Add to ORKGThe reversible variable length code (RVLC) has been proposed as one of the error resilience tools owing to recovery capability for corrupted video streams. Although the asymmetrical RVLC re-quires separate two code tables, it shows better coding efficiency due to more flexible codeword assignment. Still, existing design methods for asymmetrical RVLCs are inefficient. In this paper, we propose a new design algorithm for the asymmetrical RVLC using the property of the Huffman code and the average length function. In addition, comparing the robustness of RVLCs shows that pro-posed efficient asymmetrical RVLC does not lose error-correcting property significantly. 1
This paper is concerned with error correcting codes for asymmetric memories or channels. An asymmetr...
This contribution investigates error resilience properties of two codes, UVLC and VLCD. UVLC has bee...
In this paper we demonstrate that our ability to match the EXtrinsic Information Transfer (EXIT) fun...
[[abstract]]Variable length codes (VLCs) are widely adopted in many compression standards due to the...
Reversible variable length coding (RVLC) is a state-of-the-art entropy encoding scheme. These codes ...
We propose a generic algorithm for the construction of efficient reversible variable-length codes (R...
Maxted et al. in 1985 gave a conjecture stating that, for a Geometric source, the stable code has th...
Huffman codes used in JPEG coding are replaced with reversible variable-length codes (RVLCs) with la...
Variable-length codes (e.g., Huffman codes) are commonly employed to minimize the average codeword l...
International audienceThis paper addresses the issue of robust and progressive transmission of signa...
this paper addresses the issue of robust transmission of sources encoded with Variable Length Codes ...
The error recovery capability of variable length code (VLC) has been considered as an important perf...
Resynchronizing variable-length codes (RVLCs) for large alphabets are designed by first creating res...
Variable length codes (VLCs), used in data compression, are very sensitive to error propagation in t...
Abstract: Huffman codes used in JPEG cod-ing are replaced with reversible variable-length codes (RVL...
This paper is concerned with error correcting codes for asymmetric memories or channels. An asymmetr...
This contribution investigates error resilience properties of two codes, UVLC and VLCD. UVLC has bee...
In this paper we demonstrate that our ability to match the EXtrinsic Information Transfer (EXIT) fun...
[[abstract]]Variable length codes (VLCs) are widely adopted in many compression standards due to the...
Reversible variable length coding (RVLC) is a state-of-the-art entropy encoding scheme. These codes ...
We propose a generic algorithm for the construction of efficient reversible variable-length codes (R...
Maxted et al. in 1985 gave a conjecture stating that, for a Geometric source, the stable code has th...
Huffman codes used in JPEG coding are replaced with reversible variable-length codes (RVLCs) with la...
Variable-length codes (e.g., Huffman codes) are commonly employed to minimize the average codeword l...
International audienceThis paper addresses the issue of robust and progressive transmission of signa...
this paper addresses the issue of robust transmission of sources encoded with Variable Length Codes ...
The error recovery capability of variable length code (VLC) has been considered as an important perf...
Resynchronizing variable-length codes (RVLCs) for large alphabets are designed by first creating res...
Variable length codes (VLCs), used in data compression, are very sensitive to error propagation in t...
Abstract: Huffman codes used in JPEG cod-ing are replaced with reversible variable-length codes (RVL...
This paper is concerned with error correcting codes for asymmetric memories or channels. An asymmetr...
This contribution investigates error resilience properties of two codes, UVLC and VLCD. UVLC has bee...
In this paper we demonstrate that our ability to match the EXtrinsic Information Transfer (EXIT) fun...