This paper presents the design and implementation of a solar energy powered high pressure sodium lamp lighting system. The system is constructed with solar cells, battery chargers, and a power converter as well as batteries. In daytime the batteries are charged by solar energy, and then release the energy for high pressure sodium lamps at night. To reduce switching losses and increase power conversion efficiency, a zero voltage switching (ZVS) DC/DC converter is applied as a battery charger. The perturb and observe maximum power point tracking (MPPT) algorithm is realized in the solar cell system. By combining a push-pull DC/DC converter and a series resonant parallel loaded circuit as a push-pull series resonant parallel loaded electronic ballast, the ignition circuit directly drives the lamps on 24V DC battery voltage; therefore it simplified the structure of the system and increased the power conversion efficiency of the electronic ballast. In this paper, zero voltage switching DC/DC converter and push-pull electronic ballast are simulated by Pspice software. Then, the digital signal processor is used to implement the system, to reduce the number of circuit components and speed up the circuit design stage. The result of the experiment shows that the proposed lighting system has the advantages of high efficiency and simple structure. The lighting system is particularly suitable when installed at those areas where there is powerful sunshine and without power utility service.