12 research outputs found
Interference and Rate Analysis of Multinumerology NOMA
5G communication systems and beyond are envisioned to support an extremely diverse set of use cases with different performance requirements. These different requirements necessitate the use of different numerologies for increased flexibility. Non-orthogonal multiple access (NOMA) can potentially attain this flexibility by superimposing user signals while offering improved spectral efficiency (SE). However, users with different numerologies have different symbol durations. When combined with NOMA, this changes the nature of the interference the users impose on each other. This paper investigates a multinumerology NOMA (MN-NOMA) scheme using successive interference cancellation (SIC) as an enabler for coexistence of users with with different numerologies. Analytical expressions for the inter-numerology interference (INI) experienced by each user at the receiver are derived, where mean-squared error (MSE) is the metric used to quantity INI. Using the MSE expressions, we analytically derive achievable rates for each user in the MN-NOMA system. These expressions are then evaluated and used to compare the SE performance of MN-NOMA with that of its single-numerology counterpart. The proposed scheme can achieve the desired flexibility in supporting diverse use cases in future wireless networks. The scheme also gains the SE benefits of NOMA compared to both multinumerology and single numerology orthogonal multiple access (OMA) schemes
Resource allocation for mixed numerology NOMA
6G wireless networks will require the flexibility to accommodate an extremely diverse set of service types. Accommodating different quality of service (QoS) requirements for these service types necessitates the use of mixed numerologies, where services using different subcarrier spacings or symbol durations coexist in the same frequency band. Non-orthogonal multiple access (NOMA) techniques can potentially be used to accommodate users with different numerologies while also gaining the performance benefits associated with NOMA. To achieve the full performance benefits of a mixed numerology NOMA (MN-NOMA) system, resource allocation is paramount. However, the coexistence of mixed numerologies changes the nature of the interference that each user experiences. In this letter, we approach the problem of optimizing subcarrier and power allocation for maximizing the spectral efficiency of MN-NOMA. In particular, we propose a two-stage sub-optimal approach to solve this problem. Numerical results show that the proposed approach provides performance gains over existing benchmark schemes of up to 14% and 12% in spectral efficiency and fairness, respectively
Application-Based Coexistence of Different Waveforms on Non-orthogonal Multiple Access
The coexistence of different wireless communication systems such as LTE and
Wi-Fi by sharing the unlicensed band is well studied in the literature. In
these studies, various methods are proposed to support the coexistence of
systems, including listen-before-talk mechanism, joint user association and
resource allocation. However, in this study, the coexistence of different
waveform structures in the same resource elements are studied under the theory
of non-orthogonal multiple access. This study introduces a paradigm-shift on
NOMA towards the application-centric waveform coexistence. Throughout the
paper, the coexistence of different waveforms is explained with two specific
use cases, which are power-balanced NOMA and joint radar-sensing and
communication with NOMA. In addition, some of the previous works in the
literature regarding non-orthogonal waveform coexistence are reviewed. However,
the concept is not limited to these use cases. With the rapid development of
wireless technology, next-generation wireless systems are proposed to be
flexible and hybrid, having different kinds of capabilities such as sensing,
security, intelligence, control, and computing. Therefore, the concept of
different waveforms' coexistence to meet these concerns are becoming impressive
for researchers.Comment: Submitted to IEEE for possible publication. arXiv admin note: text
overlap with arXiv:2007.05753, arXiv:2003.0554
Inter-Numerology Interference Analysis for 5G and Beyond
One of the defining characteristics of 5G is the flexibility it offers for
supporting different services and communication scenarios. For this purpose,
usage of multiple numerologies has been proposed by the 3rd Generation
Partnership Project (3GPP). The flexibility provided by multi-numerology system
comes at the cost of additional interference, known as inter-numerology
interference (INI). This paper comprehensively explains the primary cause of
INI, and then identifies and describes the factors affecting the amount of INI
experienced by each numerology in the system. These factors include subcarrier
spacing, number of used subcarriers, power offset, windowing operations and
guard bands
Interference Analysis in Multi-Numerology OFDM Systems: A Continuous-Time Approach
Multi-numerology multi-carrier (MN-MC) techniques are considered as essential enablers for RAN slicing in fifth-generation (5G) communication systems and beyond. However, utilization of mixed numerologies breaks the orthogonality principle defined for single-numerology orthogonal frequency division multiplexing (SN-OFDM) systems with a unified subcarrier spacing. This leads to interference between different numerologies, i.e., inter-numerology interference (INI). This paper develops metrics to quantify the level of the INI using a continuous-time approach. The derived analytical expressions of INI in terms of mean square error (MSE) and error vector magnitude (EVM) directly reveal the main contributing factors to INI, which can not be shown explicitly in a matrix form INI based on discrete-time calculations. Moreover, the study of power offset between different numerologies shows a significant impact on INI, especially for high order modulation schemes. The finding in this paper provides analytical guidance in designing multi-numerology (MN) systems, for instance, developing resource allocation schemes and interference mitigation techniques