Low-complexity MU-MIMO-GFDM joint receivers

Wang, Hsuan-Fu; Ueng, Fang‐Biau; Sung, Yun-Hsuan

doi:10.1080/00207217.2022.2068666

Cited by 3 publications

(1 citation statement)

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“…Wireless communication systems generally face severe requirements in terms of latency, dependability, capacity, and transmission speed to address the communication needs of new emerging implementations like virtual reality (VR) and ultra-high definition multimedia in fifth-generation (5G) [1][2][3]. Additionally, the advancement of wireless communication technology is constrained by several detrimental components in radio propagation environments, including multipath fading, propagation attenuation, inter-symbol interference (ISI), and multi-user interference.…”

Section: Introductionmentioning

confidence: 99%

Advanced lifting wavelet transform and V‐degree polynomial‐based channel estimation in MIMO‐GFDM

Ray,

Oza

2023

Int J Communication

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SummaryThe future generation of wireless communications systems uses the generalized frequency division multiplexing (GFDM) due to its viable candidate waveform to perform multiple user scheduling. It is a non‐orthogonal waveform susceptible to intercarrier and intersymbol interference (ISI); still, it offers flexible pulse shaping that enhances the efficiency of user scheduling. Here, to accomplish spatial diversity, the multiple‐input multiple‐output (MIMO) is incorporated with GFDM to enhance the performance; there is also an extra inter‐antenna interference problem that limits the model's performance. The issue concerning inter‐antenna interference can be resolved by adopting pilot‐based information transfer. The detection of a signal at the receiver based on the minimum mean square error has the issue of computational complexity while enhancing the estimation quality of a detector. Hence, a low‐complexity channel estimation technique is proposed in this research using the V‐degree polynomial‐based channel estimation technique, wherein the cubic order computation is reduced to square order. Also, the proposed adaptive pulse shaping technique, wherein the filter coefficient is optimized using the gazelle optimization algorithm (GOA) to provide optimal pulse shaping filter parameters by employing bit error rate (BER) as the objective function. The performance of a proposed V‐degree polynomial‐based channel estimation is analyzed based on various assessment measures like BER and MSE and acquired the minimal values of 5.75E‐05 and 2.07E‐05, respectively.

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Section: Introductionmentioning

confidence: 99%