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Main Authors: Arun, Advaith, Shankar, Shiv, Baskaran, Dhivagar, Milleth, Klutto, Ramamurthi, Bhaskar
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.14953
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author Arun, Advaith
Shankar, Shiv
Baskaran, Dhivagar
Milleth, Klutto
Ramamurthi, Bhaskar
author_facet Arun, Advaith
Shankar, Shiv
Baskaran, Dhivagar
Milleth, Klutto
Ramamurthi, Bhaskar
contents Future wireless systems are expected to employ a substantially larger number of transmit ports for channel state information (CSI) estimation compared to current specifications. Although scaling ports improves spectral efficiency, it also increases the resource overhead to transmit reference signals across the time-frequency grid, ultimately reducing achievable data throughput. In this work, we propose an deep learning (DL)-based CSI reconstruction framework that serves as an enabler for reliable CSI acquisition in future 6G systems. The proposed solution involves designing a port-cycling mechanism that sequentially sounds different portions of CSI ports across time, thereby lowering the overhead while preserving channel observability. The proposed CSI Adaptive Network (CsiAdaNet) model exploits the resulting sparse measurements and captures both spatial and temporal correlations to accurately reconstruct the full-port CSI. The simulation results show that our method achieves overhead reduction while maintaining high CSI reconstruction accuracy.
format Preprint
id arxiv_https___arxiv_org_abs_2601_14953
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Deep Learning assisted Port-Cycling based Channel Sounding for Precoder Estimation in Massive MIMO Arrays
Arun, Advaith
Shankar, Shiv
Baskaran, Dhivagar
Milleth, Klutto
Ramamurthi, Bhaskar
Signal Processing
Future wireless systems are expected to employ a substantially larger number of transmit ports for channel state information (CSI) estimation compared to current specifications. Although scaling ports improves spectral efficiency, it also increases the resource overhead to transmit reference signals across the time-frequency grid, ultimately reducing achievable data throughput. In this work, we propose an deep learning (DL)-based CSI reconstruction framework that serves as an enabler for reliable CSI acquisition in future 6G systems. The proposed solution involves designing a port-cycling mechanism that sequentially sounds different portions of CSI ports across time, thereby lowering the overhead while preserving channel observability. The proposed CSI Adaptive Network (CsiAdaNet) model exploits the resulting sparse measurements and captures both spatial and temporal correlations to accurately reconstruct the full-port CSI. The simulation results show that our method achieves overhead reduction while maintaining high CSI reconstruction accuracy.
title Deep Learning assisted Port-Cycling based Channel Sounding for Precoder Estimation in Massive MIMO Arrays
topic Signal Processing
url https://arxiv.org/abs/2601.14953