We have proposed a general framework to study the neural representation of uncertainty (and thus, of probability and confidence in particular). This framework distinguishes two methods that researchers currently use, one making strong assumptions about the neural code of our belief and the associated uncertainty, the other looking for correlations between uncertainty (reported by participants, or inferred based on some model) and neural activity. This work, published in Nature Neuroscience, stresses the pros and cons of each approach, and the benefit of combining them.
Regarding the role of confidence in the regulation of learning, we have demonstrated that human learning is mathematically sound. Notably, the learning dynamics depend on how informative each new observation is relatively to our current state of knowledge. In particular, learning increases when confidence about the current estimate is low. This effect was observed in the learning of magnitude (e.g. the size of an object) and even more of probability (e.g. of event occurring of not).
To explore the neural representation of probability and confidence, we have collected a high quality dataset in human participants using ultra high field functional magnetic resonance imaging (fMRI at 7 Tesla). With this dataset, we have identified the pieces of human cortex whose activity tracks confidence levels during learning. Using artificial neural networks, we have also demonstrated that networks that are trained to estimate probabilities accurately, automatically develop a representation of confidence that regulates their learning process. This result was observed even with very small networks, provided that they are equipped with specific elements of architecture that we identified. This result demonstrates that the estimation of confidence during learning is a biologically plausible process.
Last, in order to understand the biological mechanisms of the regulation of learning by confidence, we have started to test the possibility that noradrenaline, a neuromodulator of the brain, inversely follows confidence. Being released more when confidence is low, it would render neural networks more plastic and boost learning. We have devised special fMRI methods to measure the activity of the locus coeruleus, a small nucleus in the center of the brain that releases noradrenaline. We have validated our methods in a simple task, and collected data in a more complex learning task to test our hypothesis.