Method for controlling a tracking device for maximizing the current produced by a bifacial photovoltaic solar module with multi-junction cells

The invention claimed is: 1 . A method for maximizing a current produced by a photovoltaic panel comprising one or more bifacial photovoltaic modules, said one or more bifacial photovoltaic modules comprising a plurality of cells, each provided with at least two stacked and series-connected junctions, the photovoltaic panel being able to be oriented and comprising a device for driving an orientation of the photovoltaic panel with respect to the sun, wherein the method comprises at least: measuring a front face irradiance Ai on an upper photoactive face of said panel and measuring a rear face irradiance Ar on a lower photoactive face of said panel in an initial orientation of said panel, measuring an initial current I produced by the panel in response to the front face irradiance Ai and rear face irradiance Ar and calculating currents Ijg generated by said at least two stacked and series-connected junctions on a basis of physical characteristics of the cells, said initial current I, said front face irradiance Ai and rear face irradiances Ar, calculating an optimized theoretical orientation for which, knowing said front face irradiance Ai and rear face irradiance Ar measured, the currents Ijg generated by said at least two stacked and series-connected junctions, and the physical characteristics of the cells, equalization of a theoretical currents Ijtmax of said at least two stacked and series-connected junctions of the cells is obtained, and positioning the panel in said theoretical orientation in the case where an imbalance between said theoretical currents Ijtmax and said generated currents Ijg is greater than a threshold value dIjmax or maintaining a current position of said panel in the case of a difference in current between said theoretical currents Ijtmax and said generated currents Ijg of less than said threshold value. 2 . The method according to claim 1 , comprising, when the imbalance between said theoretical currents Ijtmax and said generated currents Ijg is less than said threshold value dIjmax, scanning positions of the panel around the theoretical position obtained, measuring the current produced by the panel in each of said positions, and a step of placing the panel in a position maximizing the current produced by the panel. 3 . The method according to claim 1 , wherein the measurement of an irradiance at the upper photoactive face is carried out by one or more upper sensors towards said upper photoactive face of the panel and one or more lower sensors-towards said lower photoactive face of the panel, said method comprises steps prior to implementation of the panel comprising a step of choosing the number of said one or more upper sensors and said one or more lower sensors and a step of positioning said one or more upper sensors and said one or more lower sensors according to shading conditions and uniformity of light perceived above and below the panel according to several tilts of the panel, so as to generate irradiance data appropriate for the calculation of said theoretical orientation. 4 . The method according to claim 3 , wherein said prior steps comprise a positioning of said one or more upper sensors and said one or more lower sensors at areas of the panel with the highest irradiance variations exclusive of shade, according to an orientation of the panel. 5 . A photovoltaic panel, configured for an implementation of a method for maximizing a current produced by a photovoltaic panel comprising one or more bifacial photovoltaic modules, said one or more bifacial photovoltaic modules comprising a plurality of cells, each provided with at least two stacked and series-connected junctions, the photovoltaic panel being able to be oriented and comprising a device for driving an orientation of the photovoltaic panel with respect to the sun, wherein the method comprises at least: measuring a front face irradiance Ai on an upper photoactive face of said panel and measuring a rear face irradiance Ar on a lower photoactive face of said panel in an initial orientation of said panel, measuring an initial current I produced by the panel in response to the front face irradiance Ai and rear face irradiance Ar and calculating currents Ijg generated by said at least two stacked and series-connected junctions on a basis of physical characteristics of the cells, said initial current I, said front face irradiance Ai and rear face irradiance Ar, calculating an optimized theoretical orientation for which, knowing said front face irradiance Ai and rear face irradiance Ar measured, the currents Ijg generated by said at least two stacked and series-connected junctions, and the physical characteristics of the cells, equalization of a theoretical currents Ijtmax of said at least two stacked and series-connected junctions of the cells is obtained, and positioning the panel in said theoretical orientation in the case where an imbalance between said theoretical currents Ijtmax and said generated currents Ijg is greater than a threshold value dIjmax or maintaining a current position of said panel in the case of a difference in current between said theoretical currents Ijtmax and said generated currents Ijg of less than said threshold value, wherein said photovoltaic panel comprises one or more of said bifacial photovoltaic modules, the cells of which are bifacial multi-junction cells in which junctions of said bifacial multi-junction cells are connected in series. 6 . The panel according to claim 5 , wherein the cells of the bifacial photovoltaic modules are interconnected along a series-parallel network. 7 . A computer program comprising instructions for implementing a method for maximizing a current produced by a photovoltaic panel comprising one or more bifacial photovoltaic modules, said bifacial photovoltaic modules comprising a plurality of cells, each provided with at least two stacked and series-connected junctions, the panel being able to be oriented and comprising a device for driving an orientation of the photovoltaic panel with respect to the sun, wherein the method comprises at least: (a) measuring a front face irradiance Ai on an upper photoactive face of said panel and measuring a rear face irradiance Ar on a lower photoactive face of said panel in an initial orientation of said panel, (b) measuring an initial current I produced by the panel in response to the front face irradiance Ai and the rear face irradiance Ar and calculating a currents Ijg generated by said stacked and series-connected junctions on a basis of physical characteristics of the cells, said initial current, front face irradiance Ai and rear face irradiance Ars, (c) calculating an optimized theoretical orientation for which, knowing said measured front face irradiance Ai and the rear face irradiance Ar, the currents Ijg, and the physical characteristics of the cells, an equalization of a theoretical currents Ijtmax of the stacked and series-connected junctions of the cells is obtained, and (d) positioning the panel in said theoretical orientation in the case where an imbalance between said theoretical currents Ijtmax and said currents Ijg is greater than a threshold value dIjmax or maintaining a position of said panel in the case of a difference in current between said theoretical currents Ijtmax and said currents Ijg of less than said threshold value when this program is executed by a processor. 8 . The program according to claim 7 , comprising further instructions to provide scanning positions of the panel around the theoretical orientation obtained, measuring the current produced by the panel in each of said positions, and a step of placing the panel in a position maximizing the current produced by the panel, when the imbalance between said theoretical currents Ijtmax and said