Different aspects of fraction understanding are associated selectively with performance on a fraction learning game.

Fraction understanding seems a double-edged sword. On the one hand, it is an important predictor of later mathematical achievement. On the other hand, it is also one of the topics students struggle most in secondary math education. To complement traditional instruction, digital learning games were developed and found to successfully foster fraction understanding. However, so far, it is not known to what degree different aspects of fraction understanding (e.g., part-whole relations, fraction magnitude, fraction arithmetic) may be conveyed by such games. The current study evaluated selective associations of in-game performance of the fraction learning game Semideus with specific aspects of fraction understanding assessed using a comprehensive paper-pencil test. In Semideus, seventh graders (Mage=12.3years) from academic track secondary schools in Germany estimated the location of fractions on a number line and compared fractions according to their magnitude. Results replicated previous findings showing that in-game performance was significantly associated with mathematics achievement (i.e., math grades) and basic, whole number arithmetic skills. Moreover, we observed significant associations for aspects of fraction understanding closely matching mechanics of the learning game such as fraction number line estimation, fraction magnitude comparison and fraction ordering. These associations were observed for accuracy on the game's fraction learning tasks (e.g., estimation accuracy on the number line) but also generalized to game-based metrics such as virtual incentives (i.e., stars awarded in the game). This implies that the actual game mechanic may help to convey aspects of fraction understanding, substantiating ideas of intrinsic integration in game design.

Neurofunctional plasticity in fraction learning: An fMRI training study.

BACKGROUND: Fractions are known to be difficult for children and adults. Behavioral studies suggest that magnitude processing of fractions can be improved via number line estimation (NLE) trainings, but little is known about the neural correlates of fraction learning. METHOD: To examine the neuro-cognitive foundations of fraction learning, behavioral performance and neural correlates were measured before and after a five-day NLE training. RESULTS: In all evaluation tasks behavioral performance increased after training. We observed a fronto-parietal network associated with number magnitude processing to be recruited in all tasks as indicated by a numerical distance effect. For symbolic fractions, the distance effect on intraparietal activation was only observed after training. CONCLUSION: The absence of a distance effect of symbolic fractions before the training could indicate an initially less automatic access to their overall magnitude. NLE training facilitates processing of overall fraction magnitude as indicated by the distance effect in neural activation.