Soft robots have the potential to significantly change the way that robots interact with the environment and with humans. However, accurately modeling soft robot dynamics in order to do model-based control is extremely time consuming and difficult. neural networks are a powerful tool for modeling systems with complex dynamics such as an inflatable robot link with antagonistic pneumatic actuation. Unfortunately it is also difficult to apply standard model-based control techniques using a neural net. In this work, we show that the gradients used within a neural net to relate system states and inputs to outputs can be used to formulate a linearized discrete state space representation of the system. Using the state space representation, model predictive control can be developed with a one degree of freedom soft robot to achieve position control within 2° of the commanded joint angle. Additionally, control using the model derived from the neural net has similar performance to control using a model derived from first principles that took significantly longer to develop. This shows the potential of combining empirical modeling approaches with model-based control for soft robots.