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The increasing deployment of deep neural networks (DNNs) in cyber-physical systems (CPS) enhances perception fidelity, but imposes substantial computational demands on execution platforms, posing challenges to real-time control deadlines. Traditional distributed CPS architectures typically favor on-device inference to avoid network variability and contention-induced delays on remote platforms. However, this design choice places significant energy and computational demands on the local hardware. In this work, we revisit the assumption that cloud-based inference is intrinsically unsuitable for latency-sensitive control tasks. We demonstrate that, when provisioned with high-throughput compute resources, cloud platforms can effectively amortize network and queueing delays, enabling them to match or surpass on-device performance for real-time decision-making. Specifically, we develop a formal analytical model that characterizes distributed inference latency as a function of the sensing frequency, platform throughput, network delay, and task-specific safety constraints. We instantiate this model in the context of emergency braking for autonomous driving and validate it through extensive simulations using real-time vehicular dynamics. Our empirical results identify concrete conditions under which cloud-based inference adheres to safety margins more reliably than its on-device counterpart. These findings challenge prevailing design strategies and suggest that the cloud is not merely a feasible option, but often the preferred inference location for distributed CPS architectures. In this light, the cloud is not as distant as traditionally perceived; in fact, it is closer than it appears. 

Interest in cooperative perception is growing quickly due to its remarkable performance in improving perception capabilities for connected and automated vehicles. This improvement is crucial, especially for automated driving scenarios in which perception performance is one of the main bottlenecks to the development of safety and efficiency. However, current cooperative perception methods typically assume that all collaborating vehicles have enough communication bandwidth to share all features with an identical spatial size, which is impractical for real-world scenarios. In this paper, we propose Adaptive Cooperative Perception, a new cooperative perception framework that is not limited by the aforementioned assumptions, aiming to enable cooperative perception under more realistic and challenging conditions. To support this, a novel feature encoder is proposed and named Pillar Attention Encoder. A pillar attention mechanism is designed to extract the feature data while considering its significance for the perception task. An adaptive feature filter is proposed to adjust the size of the feature data for sharing by considering the importance value of the feature. Experiments are conducted for cooperative object detection from multiple vehicle-based and infrastructure-based LiDAR sensors under various communication conditions. Results demonstrate that our method can successfully handle dynamic communication conditions and improve the mean Average Precision by 10.18% when compared with the state-of-the-art feature encoder.