The microplasma system under normal pressure does not need to operate in a low-pressure to vacuum environment, and the plasma discharge volume is small, so the cost of the equipment can be greatly reduced and the high portability can be provided. This study combines a home-made high voltage circuit module with a smartphone spectrometer device, and regulates the components in the circuit module to increase the output power of the plasma to improve the intensity of the metal during spectral analysis, and combines the smartphone with a home-made monochromator to collect plasma source, which provides the possibility of heavy metal detection in aqueous solution.The home-made high voltage circuit module of this research belongs to DC to DC boost module, and its circuit configuration is composed of oscillating circuit, transformer and voltage doubler circuit.The oscillating circuit converts the DC input into AC, then boosts voltage through transformer. Finally the AC voltage is doubled and rectified with a doubler voltage circuit, so the final output is high DC voltage. In addition, in the above three components of the circuit, the components of the oscillating circuit are mainly studied, and the influence of the series inductance or ballast resistance on the plasma voltage and current is investigated. A needle tip to aqueous microplasma system was used. The device consisted of a metal needle and a copper. The tip of the needle was defined as a high voltage end, and the solution to be tested in the filter paper on the copper was a low voltage end. The high energy density property of the plasma vaporized the solution to be tested. A optical fiber was used to collect the characteristic light emitted by the excitation of heavy metal element in the solution: the emission spectra were used for the analyze of the heavy metal in the solution. Furthermore, a smartphone were used as a portable heavy metal detector. A mobile power supply was used to provide 5 V DC power, and outputs high DC voltage via a high-voltage module was used to generate plasma. The plasma light source first passed through the slit and became parallel light which was and then diffracted by the grating and split into the photosensitive element inside the smartphone. The photography was taken by the smart phone and was analyzed determine the metal elements in the solution.