Performing that type of arithmetic allows you to use that information in models that don't explicitly consider nonlinear combinations of variables. Some classifiers attempt to find features that best explain/predict the training data and often the best feature may be nonlinear.
Using your data, suppose you wanted to predict whether a group of people will - on average - gain weight. And suppose the "correct" answer is that the group will gain weight if people in the group consume over an average of 3,000 calories per day. If your inputs are
group_calories, you will need to use both of those variables to make an accurate prediction. But if you also provide
group_avg_calories (which is just
group_size), you could just use that single feature to make the prediction. Even if the first two features added some additional information, if you were to feed those 3 features to a decision tree classifier, it would almost certainly pick
group_avg_calories as the root node and you would end up with a much simpler tree structure. There is also a downside to adding lots of arbitrary nonlinear combinations of features to your model, which is that it can add significantly to the classifier's training time.
With regard to
calories/10, it's not clear why you would do that specifically, but normalizing the input features can improve convergence rates for some classifiers (e.g., ANNs) and can also provide better performance for clustering algorithms because the input features will all be at the same scale (i.e., distances along different feature axes are comparable).