Abstract
In recent years, the standardization for the fifth generation (5G) mobile communication systems has been actively discussed, and it is expected that a large number of wireless communication terminals, and beyond, in the current systems are accommodated in 5G systems. One of the steps in establishing this system is an advanced multiple access technology. In this paper, we propose a chaos non-orthogonal multiple access (C-NOMA) scheme for downlink transmission that offers high capacity allocation and secure wireless multiple access with physical layer security. In 5G systems where many terminals concurrently communicate, it is also important to ensure communication integrity for each user while maintaining large capacity communication. As a secure wireless channel-coded communication scheme, we have proposed a chaos multiple-input multiple-output (C-MIMO) scheme using the principle of chaos communication. By applying C-MIMO into a power-domain non-orthogonal multiple access transmission, we were able to demonstrate the operation and suitability of the C-NOMA configuration for handling both large capacity and physical layer security against eavesdroppers. We also demonstrated its improved performances through numerical simulations, and provided comparisons with those of conventional NOMA and chaos orthogonal frequency division multiple access schemes. In addition, we evaluated the security capability of the proposed technique based on the channel capacity of eavesdroppers and showed that secure transmission can be achieved using floating-point calculations.
Highlights
With the increasing advancement of Internet technology, and in addition to conventional physical devices such as personal computers and smartphones, all kinds of other objects around the world like household appliances and automobiles are being connected to the Internet
3.2 Configuration of signal keys and chaos iteration number among users We investigated the influence of the configuration of signal keys and chaos iteration number among users for the bit error rate (BER) performance in the C-non-orthogonal multiple access (NOMA) scheme to clarify the restrictions of the signal keys
4 Conclusions A downlink chaos non-orthogonal multiple access scheme (C-NOMA), which provided high capacity allocation and physical layer security by applying the principle of chaos multiple-input multiple-output (C-MIMO) scheme was presented in this paper
Summary
With the increasing advancement of Internet technology, and in addition to conventional physical devices such as personal computers and smartphones, all kinds of other objects around the world like household appliances and automobiles are being connected to the Internet. As with regards to physical layer security schemes, we have proposed a chaos multiple-input multiple-output (C-MIMO) transmission method, which has both the functionality of encrypted modulation and channel coding, for exploiting the principle of chaos communications [7]. In this method, Gaussian modulated signals are generated from chaos signals correlated with transmission bits in a short block, and these signals are transmitted by MIMO spatial multiplexing. In [14], the security rate in unicast and multicast streaming scenarios in NOMA was investigated In these studies, secrecy of the system is safeguarded in the physical layer using SISO, MISO, or MIMO channel matrix and beamforming techniques like the multi-user MIMO system, in which user-specific components are not accommodated. (Comments #3–5) Notations: lowercase and uppercase boldface letters denote vectors and matrices, respectively
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