Random Access Channel Coding in the Finite Blocklength Regime

Abstract: Consider a random access communication scenario over a channel whose operation is defined for any number of possible transmitters. As in the model recently introduced by Polyanskiy for the Multiple Access Channel (MAC) with a fixed, known number of transmitters, the channel is assumed to be invariant to permutations on its inputs, and all active transmitters employ identical encoders. Unlike the Polyanskiy model, in the proposed scenario, neither the transmitters nor the receiver knows which transmitters are a… Show more

“…In this section, we show that the error value N chosen in (123) is second-order optimal in the sense that under the VLSF code design in Section IV-D, the error value * N that minimizes the average decoding time in (126) has the same asymptotic expansion (19) of the maximum achievable message size as N up to the second-order term.…”

“…Random variable U is common randomness shared by the transmitter and receiver. As in [6], [13], [19], the traditional 2 The realization u of U specifies the codebook. random-coding argument does not prove the existence of a single (deterministic) code that simultaneously satisfies two conditions on the code (e.g., ( 9) and ( 10)).…”

“…are shown for K = 1 (14) and K ∈ {2, 3, 4} (Theorem 1), P = 1 and = 10 −3 . The achievability bounds use the asymptotic approximation, i.e., we ignore the O(•) term in (19).…”

“…When K < ∞ and the probability P [ı(X n K ; Y n K ) < γ] dominates, using i.i.d. N (0, P ) inputs achieves a worse second-order term in the asymptotic expansion (19) of the maximum achievable message size. This implies that when K < ∞, using our uniform distribution on a subset of the power sphere is superior to choosing codewords i.i.d.…”

“…In particular, i.i.d. N (0, P ) inputs achieve (19), where the dispersion V (P ) is replaced by the variancẽ V (P ) = P 1+P of ı(X; Y ) when X ∼ N (0, P ); hereṼ (P ) is greater than the dispersion V (P ) for all P > 0 (see [25, eq. (2.56)]).…”

Variable-length Feedback Codes with Several Decoding Times for the Gaussian Channel

“…In this section, we show that the error value N chosen in (123) is second-order optimal in the sense that under the VLSF code design in Section IV-D, the error value * N that minimizes the average decoding time in (126) has the same asymptotic expansion (19) of the maximum achievable message size as N up to the second-order term.…”

“…Random variable U is common randomness shared by the transmitter and receiver. As in [6], [13], [19], the traditional 2 The realization u of U specifies the codebook. random-coding argument does not prove the existence of a single (deterministic) code that simultaneously satisfies two conditions on the code (e.g., ( 9) and ( 10)).…”

“…are shown for K = 1 (14) and K ∈ {2, 3, 4} (Theorem 1), P = 1 and = 10 −3 . The achievability bounds use the asymptotic approximation, i.e., we ignore the O(•) term in (19).…”

“…When K < ∞ and the probability P [ı(X n K ; Y n K ) < γ] dominates, using i.i.d. N (0, P ) inputs achieves a worse second-order term in the asymptotic expansion (19) of the maximum achievable message size. This implies that when K < ∞, using our uniform distribution on a subset of the power sphere is superior to choosing codewords i.i.d.…”

“…In particular, i.i.d. N (0, P ) inputs achieve (19), where the dispersion V (P ) is replaced by the variancẽ V (P ) = P 1+P of ı(X; Y ) when X ∼ N (0, P ); hereṼ (P ) is greater than the dispersion V (P ) for all P > 0 (see [25, eq. (2.56)]).…”

Variable-length Feedback Codes with Several Decoding Times for the Gaussian Channel

Achievable Second-Order Asymptotics for Additive Non-Gaussian MAC and RAC

Every Bit Counts: Second-Order Analysis of Cooperation in the Multiple-Access Channel