Quality Aware MPEG-2 Stream Adaptation in Resource Constrained Systems
ECRTS '04 Proceedings of the 16th Euromicro Conference on Real-Time Systems
Principles for the Prediction of Video Decoding Times Applied to MPEG-1/2 and MPEG-4 Part 2 Video
RTSS '06 Proceedings of the 27th IEEE International Real-Time Systems Symposium
Proceedings of the 15th international conference on Multimedia
A framework for end-to-end video quality prediction of MPEG video
Journal of Visual Communication and Image Representation
Quality-aware media scheduling on MPSoC platforms
Proceedings of the Conference on Design, Automation and Test in Europe
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Multimedia decoders mapped onto MPSoC platforms exhibit degraded video quality when the critical system resources such as buffer and processor frequency are constrained. Hence, it is essential for system designers to find the appropriate mix of resources, living within the constraints, for a desired output video quality. A naive approach to do this would be to run expensive system simulations of the decoder tasks mapped onto a model of the underlying MPSoC architecture. This turns out to be inefficient when the input video library set has a large number of video clips. We propose a fast hybrid simulation framework to quantitatively estimate decoded video quality in the context of an MPEG-2 decoder. Here, the workload of simulation heavy tasks are estimated using accurate analytical models. The workload of other light (but difficult to analytically model) tasks are obtained from system simulations. This framework enables the system designer to perform a fast trade-off analysis of the system resources in order to choose the optimal combination of resources for the desired video quality. When compared to a naive system simulation approach, the hybrid simulation-based framework shows speed-up factors of about 5x for motion and 8x for still videos. The results obtained using this framework highlight important trade-offs such as the decoded video quality (measured in terms of the peak signal to noise ratio (PSNR)) vs buffer size and PSNR vs processor frequency.