Abstract
In this paper, we derive lower and upper bounds on the OPTA of a two-user multi-input multi-output (MIMO) causal encoding and causal decoding problem. Each user’s source model is described by a multidimensional Markov source driven by additive noise process subject to three classes of spatio-temporal distortion constraints. To characterize the lower bounds, we use state augmentation techniques and a data processing theorem, which recovers a variant of rate distortion function as an information measure known in the literature as nonanticipatory -entropy, sequential or nonanticipative RDF. We derive lower bound characterizations for a system driven by an Gaussian noise process, which we solve using the SDP algorithm for all three classes of distortion constraints. We obtain closed form solutions when the system’s noise is possibly non-Gaussian for both users and when only one of the users is described by a source model driven by a Gaussian noise process. To obtain the upper bounds, we use the best linear forward test channel realization that corresponds to the optimal test channel realization when the system is driven by a Gaussian noise process and apply a sequential causal DPCM-based scheme with a feedback loop followed by a scaled ECDQ scheme that leads to upper bounds with certain performance guarantees. Then, we use the linear forward test channel as a benchmark to obtain upper bounds on the OPTA, when the system is driven by an additive non-Gaussian noise process. We support our framework with various simulation studies.
Highlights
In this paper, we derive lower and upper bounds on the OPTA of a two-user multi-input multi-output (MIMO) causal encoding and causal decoding problem
We use the three types of distortion constraints introduced in Section 1.2 to define the corresponding operational definitions for which we study lower and upper bounds in this paper
We give a numerical simulation where we compare the solution of Rjoint corresponds to the lower bound achieved by the optimal coding policies when the system is driven by additive i.i.d
Summary
In this setup, users 1 and 2 are modeled by the following discrete-time time-invariant multidimensional. Where x1t ∈ R p1 , x2t ∈ R p2 , with p1 not necessarily equal to p2 , ( A1 , A2 ) are known constant matrices of appropriate dimensions and (w1t , w2t ) are additive i.i.d. possibly non-Gaussian noise processes with zero mean and covariance matrix Σwi 0, i = 1, 2, independent of x0i , i = 1, 2 and from each other for all t ≥ 0. System Operation: The encoder at each time instant t observes the augmented state xt and generates the data packett ∈ {1, .
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