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Main Authors: Zhang, Xiaoqi, Zhang, J. Andrew, Liu, Chang, Yuan, Weijie, Li, Geoffrey Ye, Amin, Moeness G.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.29102
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author Zhang, Xiaoqi
Zhang, J. Andrew
Liu, Chang
Yuan, Weijie
Li, Geoffrey Ye
Amin, Moeness G.
author_facet Zhang, Xiaoqi
Zhang, J. Andrew
Liu, Chang
Yuan, Weijie
Li, Geoffrey Ye
Amin, Moeness G.
contents Sensing and communication are fundamental enablers of next-generation networks. While communication technologies have advanced significantly, sensing remains limited to conventional parameter estimation and is far from fully explored. Motivated by these limitations, we propose semantic sensing (SemS), a novel framework that shifts the design objective from reconstruction fidelity to semantic effective recognition. Specifically, we mathematically formulate the interaction between transmit waveforms and semantic entities, thereby establishing SemS as a semantics-oriented transceiver design. Within this architecture, we leverage the information bottleneck (IB) principle as a theoretical criterion to derive a unified objective, guiding the sensing pipeline to maximize task-relevant information extraction. To practically solve this optimization problem, we develop a deep learning (DL)-based framework that jointly designs transmit waveform parameters and receiver representations. The framework is implemented in an orthogonal frequency division multiplexing (OFDM) system, featuring a shared semantic encoder that employs a Gumbel-Softmax-based pilot selector to discretely mask task-irrelevant resources. At the receiver, we design distinct decoding architectures tailored to specific sensing objectives, comprising a 2D residual network (ResNet)-based classifier for target recognition and a correlation-driven 1D regression network for high-precision delay estimation. Numerical results demonstrate that the proposed semantic pilot design achieves superior classification accuracy and ranging precision compared to reconstruction-based baselines, particularly under constrained resource budgets.
format Preprint
id arxiv_https___arxiv_org_abs_2603_29102
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Semantic Sensing: A Task-Oriented Paradigm
Zhang, Xiaoqi
Zhang, J. Andrew
Liu, Chang
Yuan, Weijie
Li, Geoffrey Ye
Amin, Moeness G.
Signal Processing
Sensing and communication are fundamental enablers of next-generation networks. While communication technologies have advanced significantly, sensing remains limited to conventional parameter estimation and is far from fully explored. Motivated by these limitations, we propose semantic sensing (SemS), a novel framework that shifts the design objective from reconstruction fidelity to semantic effective recognition. Specifically, we mathematically formulate the interaction between transmit waveforms and semantic entities, thereby establishing SemS as a semantics-oriented transceiver design. Within this architecture, we leverage the information bottleneck (IB) principle as a theoretical criterion to derive a unified objective, guiding the sensing pipeline to maximize task-relevant information extraction. To practically solve this optimization problem, we develop a deep learning (DL)-based framework that jointly designs transmit waveform parameters and receiver representations. The framework is implemented in an orthogonal frequency division multiplexing (OFDM) system, featuring a shared semantic encoder that employs a Gumbel-Softmax-based pilot selector to discretely mask task-irrelevant resources. At the receiver, we design distinct decoding architectures tailored to specific sensing objectives, comprising a 2D residual network (ResNet)-based classifier for target recognition and a correlation-driven 1D regression network for high-precision delay estimation. Numerical results demonstrate that the proposed semantic pilot design achieves superior classification accuracy and ranging precision compared to reconstruction-based baselines, particularly under constrained resource budgets.
title Semantic Sensing: A Task-Oriented Paradigm
topic Signal Processing
url https://arxiv.org/abs/2603.29102