Classic metasurfaces are functional media which have promising applications, yet they cannot react to environmental changes and
adapt themselves in a controllable manner. As an upshot, they cannot allow for point-to-point or programmatic control, i.e. no interface,
means for automation and formal programming. Even at the level of plain, static metasurfaces, many significant configurations are
hindered by the lack of metasurface tuning competences and their limited working bandwidth, primarily attributed to the resonance
nature of their sub-wavelength building blocks. Presently, research acknowledges the need to attain tunable, switchable, nonlinear
and sensing functionalities at the metasurface level. However, there is no proposal for software-defined smart control or equivalent.
VISORSURF addresses the shortcomings of the literature and proposes true, software definition of the EM properties of a medium, allowing its interconnection to smart control loops in real-time.
VISORSURF is expected to allow software developers and engineers to design systems that contain the electromagnetic behavior of objects into their control loops, without required knowledge
of the underlying Physics. This evolution comes as a timely extension of the Internet-of-Things (IoT) concept. IoT constitutes a robust, complete hardware platform (hardware and full
software stack included) for connecting anything-to-anything, under a considerable range of conditions and use-cases: houses that perform
access control, unlocking/locking doors when the owner approaches, and regulating the room temperature, lights and music according to
his perceived mood; medical implants can calls the doctors if they shows signs of failure, long before the user notices, and more. Novel
IoT products are being released almost daily, at a trend that is expected to yield 20-30 billion connected IoT devices by 2020.
Software-defined metasurfaces can give the already successful IoT concept a new application field over the electromagnetic behavior
of objects. Coupled with related efforts seeking to provide control over mechanical properties, IoT can extend to IoM (Internet-of-Materials),
offering unprecedented capabilities.