A Novel Video Coding Framework with Tensor Representation for Efficient Video Streaming

Video compression is one among the pre-processes in video streaming. While capturing moving objects with moving cameras, more amount of redundant data is recorded along with dynamic change. In this paper, this change is identified using various geometric transformations. To register all these dynamic relations with minimal storage, tensor representation is used. The amount of similarity between the frames is measured using canonical correlation analysis (CCA). The key frames are identified by comparing the canonical auto-correlation analysis score of the candidate key frame with CCA score of other frames. In this method, coded video is represented using tensor which consists of intra-coded key frame, a vector of P frame identifiers, transformation of each variable sized block and information fusion that has three levels of abstractions: measurements, characteristics and decisions that combine all these factors into a single entity. Each dimension can have variable sizes which facilitates storing all characteristics without missing any information. In this paper, the proposed video compression method is applied to under-water videos that have more redundancy as both the camera and the underwater species are in motion. This method is compared with H.264, H.265 and some recent compression methods. Metrics like Peak Signal to Noise Ratio and compression ratio for various bit rates are used to evaluate the performance. From the results obtained, it is obvious that the proposed method performs compression with a high compression ratio, and the loss is comparatively less.