Fully Linear Multimedia Multicast Method Without Error Correction Protection
A multimedia data and data technology, applied in wireless communication, broadcast service distribution, network traffic/resource management, etc., can solve problems such as image quality degradation, metadata transmission occupying bandwidth, and digital sidewalk computing overhead
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Embodiment 1
[0098] This embodiment provides a processing flow of a fully linear non-error-correction-protected multimedia data multicast method as follows: figure 1 As shown, the following processing steps are included:
[0099] Step 1. Separate each frame of multimedia data to be transmitted independently, and then split each frame of image into a large block X of MN×MN.
[0100] Step 2, large block X translation of each frame image 2 b-1 , where b is the image sampling depth, and then the large block after translation is subjected to the whole frame decorrelation transformation:
[0101] y=Tr(x-2 b-1 )
[0102] Y is the large block after the decorrelation transformation, Tr is the decorrelation transformation, and x is the pixel matrix of the large block.
[0103] The above decorrelation transformation can concentrate a large amount of energy (or information) of the image in a small area, and the decorrelation transformation can use K-L transformation, DCT transformation, DST transf...
Embodiment 2
[0169] FPGA (Field-Programmable Gate Array, Field Programmable Gate Array) + DSP (digital signal processing, digital signal processing) implementation method: Due to the need for real-time video encoding and decoding (especially the receiving and decoding part), the FPGA+DSP implementation method becomes very necessary. The implementation of this scheme is divided into two parts: encoding, transmitting and receiving and decoding. The system block diagram is shown in the appendix Figure 8 , respectively implemented on two Xilinx KC705FPGA development boards.
[0170] In this implementation scheme, the maximum module size is , and MN=1024 at the same time. The communication system adopts the OFDM system. The energy parameter P is determined with reference to the frame structure and the rated transmission power. The random sorting can be customized by using seeds. The decorrelation transformation is 2D-DCT transformation. The number of small blocks is N=1024. Data aggregation c...
Embodiment 3
[0197] 2): Implementation of software radio:
[0198] In this implementation scheme, the maximum module size is , and MN=1024 at the same time. The communication system adopts the OFDM system. The energy parameter P is determined with reference to the frame structure and the rated transmission power. The random sorting can be customized by using seeds. The decorrelation transformation is 2D-DCT transformation. The number of small blocks is N=1024. Data aggregation calculation is in progress M=20, the whitening transformation adopts the Walsh-Hadamard transformation, and the revised model parameters are as follows C1=1, C2=0.9, C3=0.8, C4=10, C5=1.36, C6=31.2, C6=0.115, C7=4.66, MCHUNK=1024, NUM=900. The system block diagram is attached image 3 , the specific implementation plan is as follows:
[0199] Source channel coding and decoding is completed on the PC by software Matlab, and high-speed digital signal processing and RF transmission and reception are completed on the ...
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