maximum-power-pointtracking

(MPPT) method focused on low-power (< 1 W) photovoltaic

(PV) panels. The static and dynamic performance is

theoretically analyzed, and design criteria are provided. A prototype

was implemented with a 500-mW PV panel, a commercial

boost converter, and low-power components for the MPPT

controller. Laboratory measurements were performed to assess

the effectiveness of the proposed method. Tracking efficiency was

higher than 99.6 . The overall efficiency was higher than 92 for

a PV panel power higher than 100 mW. This is, in part, feasible

due to the low power consumption of the MPPT controller, which

was kept lower than 350 μW. The time response of the tracking

circuit was tested to be around 1 s. Field measurements showed

energy gains higher than 10.3 with respect to a direct-coupled

solution for an ambient temperature of 26 ◦ C. Higher gains are

expected for lower temperatures.-maximum-power-pointtracking

(MPPT) method focused on low-power (< 1 W) photovoltaic

(PV) panels. The static and dynamic performance is

theoretically analyzed, and design criteria are provided. A prototype

was implemented with a 500-mW PV panel, a commercial

boost converter, and low-power components for the MPPT

controller. Laboratory measurements were performed to assess

the effectiveness of the proposed method. Tracking efficiency was

higher than 99.6 . The overall efficiency was higher than 92　for

a PV panel power higher than 100 mW. This is, in part, feasible

due to the low power consumption of the MPPT controller, which

was kept lower than 350 μW. The time response of the tracking

circuit was tested to be around 1 s. Field measurements showed

energy gains higher than 10.3　with respect to a direct-coupled

solution for an ambient temperature of 26 ◦ C. Higher gains are

expected for lower temperatures.