2011: Benjamin Franklin Medal in Computer and Cognitive Science, Franklin Institute "for the development of the first large-scale computational theory of the process by which humans perceive, learn and reason, and its application to computer tutoring systems."
2016: Atkinson Prize from the National Academy of Sciences.
Anderson's research has used fMRI brain imaging to study how students learn with intelligent tutoring systems. Most of his studies have looked at neural processes of students while they are solving algebraic equations or proofs. Anderson and colleagues generated a cognitive model that predicted that while students were learning an algebra proof, neuroimages showed decreased activation in a lateral inferior prefrontal region and a predefined fusiform region. This decrease in activity showed an increased fluency in retrieving declarative information, as students required less activity in these regions to solve the problems.
Cognitive stages when solving mathematical problems
In a 2012 study, Anderson and Jon Fincham, a colleague at Carnegie Mellon, examined the cognitive stages participants engaged in when solving mathematical problems. These stages included encoding, planning, solving, and response. The study determined how much time participants spent in each problem solving stage when presented with a mathematical problem. Multi-voxel pattern recognition techniques and Hidden Markov models were used to determine participants' problem solving stages. The results of the study showed that the time spent in the planning stage was dependent on the novelty of the problem. The time spent in the solving stage was dependent on the amount of computation required for the particular problem. Lastly, the time spent in the response stage was dependent on the complexity of the response required by the problem.
Decomposition Hypothesis
In another study, Anderson and colleagues used a video game task to test the Decomposition Hypothesis, or the idea that a complex cognitive task can be broken down into a set of information processing components. The combination of these components remains the same across different tasks. The study used a cognitive model that predicted behavioral and activation patterns for specific regions in the brain. The predictions involved both tonic activation, which remained stable across brain regions during game play, and phasic activation, which was present only when there was resource competition. The study's results supported the Decomposition Hypothesis. Individual differences were also found in participants' learning gains, which indicated that learning a complex skill is dependent on cognitive capacity limits.
