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I am interested in how to increase the accuracy of the model and how to know where the model is accurate.

I have also tried gaussian process regression and KNeighborsRegressor but so far have been unable to get it to work for this problem.

I am working on building a surrogate model for a PDE solver. The PDE solver outputs some data and then I calculate some metrics based on that data. There are about 2-6 parameters that I want to model along with 4-10 outputs. (There are many other parameters but they are fixed so I am not modeling them)

All my data is generated with no noise at all and running the same input will produce identical output. I normally run a genetic algorithm over the simulator and then run MCMC on it later to get parameter confidence. The problem is that this is really slow since the simulator has to be run so many times (millions) and I would like to call the neural network instead in areas where I can be confident of its output.

As it stands right now my network is about 35% (absolute error < 0.01 with outputs running from 0.0 to 1.0) accurate based on using the first 4% (8K rows) of the data and predicting the other 96% (140K rows).

This is my current model design

layers = 10, neurons = 30, virtual_batch_size = 64, bach_size = 8192, optimizer = 'Adam'

def get_model(settings):
    with tf.device('/gpu:0'):
        inputs = tf.keras.Input(shape=(settings.input_dim,))
        outputs = []
        for dim in range(settings.output_dim):
            for layer in range(settings.layers):
                dense = tf.keras.layers.Dense(settings.neurons, 
                    kernel_regularizer=tf.keras.regularizers.l2(0.001), 
                    kernel_initializer='he_normal')

                if layer == 0:
                    x = dense(inputs)
                else:
                    x = dense(x)
                x = tf.keras.layers.PReLU()(x)
                if layer < (settings.layers - 1):
                    x = tf.layers.BatchNormalization(virtual_batch_size=settings.virtual_batch_size)(x)

                outputs.append(tf.keras.layers.Dense(1, activation='linear', 
                    kernel_initializer='he_normal')(x))

        outputs = tf.keras.layers.concatenate(outputs, axis=1)
        model = tf.keras.Model(inputs=inputs, outputs=outputs)
        model.compile(loss='mse',
            optimizer=settings.optimizer,
            metrics=['mse', 'mae'])
        return model

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