Faced with the current environmental crisis, developing technologies with less negative impact and promoting energy efficiency actions are essential to reconcile productivity and emissions reduction. In this context, the study of internal combustion engines by modeling their operation presents itself as a very interesting tool, whether by bench tests or modeling. The present work aimed to develop models using different architectures of Artificial Neural Networks (ANNs) to obtain performance parameters of Internal Combustion Engines powered by natural gas and blends of diesel – biodiesel – ethanol. For the first case, 5 engines were considered to evaluate the thermal efficiency, specific consumption, exhaust temperature, and for the second case, the database includes an engine, on which, in addition to the mentioned parameters, the compression and expansion polytropic coefficients were evaluated, the specific consumption of ethanol, the maximum rate of heat release and the maximum pressure. For the networks that presented better results, response surfaces were made in order to analyze the models from the perspective of the phenomenon they represent. It was possible to obtain models with good representation of the mentioned parameters (obtaining R2 values above 70 percent for training and test data), except for the two polytropic coefficients. In this case, although the errors were relatively satisfactory, the response surfaces reached extremes that do not agree with the related theory. On the other hand, it was possible to build a model for thermal efficiency from consumption and throttle, with R2 of 99 percent for training and testing. This is explained by the fact that the first input variable is part of the equation that calculates this parameter, and the second is linked to the air-fuel ratio of the mixture.