OFDM-PASS: Frequency-Selective Modeling and Analysis for Pinching-Antenna Systems

Abstract: Pinching antenna systems (PASS), which utilize dielectric waveguides for adaptable antenna deployment, offer novel opportunities to create controllable line-of-sight links. This letter is the first to investigate the integration of PASS with orthogonal frequency division multiplexing (OFDM) to ensure their compatibility and to explore the frequency-selective behavior inherent to PASS. First, an end-to-end channel model is proposed for OFDM PASS based on electromagnetic-compliant modeling of waveguides and coupled-mode theory, which includes frequency-dependent waveguide dispersion and antenna coupling effect. Furthermore, a critical dependence of the OFDM cyclic prefix (CP) overhead on the proximity of the operating frequency to the waveguide cutoff is revealed. Moreover, this letter evaluates an approximate pinching antenna location strategy based on path loss minimization, from which the phase misalignment effect across subcarriers in wideband scenarios is derived. Numerical results show that: 1) frequency-selective effects in OFDM PASS lead to substantial variations in subcarrier achievable rates, highlighting the necessity of operating above the waveguide cutoff frequency for effective communication; 2) frequency-independent pinching antenna location approximation incurs significant phase misalignment, particularly for wider bandwidths and larger array sizes; and 3) waveguide dispersion mandates considerable CP overhead when operating near the cutoff frequency, severely impacting the spectral efficiency of OFDM PASS.