This study focus on developing a stable, complete, and energy-efficient control strategy for specific PHEVs. Under different driving conditions and requests, the power units can drive the mobile efficiently, accomplish best performance and reduce the exhaust emissions. The control strategy would be very complicated to realize the functional requirements. There are increasing risks from systematic failures caused by logic defects and random hardware failures. To prevent failures and avoid hazards effectively before the mule car is assembled, and reduce the time spent on system debugging. This study also proposes a validation process for the control strategy embedded in PHEVs. The strategy can be continuously verified if it fulfills the system requirements during the early phase of automotive development. At first, implement model-in-the-loop simulation with ASM vehicle dynamics model on offline PC. To certify whether the strategy meet the functional requirements, and burn it to hybrid control unit (HCU). At last, set up the full-scale powertrain testbed, build the virtual vehicle model in AVL Inmotion, and communicate HCU with AVL PUMA system. Using hardware-in-the-loop simulation, to imitate real-life driving situations, analysis the actual feedback of the powertrain system, and validate effectiveness of the control strategy. In this way, most of the failures and hazards can be eliminated before the mule car is assembled. In order to confirm the completeness of the developed control strategy.