A general modeling method for I–V characteristics of geometrically and electrically configured photovoltaic arrays

A general method for modeling typical photovoltaic (PV) arrays and modules is proposed to find the exact current and voltage relationship of PV arrays or modules of geometrically and electrically different configurations. Nonlinear characteristic equations of electrical devices in solar array or module systems are numerically constructed without adding any virtual electrical components. Then, a robust damped Newton method is used to find exact I–V relationship of these general nonlinear equations, where the convergence is guaranteed. The model can deal with different mismatch effects such as different configurations of bypass diodes, and partial shading. Geometry coordinates of PV components are also considered to facilitate the modeling of the actual physical configuration. Simulation of a PV array with 48 modules, partially shaded by a concrete structure, is performed to verify the effectiveness and advantages of the proposed method.

► A novel and general method is proposed for modeling PV arrays or modules.
► A robust algorithm is used for the first time to improve the convergence to solution.
► Auxiliary functions in other general methods are not compulsory in our method.
► It is novel that geometric configuration is also incorporated.
► A case study is performed to show the approach’s advantages and unique features.