Abstract
In order to gain insights into the potential and behavior of training-based MIMO systems, the relationship of joint decoding scheme and separate decoding scheme is considered, and the equivalence between these two decoding schemes is proved. For the considered joint decoding scheme, receiver decodes out data by joint processing of received signals of both training symbols and data symbols in the maximum likelihood (ML) sense. We refer it as the joint ML-decoder. By contrast, in the considered separate decoding scheme, receiver first estimates channels in the minimum mean-square-errors (MMSE) sense, and then, based on the estimated channel information and the received signals of data symbols, the receiver decodes out data in the ML sense. We refer it as the separate MMSE-ML decoder. Notice that this separate MMSE-ML decoder is different from the decoder appeared in the most of existing works, where a kind of mismatched ML decoding is used after the phase of channel estimation. Although the above-mentioned decoding schemes have different decoding procedures, we prove that the joint ML-decoder and the separate MMSE-ML decoder are equivalent, while they outperform the mismatched ML decoder. With this equivalence, it is implied that the MMSE channel estimator is optimal when the overall system performance is considered, and the separate MMSE-ML decoding scheme can achieve the same performance with that of joint ML decoding scheme. Furthermore, this equivalence also provides us another way to analyze the system performance of the considered separate or joint decoding scheme. Namely, the results obtained from the considered joint decoding scheme can be directly applied to the considered separate decoding scheme, and vice versa.
Highlights
Future wireless communication systems are aiming at providing high-speed data services with high reliability
One of the efficient routes for achieving this objective is to design the wireless communication systems based on the principles of multiple-input multiple-output (MIMO), owning to the fact that MIMO systems have the potential to achieve a much higher spectral-efficiency than what can be achieved by the conventional single-input single-output (SISO) systems without increase in transmitted power [1]–[3]
Our main contribution in this paper is that we strictly prove that the joint maximum likelihood (ML) decoding scheme is equivalent to the separate minimum mean-square-errors (MMSE)-ML decoding scheme
Summary
Future wireless communication systems are aiming at providing high-speed data services with high reliability. In the performance analysis of training based MIMO systems, a combination of MMSE channel estimation and ML data decoding, which is referred to as separate MMSE-ML decoding, is usually considered [6], [8], [13]–[15]. This is because that the above-mentioned receiver scheme is intuitively regarded as optimal in the type of separate decoding scheme. We want to gain insights into the potential of separate decoding scheme in the training-based MIMO systems, as well as to know whether the linear MMSE channel estimation is optimal in the sense of system BER performance. For a matrix A, At denotes its transpose, AH denotes its conjugate transpose, det(A) denotes its determinant, tr(A) denotes its trace, and A denotes its Frobenius norm
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