where task location access is granted only to eligible workers executing a task, benefiting from the design of geographic coordinate transformation and bilinear mapping methodology. To further demonstrate the task matching scheme's operation and impact, we present an easy-to-understand case study. Our evaluation findings confirm that the proposed system effectively maintains location privacy for both SC workers and task requesters, without a considerable sacrifice in task matching efficiency.
KW - blockchain
KW - Location based service
KW - location privacy
KW - metaverse
KW - task assignment
UR - http://www.scopus.com/inward/record.url?scp=85182384357&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85182384357&partnerID=8YFLogxK
U2 - 10.1109/JSAC.2023.3345416
DO - 10.1109/JSAC.2023.3345416
M3 - Article
AN - SCOPUS:85182384357
SN - 0733-8716
VL - 42
SP - 880
EP - 892
JO - IEEE Journal on Selected Areas in Communications
JF - IEEE Journal on Selected Areas in Communications
IS - 4
ER -