Title :
Dependent source and channel rate allocation for video transmission
Author :
Bystrom, Maja ; Stockhammer, Thomas
Author_Institution :
Dept. of Electr. & Comput. Eng., Boston Univ., MA, USA
Abstract :
A general joint source-channel rate allocation scheme for a dependent video coding environment is presented. It is assumed that the source coders rely on motion-compensated prediction, and thus error propagation will contribute significantly to the degradation of the reconstructed video. The rate allocation methodology is based upon generation of operational distortion-rate characteristics. In order to reduce computational complexity, these surfaces and the channel code performance are modeled. An analytic method for computing optimal rate allocation across frames in a video sequence is then introduced. Comparisons are made between equal error protection and unequal error protection over video frames. Results are shown for H.263 compressed video used in conjunction with rate-compatible punctured convolutional codes.
Keywords :
AWGN; coding errors; combined source-channel coding; computational complexity; convolutional codes; error statistics; phase shift keying; sequences; video coding; AWGN; BER; BPSK; H.263 compressed video; Susie video sequence; additive white Gaussian noise; bit error rate; channel code; computational complexity; dependent transmission; dependent video coding; distortion-rate characteristics; equal error protection; error propagation; joint source-channel rate allocation scheme; motion-compensated prediction; phase shift keying; rate-compatible punctured systematic recursive convolutional codes; reconstructed video; source coders; unequal error protection; video frames; video transmission; AWGN; Channel coding; Convolutional codes; Error correction codes; Fading; Modulation coding; Pulse modulation; Source coding; Vector quantization; Video compression;
Journal_Title :
Wireless Communications, IEEE Transactions on
DOI :
10.1109/TWC.2003.821150
