In this research, we investigate a system identification method based on deep neural networks for nonlinear Model Predictive Control (MPC), focusing on efficiently managing massive multi-output systems. This method involves the direct synthesis of state estimators and output predictors represented by neural networks from experimental data. The integration of these components with the Levenberg-Marquardt optimization method, coupled with the use of automatic differentiation, enables efficient realization of nonlinear MPC.In this research, we propose a specific architecture for the state estimator and output predictor, designed to suit multi-output systems. This approach is applied to a miniature four-wheeled vehicle equipped with a 1D camera, which generates 160-pixel image outputs. The experimental application to this test vehicle demonstrates the method's capability in effectively managing complex, multi-output systems.