The tunability of radio environments with reconfigurable intelligent surfaces
(RISs) enables the paradigm of smart radio environments in which wireless
system engineers are no longer limited to only controlling the radiated signals
but can in addition also optimize the wireless channels. Many practical radio
environments include complex scattering objects, especially indoor and factory
settings. Multipath propagation therein creates seemingly intractable coupling
effects between RIS elements, leading to the following questions: How can a
RIS-parametrized rich-scattering environment be modelled in a physics-compliant
manner? Can the parameters of such a model be estimated for a specific but
unknown experimental environment? And how can the RIS configuration be
optimized given a calibrated physics-compliant model? This chapter summarizes
the current state of the art in this field, highlighting the recently unlocked
potential of frugal physical-model-based open-loop control of RIS-parametrized
rich-scattering radio environments.Comment: 29 pages, 3 figures, author's version of chapter from forthcoming
book "Reconfigurable Metasurfaces for Wireless Communications: Architectures,
Modeling, and Optimization