Abstract
The rapid booming of future smart city applications and Internet of things (IoT) has raised higher demands on the next-generation radio access technologies with respect to connection density, spectral efficiency (SE), transmission accuracy, and detection latency. Recently, faster-than-Nyquist (FTN) and nonorthogonal multiple access (NOMA) have been regarded as promising technologies to achieve higher SE and massive connections, respectively. In this paper, we aim to exploit the joint benefits of FTN and NOMA by superimposing multiple FTN-based transmission signals on the same physical recourses. Considering the complicated intra- and interuser interferences introduced by the proposed transmission scheme, the conventional detection methods suffer from high computational complexity. To this end, we develop a novel sliding-window detection method by incorporating the state-of-the-art deep learning (DL) technology. The data-driven offline training is first applied to derive a near-optimal receiver for FTN-based NOMA, which is deployed online to achieve high detection accuracy as well as low latency. Monte Carlo simulation results validate that the proposed detector achieves higher detection accuracy than minimum mean squared error-frequency domain equalization (MMSE-FDE) and can even approach the performance of the maximum likelihood-based receiver with greatly reduced computational complexity, which is suitable for IoT applications in smart city with low latency and high reliability requirements.
Highlights
With the rapid development of 5G, higher demands have been brought forward for communication systems. e typical usage scenarios, such as smart city, virtual reality (VR), wearable computing, and the transmission of big data [1], will be effectively realized with the support of advanced radio access technologies in 5G
Compared with Viterbi detections, frequency-domain equalization (FDE)-based algorithm reduces the complexity to a certain extent but the usage of cycle prefix (CP) decreases the spectral efficiency and the detection accuracy does not meet the ideal requirement. erefore, this paper aims to design a joint detection algorithm of FTN-nonorthogonal multiple access (NOMA), where both low computational complexity and high detection accuracy are simultaneously achieved
E training network consists of input layer, three hidden layers, and output layer with 6, 48, 128, 32, and 2 neurons, respectively. e proposed network is constructed and trained based on Tensorflow framework. e module of loss function, i.e., cross entropy in Tensorflow, is sigmoid_cross_entropy_with_logits, in which output values are mapped to the (0, 1) interval with sigmoid function at first, and the cross entropy between the practical output value and training target is calculated. e AdamOptimizer module which can control the learning speed provided by Tensorflow environment is utilized to minimize the loss function
Summary
With the rapid development of 5G, higher demands have been brought forward for communication systems. e typical usage scenarios, such as smart city, virtual reality (VR), wearable computing, and the transmission of big data [1], will be effectively realized with the support of advanced radio access technologies in 5G. Internet of things (IoT), which enables humancomputer interaction and machine-to-machine (M2M) communications, will be the foundation of the services in smart city [1, 2]. With IoT, numerous devices in future smart city can be closely linked and a more intelligent life will be expected. To this end, the spectral efficiency and transmission latency shall be greatly improved and reduced, respectively, under massive connected devices. The spectral efficiency and transmission latency shall be greatly improved and reduced, respectively, under massive connected devices To fulfill these requirements, novel radio access technologies are required, such as novel multiple access (MA) technologies, network architectures, encoding, and modulation methods [3,4,5]
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