In this study, we report the experimental results of selective deposition of Platinum on nanodevices as real-time hydrogen sensors by localized joule heating. The active channels of nanobelt devices were consisted of n+/n-/n+ structure, and localize joule heating was induced at the local high resistance region. The surface temperature was estimated by COMSOL simulations for different biases. AFM was used to investigate the removal of PMMA, and monitored different lengths and thicknesses of Platinum deposition. First, responses of different hydrogen concentrations in vacuum were measured. The results show that the metal length on sensing region are proportional to the sensitivity, and metal thickness are inversely proportional to the sensitivity. Furthermore, different self-heating voltages were applied to accelerate the response and recovery time, and increase detection limit to 50 ppm. In addition, devices after high voltage and long-time stress exhibited improvement in sensing. Finally, in order to detect hydrogen under atmosphere, we design a small chamber made by PDMS to achieve the hydrogen detection. This modification functioned well and showed as almost the same sensitive as that in vacuum, proving by equilibrium dissociation rate constant calculation. The detection limit under atmosphere is about 2.5 ppm.