XR Offloading Across Multiple Time Scales: The Roles of Power, Temperature, and Energy
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Extended reality (XR) devices, commonly known as wearables, must handle significant computational loads under tight latency constraints. To meet these demands, they rely on a combination of on-device processing and edge offloading. This letter focuses on offloading strategies for wearables by considering their impact across three time scales: instantaneous power consumption, short-term temperature fluctuations, and long-term battery duration. We introduce a comprehensive system model that captures these temporal dynamics, and propose a stochastic and stationary offloading strategy, called TAO (for temperature-aware offloading), designed to minimize the offloading cost while adhering to power, thermal, and energy constraints. Our performance evaluation, leveraging COMSOL models of real-world wearables, confirms that TAO reduces offloading cost by over 35% compared to state-of-the-art approaches, without violating the wearable operational limits.
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Dynamic XR Rendering Offloading Based on Feature-Based Quality Assessment
The paper presents an edge-aided XR testbed with dynamic offloading, a deep feature-based perceptual quality metric robust to misalignments, and a contextual bandit controller for real-time rendering decisions.
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