Maximum power point (MPP) tracking technique based an optimized
adaptive differential conductance technique was developed in this paper. The performance
of the algorithm developed in this paper was evaluated at solar irradiance
of 1,000, 800 and 600 W/m2 and at temperature of 298, 328 and 358 K. From the
simulation results, it was observed that the impedance of the panel decreases as
the irradiance increases while the impedance of the load is not affected by the irradiance.
This technique was also validated with conventional incremental conductance
(INC) technique. From the validation result, the resultant conductance of the
optimized adaptive differential conductance technique at MPP is 0.0030 mho higher
than resultant conductance at ideal condition while conventional technique has the
resultant conductance of 0.0418 mho lower than the resultant conductance at ideal
condition. From the analysis, the technique has a relative improvement of 6.0558%
compared to the conventional INC technique. The simulation was done using Matrix
Laboratory (MATLAB).
U., V , Iloanusi1, O & Eze1, M (2023). Maximum power point tracking based on differential conductance. Afribary. Retrieved from https://track.afribary.com/works/maximum-power-point-tracking-based-on-differential-conductance
U., Val et. al. "Maximum power point tracking based on differential conductance" Afribary. Afribary, 12 Jul. 2023, https://track.afribary.com/works/maximum-power-point-tracking-based-on-differential-conductance. Accessed 26 Dec. 2024.
U., Val, Ogechukwu Iloanusi1 and Martin Eze1 . "Maximum power point tracking based on differential conductance". Afribary, Afribary, 12 Jul. 2023. Web. 26 Dec. 2024. < https://track.afribary.com/works/maximum-power-point-tracking-based-on-differential-conductance >.
U., Val , Iloanusi1, Ogechukwu and Eze1, Martin . "Maximum power point tracking based on differential conductance" Afribary (2023). Accessed December 26, 2024. https://track.afribary.com/works/maximum-power-point-tracking-based-on-differential-conductance