Abstract
Conventional predictive Artificial Neural Networks (ANNs) commonly employ deterministic weight matrices; therefore, their prediction is a point estimate. Such a deterministic nature in ANNs causes the limitations of using ANNs for medical diagnosis, law problems, and portfolio management in which not only discovering the prediction but also the uncertainty of the prediction is essentially required. In order to address such a problem, we propose a predictive probabilistic neural network model, which corresponds to a different manner of using the generator in the conditional Generative Adversarial Network (cGAN) that has been routinely used for conditional sample generation. By reversing the input and output of ordinary cGAN, the model can be successfully used as a predictive model; moreover, the model is robust against noises since adversarial training is employed. In addition, to measure the uncertainty of predictions, we introduce the entropy and relative entropy for regression problems and classification problems, respectively. The proposed framework is applied to stock market data and an image classification task. As a result, the proposed framework shows superior estimation performance, especially on noisy data; moreover, it is demonstrated that the proposed framework can properly estimate the uncertainty of predictions.
Highlights
Conventional predictive Artificial Neural Network (ANN) models commonly operate with a feed-forward framework using deterministic weight matrices as the network weight parameters [1,2,3]
By reversing the input and output of ordinary conditional Generative Adversarial Network (cGAN), the model can be successfully used as a predictive model; the model is robust against noises since adversarial training is employed
We proposed a new framework to use the generator in cGAN as a predictive model while the existing cGAN is routinely employed for sample generation
Summary
Conventional predictive Artificial Neural Network (ANN) models commonly operate with a feed-forward framework using deterministic weight matrices as the network weight parameters [1,2,3]. While outstanding progress has been made in ANNs in recent years [4,5] and ANNs are widely used for many practical applications [6,7,8,9,10], conventional predictive ANN models have an obvious limitation since their estimation corresponds to a point estimate. The models attempt to make a confident prediction for an outlier or even complete noise data of which predictions are meaningless and impossible. In such a framework, it is not clear how much the models are sure on their predictions.
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