Physics-compliant channel models of RIS-parametrized radio environments
require the inversion of an "interaction matrix" to capture the mutual coupling
between wireless entities (transmitters, receivers, RIS, environmental
scattering objects) due to proximity and reverberation. The computational cost
of this matrix inversion is typically dictated by the environmental scattering
objects in non-trivial radio environments, and scales unfavorably with the
latter's complexity. In addition, many problems of interest in wireless
communications (RIS optimization, fast fading, object or user-equipment
localization, etc.) require the computation of multiple channel realizations.
To overcome the potentially prohibitive computational cost of using
physics-compliant channel models, we i) introduce an isospectral reduction of
the interaction matrix from the canonical basis to an equivalent reduced basis
of primary wireless entities (antennas and RIS), and ii) leverage the fact that
interaction matrices for different channel realizations only differ regarding
RIS configurations and/or some wireless entities' locations.Comment: 12 pages, 1 figure, submitted to an IEEE Journa