Today I read a paper titled “Design of an Electro-Hydraulic System Using Neuro-Fuzzy Techniques”
The abstract is:
Increasing demands in performance and quality make drive systems fundamental parts in the progressive automation of industrial processes.
Their conventional models become inappropriate and have limited scope if one requires a precise and fast performance.
So, it is important to incorporate learning capabilities into drive systems in such a way that they improve their accuracy in realtime, becoming more autonomous agents with some degree of intelligence.
To investigate this challenge, this chapter presents the development of a learning control system that uses neuro-fuzzy techniques in the design of a tracking controller to an experimental electro-hydraulic actuator.
We begin the chapter by presenting the neuro-fuzzy modeling process of the actuator.
This part surveys the learning algorithm, describes the laboratorial system, and presents the modeling steps as the choice of actuator representative variables, the acquisition of training and testing data sets, and the acquisition of the neuro-fuzzy inverse-model of the actuator.
In the second part of the chapter, we use the extracted neuro-fuzzy model and its learning capabilities to design the actuator position controller based on the feedback-error-learning technique.
Through a set of experimental results, we show the generalization properties of the controller, its learning capability in actualizing in realtime the initial neuro-fuzzy inverse-model, and its compensation action improving the electro-hydraulics tracking performance.