Error Exponents for Variable-length Block Codes with Feedback and Cost Constraints
Abstract
Variable-length block-coding schemes are investigated for discrete memoryless channels with ideal feedback under cost constraints. Upper and lower bounds are found for the minimum achievable probability of decoding error Pe, as a function of constraints R, , and τ on the transmission rate, average cost, and average block length respectively. For given R and , the lower and upper bounds to the exponent -( Pe,)/ τ are asymptotically equal as τ ∞. The resulting reliability function, τ ∞ (- Pe,)/ τ, as a function of R and , is concave in the pair (R, ) and generalizes the linear reliability function of Burnashev to include cost constraints. The results are generalized to a class of discrete-time memoryless channels with arbitrary alphabets, including additive Gaussian noise channels with amplitude and power constraints.
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