Disclosed herein is a multilayer solar module installation structure. The multilayer solar module installation structure includes: a pair of frames which are spaced apart from each other, and in which guide grooves are formed through the opposite side surfaces thereof in longitudinal directions; and solar modules which are installed on upper and lower sides between the frames so that they are movable along the guide grooves, and which convert the solar energy of incident solar light into electric energy. Through this configuration, the solar modules are disposed on the upper and lower sides of the frames, thereby achieving the effect of efficiently using a solar light installation space.

Methods and systems are disclosed that automatically determine solar access values. In one implementation, a 3D geo-referenced model of a structure is retrieved in which geographic location on the earth of points in the 3D geo-referenced model are stored or associated with points in the 3D geo-referenced model. Object point cloud data indicative of object(s) that cast shade on the structure is retrieved. The object point cloud data may be generated from one or more georeferenced images and the object point cloud data is indicative of an actual size, shape, and location of the object(s) on the earth. The structure in the 3D geo-referenced model is divided into one or more sections, which are divided into one or more areas, each area having at least three vertices. Then, a solar access value for the particular vertex is determined.

A solar tracker system comprising a plurality of on sun trackers and a plurality of off sun tracker. Each tracker is selectively adjusted to achieve a desired power output of the solar power plant system in an example.

A photovoltaic energy system includes a photovoltaic field configured to convert solar energy into electrical energy, one or more solar intensity sensors configured to measure solar intensity and detect a cloud approaching the photovoltaic field, and a controller. The controller receives input from the solar intensity sensors and predicts a change in solar intensity within the photovoltaic field before the change in solar intensity within the photovoltaic field occurs. The controller is configured to preemptively adjust an electric power output of the photovoltaic energy system in response to predicting the change in solar intensity within the photovoltaic field.

A method of modulating the impact of electromagnetic irradiance on the thermal energy budget of a predominantly enclosed space includes providing at least an inner shell of the predominantly enclosed space, and placing a plurality of functional elements in an exterior position relative to an outside facing side of the inner shell. The outside facing surfaces of the functional elements have higher reflectivity in the visible (VIS) and near infrared (NIR) wavelength range relative to the (MIR) wavelength range. The inside facing surfaces of the functional elements have higher reflectivity in the NIR and mid-infrared (MIR) wavelength range relative to the (VIS) wavelength range. A thickness of the functional elements is equal to or smaller than a thickness of the inner shell.

A drone landing system includes a solar collector to charge the drone at a landing cite of the drone landing system. The solar collector may include a solar collector mounting assembly, preferably comprises a bi-facial solar active component mounted with its solar active face(s) orthogonal to the ground/horizon, at or near its perimeter frame.

A robotic controller for autonomous calibration and inspection of two or more solar surfaces wherein the robotic controller includes a drive system to position itself near a solar surface such that onboard sensors may be utilized to gather information about the solar surface. An onboard communication unit relays information to a central processing network, this processor combines new information with stored historical data to calibrate a solar surface and/or to determine its instantaneous health.

Mixed heliostat field combining, in the same field, heliostats of different sizes and/or with different types of facets, all of them having at least one facet and being canted or not, and either having spherical, cylindrical, flat or quasi-flat (spherical with a high curvature radius) facets, such that the solar field is optimised in order to minimise shadows and blockages between heliostats, as a result of correct positioning of the heliostats in the field.

A method of modulating the impact of electromagnetic irradiance on the thermal energy budget of a predominantly enclosed space, in some instances buildings, includes providing at least an inner shell and placing a plurality of functional elements in an exterior position relative to an outside facing side thereof. The outside facing surfaces of the functional elements have higher reflectivity in the visible (VIS) and near infrared (NIR) wavelength range relative to the mid-infrared (MIR) wavelength range. The inside facing surfaces of the functional elements have higher reflectivity in the NIR and MIR wavelength range relative to the VIS wavelength range. The functional elements are least in one degree of freedom spatially adjustable. A thermal carrier medium may be present to increase thermal capacity and to permit transfer of thermal energy. A control system adjusts the spatial position of some of said functional elements and/or the distribution of the thermal carrier medium such that the thermal energy budget of the predominately enclosed space is influenced according to at least one desired target value.

Split-cell and multi-panel photovoltaic backtracking control systems and methods allow for increased total power generation during low sun elevation conditions by shading a percentage of panel modules, thereby allowing for a lower angle of incidence on unshaded modules. The control systems and methods involve determining a sun elevation angle, a traditional backtracking angle, a split-cell or multi-panel backtracking angle, a single-cell or single-panel relative light transmission (RLT) based on the single-cell or single-panel backtracking angle, and a split-cell or multi-panel RLT based on the split-cell or multi-panel backtracking angle. If twice the single-cell or single-panel RLT is greater than the split-cell or multi-panel RLT, the split-cell or multi-panel backtracking angle is used; otherwise, the single-cell or single-panel backtracking angle is used. The control systems and methods may further involve determining a diffuse fraction index (DFI) and, if the DFI is greater than a DFI limit, using a DFI tracking angle.