Abstract
For supporting the massive connectivities and better adapting the high dynamical channel states of the cellular Internet of things networks, in this paper we proposed a new grant-free rateless sparse code multiple access (RSCMA) protocol. In the proposed grant-free RSCMA, users switch from the inactive mode to the active mode as soon as they receive data packages, and start to transmit the data without the request-grant process between the base station (BS) and users. In each transmission, the active users firstly choose a certain number of the modulated SCMA symbols according to the pre-assigned access control function (ACF), and then transmit the linearly superimposed SCMA symbols to the BS over the available resource elements. At the BS, owing to the sparsity of RSCMA, message passing algorithm which allows multi-user detection with near-optimal performance can be utilized to decode the messages. The transmission will continue until the user successfully receives an ACK signal sent back from the BS. Theoretical analysis in terms of achievable constellation constrained throughput is provided to show the maximal sum rate of RSCMA and to optimize the ACF design under the trade-off between the complexity and throughput performance. Both theoretical and simulation results show that the RSCMA can achieve higher throughput than the existing rateless multiple access schemes, such as hybrid automatic repeat request SCMA, LT code coded SCMA, and rateless multiple access.
Highlights
The future cellular Internet of things (IoT) networks are required to support larger-scale connectivities [1]
Inspired by the improvement from low-density signature (LDS) to sparse code multiple access (SCMA), in this paper we propose the grant-free rateless SCMA (RSCMA) scheme based on the basic framework of rateless multiple access (RMA) proposed in [10]–[12]
According to the analysis results, we find that the shaping gain of the SCMA codebook can improve the throughput performance of RSCMA when compared to the conventional RMA
Summary
The future cellular Internet of things (IoT) networks are required to support larger-scale connectivities [1]. Physical resources in NOMA are usually allocated to the users in a fixed and centralize manner, such as user pairing and power allocation in power-domain NOMA [3], [4], codebook or sparse signature assign in sparse code multiple access (SCMA) [5] or low-density signature (LDS) [6] This centralized resource allocation imposes on high signaling overhead, especially along with the increase of the number of the connected users in future cellular IoT networks. The authors in [10]–[12] proposed the rateless multiple access (RMA) to overcome the challenges brought by centralized resource allocation and high dynamical channel state.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
