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引用次数: 0
摘要
将深度神经网络(DNN)集成到嵌入式系统中进行实时图像和视频处理,推动了嵌入式人工智能的快速发展,而 AMD Xilinx Vitis AI on the MPSoC-FPGA 平台等人工智能专用平台则显著推动了这一发展。该平台利用可配置的深度处理单元(DPU)实现可扩展的资源利用率和工作频率。我们的研究采用了详细的方法来评估各种 DPU 配置和频率对资源利用率和能耗的影响。研究结果表明,提高 DPU 频率可提高资源利用效率并改善性能。相反,频率越低,资源利用率越低,而性能仅有微弱的下降。这些权衡不仅受到频率的影响,还受到 DPU 参数变化的影响。这些发现对于在高级驾驶辅助系统(ADAS)中开发基于实时视频处理的高能效人工智能驱动系统至关重要。通过利用部署在 Kria KV260 MPSoC 平台上的赛灵思 Vitis AI 的功能,我们探索了在实时 ADAS 应用中通过多任务学习优化能效的复杂性。
Energy efficiency assessment in advanced driver assistance systems with real-time image processing on custom Xilinx DPUs
The rapid advancement in embedded AI, driven by integrating deep neural networks (DNNs) into embedded systems for real-time image and video processing, has been notably pushed by AI-specific platforms like the AMD Xilinx Vitis AI on the MPSoC-FPGA platform. This platform utilizes a configurable Deep Processing Unit (DPU) for scalable resource utilization and operating frequencies. Our study employed a detailed methodology to assess the impact of various DPU configurations and frequencies on resource utilization and energy consumption. The findings reveal that increasing the DPU frequency enhances resource utilization efficiency and improves performance. Conversely, lower frequencies significantly reduce resource utilization, with only a borderline decrease in performance. These trade-offs are influenced not only by frequency but also by variations in DPU parameters. These findings are critical for developing energy-efficient AI-driven systems in Advanced Driver Assistance Systems (ADAS) based on real-time video processing. By leveraging the capabilities of Xilinx Vitis AI deployed on the Kria KV260 MPSoC platform, we explore the intricacies of optimizing energy efficiency through multi-task learning in real-time ADAS applications.
期刊介绍:
Due to rapid advancements in integrated circuit technology, the rich theoretical results that have been developed by the image and video processing research community are now being increasingly applied in practical systems to solve real-world image and video processing problems. Such systems involve constraints placed not only on their size, cost, and power consumption, but also on the timeliness of the image data processed.
Examples of such systems are mobile phones, digital still/video/cell-phone cameras, portable media players, personal digital assistants, high-definition television, video surveillance systems, industrial visual inspection systems, medical imaging devices, vision-guided autonomous robots, spectral imaging systems, and many other real-time embedded systems. In these real-time systems, strict timing requirements demand that results are available within a certain interval of time as imposed by the application.
It is often the case that an image processing algorithm is developed and proven theoretically sound, presumably with a specific application in mind, but its practical applications and the detailed steps, methodology, and trade-off analysis required to achieve its real-time performance are not fully explored, leaving these critical and usually non-trivial issues for those wishing to employ the algorithm in a real-time system.
The Journal of Real-Time Image Processing is intended to bridge the gap between the theory and practice of image processing, serving the greater community of researchers, practicing engineers, and industrial professionals who deal with designing, implementing or utilizing image processing systems which must satisfy real-time design constraints.
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