Recently, due to my current occupation, I have been using the Machine Learning for the Electrical Impedance Tomography(EIT) problem. The introduction of EIT is in this link: https://en.wikipedia.org/wiki/Electrical_impedance_tomography. In short, the EIT have two problems: the forward problem and the inverse problem. Suppose we have an square of metal with defect and 4 electrodes on each sides, and from FEM we have 324 meshes.
The forward problem is that we have the conductivity distribution of the metal, and from the FEM we can know the voltage distribution between each element. The inverse problem is that we have the distribution of voltage, and calculate the conductivity. But the inverse problem is an ill-posed problem so we need many iteration of forward problem with using Gauss-Newton method to access the value of conductivity. Thus, the inverse problem is extremely time-consuming.
The aim of using Machine Learning is want to find a direct way to solve the inverse problem with a large number of data, including the voltage and conductivity.
In my previous working, the input data is voltage. And because we need the current injection between two electrodes, so the voltage we can acquire in one injection is 16-4 = 12, and iteration in 16 electrodes, the input dimension will be 12x16=192. And the output is conductivity of each mesh, and the dimension of the output is 324.
I have used the Neural networks to do this work. The training cases number is 700, and testing cases number is 300. Using Keras to build my MLP network, 'relu' as my activation function, 'Adam' as my optimizer, 4 hidden layers with dimension of 1x128. However, the training result is really terrible. The accuracy is ZERO. The value of voltage and conductivity are attached as .csv file. Many paper indicates that using neural network in the EIT is practical, and they acquire some beautiful results, such as the following paper:
Rymarczyk, Tomasz, Grzegorz Kłosowski, and Edward Kozłowski. "A Non-Destructive System Based on Electrical Tomography and Machine Learning to Analyze the Moisture of Buildings." Sensors 18.7 (2018): 2285.
And in that case, I think maybe the data have problem. I have generated the data in a matlab code, which the value is correct. I change the same position of mesh's conductivity value with step length of 0.001, from 0 to 1, and get the voltage value in scale of 10^-4 (V). Thus I have 1000 cases of data, after the process of L2 normalization, they are divided into 700 cases of training data and 300 cases of testing data, randomly. But whatever I try, the accuracy is ZERO, and the loss is 0.0027513225567511643 for the conductivity. So I want to ask that, what method should I try to increase the accuracy? I'm really tortured with that problem in several weeks, and hope I can get some inspiration from yours.
p.s. This is my first time to post question in here, and I'm not sure if it is possible to post codes. So I have just describe my problem. If it is allowable, I could post my code to make the problem more specifically.