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Main Authors: Tong, Jianming, Xiao, Hanshen, Nair, Krishna Kumar, Kang, Hao, Sirasao, Ashish, Zhang, Ziqi, Suh, G. Edward, Krishna, Tushar
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.17476
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author Tong, Jianming
Xiao, Hanshen
Nair, Krishna Kumar
Kang, Hao
Sirasao, Ashish
Zhang, Ziqi
Suh, G. Edward
Krishna, Tushar
author_facet Tong, Jianming
Xiao, Hanshen
Nair, Krishna Kumar
Kang, Hao
Sirasao, Ashish
Zhang, Ziqi
Suh, G. Edward
Krishna, Tushar
contents Multi-user virtual reality enables immersive interaction. However, rendering avatars for numerous participants on each headset incurs prohibitive computational overhead, limiting scalability. We introduce a framework, Privatar, to offload avatar reconstruction from headset to untrusted devices within the same local network while safeguarding attacks against adversaries capable of intercepting offloaded data. Privatar's key insight is that domain-specific knowledge of avatar reconstruction enables provably private offloading at minimal cost. (1) System level. We observe avatar reconstruction is frequency-domain decomposable via BDCT with negligible quality drop, and propose Horizontal Partitioning (HP) to keep high-energy frequency components on-device and offloads only low-energy components. HP offloads local computation while reducing information leakage to low-energy subsets only. (2) Privacy level. For individually offloaded, multi-dimensional signals without aggregation, worst-case local Differential Privacy requires prohibitive noise, ruining utility. We observe users' expression statistical distribution are slowly changing over time and trackable online, and hence propose Distribution-Aware Minimal Perturbation. DAMP minimizes noise based on each user's expression distribution to significantly reduce its effects on utility, retaining formal privacy guarantee. Combined, HP provides empirical privacy against expression identification attacks. DAMP further augments it to offer a formal guarantee against arbitrary adversaries. On a Meta Quest Pro, Privatar supports 2.37x more concurrent users at 6.5% higher reconstruction loss and 9% energy overhead, providing a better throughout-loss Pareto frontier over quantization, sparsity and local construction baselines. Privatar provides both provable privacy guarantee and stays robust against both empirical and NN-based attacks.
format Preprint
id arxiv_https___arxiv_org_abs_2604_17476
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Privatar: Scalable Privacy-preserving Multi-user VR via Secure Offloading
Tong, Jianming
Xiao, Hanshen
Nair, Krishna Kumar
Kang, Hao
Sirasao, Ashish
Zhang, Ziqi
Suh, G. Edward
Krishna, Tushar
Cryptography and Security
Hardware Architecture
Computer Vision and Pattern Recognition
Systems and Control
Multi-user virtual reality enables immersive interaction. However, rendering avatars for numerous participants on each headset incurs prohibitive computational overhead, limiting scalability. We introduce a framework, Privatar, to offload avatar reconstruction from headset to untrusted devices within the same local network while safeguarding attacks against adversaries capable of intercepting offloaded data. Privatar's key insight is that domain-specific knowledge of avatar reconstruction enables provably private offloading at minimal cost. (1) System level. We observe avatar reconstruction is frequency-domain decomposable via BDCT with negligible quality drop, and propose Horizontal Partitioning (HP) to keep high-energy frequency components on-device and offloads only low-energy components. HP offloads local computation while reducing information leakage to low-energy subsets only. (2) Privacy level. For individually offloaded, multi-dimensional signals without aggregation, worst-case local Differential Privacy requires prohibitive noise, ruining utility. We observe users' expression statistical distribution are slowly changing over time and trackable online, and hence propose Distribution-Aware Minimal Perturbation. DAMP minimizes noise based on each user's expression distribution to significantly reduce its effects on utility, retaining formal privacy guarantee. Combined, HP provides empirical privacy against expression identification attacks. DAMP further augments it to offer a formal guarantee against arbitrary adversaries. On a Meta Quest Pro, Privatar supports 2.37x more concurrent users at 6.5% higher reconstruction loss and 9% energy overhead, providing a better throughout-loss Pareto frontier over quantization, sparsity and local construction baselines. Privatar provides both provable privacy guarantee and stays robust against both empirical and NN-based attacks.
title Privatar: Scalable Privacy-preserving Multi-user VR via Secure Offloading
topic Cryptography and Security
Hardware Architecture
Computer Vision and Pattern Recognition
Systems and Control
url https://arxiv.org/abs/2604.17476