Abstract We experimentally, numerically and theoretically study the optimal mean time needed by a Brownian particle, freely diffusing either in one or two dimensions, to reach, within a tolerance radius R tol , a target at a distance L from an initial position in the presence of resetting. The reset position is Gaussian distributed with width σ . We derived and tested two resetting protocols, one with a periodic and one with random (Poissonian) resetting times. We computed and measured the full first-passage probability distribution that displays spectacular spikes immediately after each resetting time for close targets. We study the optimal mean first-passage time as a function of the resetting period/rate for different target distances (values of the ratios b = L / σ ) and target size ( a = R tol / L ). We find an interesting phase transition at a critical value of b , both in one and two dimensions. The details of the calculations as well as the experimental setup and limitations are discussed.