Joint Detection and Velocity Estimation in OFDM-ISAC Cell-Free Massive MIMO Networks
This work addresses the challenge of joint detection and velocity estimation in distributed ISAC networks, providing a scalable solution with practical optimization strategies.
This paper develops a Doppler-aware sensing framework for cell-free massive MIMO networks under OFDM-based ISAC, incorporating 3D-bistatic Doppler geometry into a GLRT detector. The proposed PSO-aided detector achieves the best accuracy-complexity trade-off, and Doppler mismatch causes substantial sensing-SNR degradation in high-mobility scenarios.
This paper develops a Doppler-aware sensing framework for cell-free massive MIMO (CF-mMIMO) networks operating under OFDM-based integrated sensing and communication (ISAC). The framework explicitly incorporates the 3D-bistatic Doppler geometry across distributed access points (APs) into a generalized likelihood ratio test (GLRT) detector. To address the scalability, a user-target-centric AP association approach is utilized. The 3D tangential components of the target's velocity vector are estimated, and several search and optimization strategies, including coarse grid search, gradient-based refinement, and particle swarm optimization (PSO), are developed and evaluated. The Doppler-aware GLRT statistic and receive sensing signal-to-noise ratio (SNR) are derived. Simulation results demonstrate that the proposed PSO-aided detector achieves the most favorable accuracy-complexity trade-off, while Doppler mismatch can cause substantial sensing-SNR degradation in high-mobility scenarios. Additionally, leveraging more OFDM subcarriers enhances frequency-domain diversity and yields further sensing-SNR gains.