TY - BOOK ID - 136758034 TI - Toward a Unified View of the Speed-Accuracy Trade-Off: Behaviour, Neurophysiology and Modelling AU - Richard P. Heitz AU - Dominic Standage AU - Da-Hui Wang AU - Patrick Simen PY - 2016 PB - Frontiers Media SA DB - UniCat KW - Decision Making KW - Neural mechanisms of cognition KW - Speed-accuracy trade-off KW - decision neuroscience KW - bounded integration UR - https://www.unicat.be/uniCat?func=search&query=sysid:136758034 AB - Everyone is familiar with the speed-accuracy trade-off (SAT). To make good choices, we need to balance the conflicting demands of fast and accurate decision making. After all, hasty decisions often lead to poor choices, but accurate decisions may be useless if they take too long. This notion is intuitive because it reflects a fundamental aspect of cognition: not only do we deliberate over the evidence for decisions, but we can control that deliberative process. This control raises many questions for the study of choice behaviour and executive function. For example, how do we figure out the appropriate balance between speed and accuracy on a given task? How do we impose that balance on our decisions, and what is its neural basis? Researchers have addressed these and related questions for decades, using a variety of methods and offering answers at different levels of abstraction. Given this diverse methodology, our aim is to provide a unified view of the SAT. Extensive analysis of choice behaviour suggests that we make decisions by accumulating evidence until some criterion is reached. Thus, adjusting the criterion controls how long we accumulate evidence and therefore the speed and accuracy of decisions. This simple framework provides the platform for our unified view. In the pages that follow, leading experts in decision neuroscience consider the history of SAT research, strategies for determining the optimal balance between speed and accuracy, conditions under which this seemingly ubiquitous phenomenon breaks down, and the neural mechanisms that may implement the computations of our unifying framework. ER -