Classically, error-correcting codes are studied with respect to performance metrics such as minimum distance (combinatorial) or probability of bit/block error over a given stochastic channel. In this paper, a different metric is considered. It is assumed that the block code is used to repeatedly encode user data. The resulting stream is subject to adversarial noise of given power, and the decoder is required to reproduce the data with minimal possible bit-error rate. This setup may be viewed as a combinatorial joint source-channel coding. Two basic results are shown for the achievable noise-distortion tradeoff: the optimal performance for decoders that are informed of the noise power, and global bounds for decoders operating in complete obl...
In this paper, the bit error probability P(sub b) for maximum likelihood decoding of binary linear c...
In the random deletion channel, each bit is deleted independently with probability p. For the random...
Let C = {x_1,...,x_N} ⊂ {0, 1}^n be an [n, N] binary error correcting code (not necessarily linear)....
This paper continues the investigation of the combinatorial formulation of the joint source-channel ...
We consider coding schemes for computationally bounded channels, which can introduce an arbitrary se...
This thesis is a study of error-correcting codes for reliable communication in the presence of extre...
By using coding and combinatorial techniques, an approximate formula for the weight distribution of ...
Let the input to a computation problem be split between two processors connected by a communication ...
Cover title.Includes bibliographical references (p. 49-51).Supported in part by the Advanced Concept...
We consider coding schemes for computationally bounded channels, which can introduce an arbitrary se...
In this paper, we consider coding schemes for computationally bounded channels, which can introduce ...
New lower bounds are presented for the minimum error probability that can be achieved through the us...
Maximum likelihood decoding of long block codes is not feasable due to large complexity. Some classe...
We introduce a new algorithm for Maximum Likelihood (ML) decoding for channels with memory. The algo...
Upper bounds On the decoder error probability for Reed-Solomon codes are derived. By definition, "de...
In this paper, the bit error probability P(sub b) for maximum likelihood decoding of binary linear c...
In the random deletion channel, each bit is deleted independently with probability p. For the random...
Let C = {x_1,...,x_N} ⊂ {0, 1}^n be an [n, N] binary error correcting code (not necessarily linear)....
This paper continues the investigation of the combinatorial formulation of the joint source-channel ...
We consider coding schemes for computationally bounded channels, which can introduce an arbitrary se...
This thesis is a study of error-correcting codes for reliable communication in the presence of extre...
By using coding and combinatorial techniques, an approximate formula for the weight distribution of ...
Let the input to a computation problem be split between two processors connected by a communication ...
Cover title.Includes bibliographical references (p. 49-51).Supported in part by the Advanced Concept...
We consider coding schemes for computationally bounded channels, which can introduce an arbitrary se...
In this paper, we consider coding schemes for computationally bounded channels, which can introduce ...
New lower bounds are presented for the minimum error probability that can be achieved through the us...
Maximum likelihood decoding of long block codes is not feasable due to large complexity. Some classe...
We introduce a new algorithm for Maximum Likelihood (ML) decoding for channels with memory. The algo...
Upper bounds On the decoder error probability for Reed-Solomon codes are derived. By definition, "de...
In this paper, the bit error probability P(sub b) for maximum likelihood decoding of binary linear c...
In the random deletion channel, each bit is deleted independently with probability p. For the random...
Let C = {x_1,...,x_N} ⊂ {0, 1}^n be an [n, N] binary error correcting code (not necessarily linear)....