This functional neuroimaging (fMRI) study examined the neural networks (spatial patterns of covarying neural activity) associated with the speed-accuracy tradeoff (SAT) in younger adults. The response signal method was used to systematically increase probe duration (125, 250, 500, 1000 and 2000 ms) in a nonverbal delayed-item recognition task. A covariance-based multivariate approach identified three networks that varied with probe duration--indicating that the SAT is driven by three distributed neural networks
For decisions made under time pressure, effective decision making based on uncertain or ambiguous ev...
Processing speed is an important construct in understanding cognition. This study was aimed to contr...
It has been suggested that differential neural activity in imaging studies is most informative if it...
People are able to trade off speed and accuracy when performing a task; that is, they can either foc...
Recent computational models and physiological studies suggest that simple, two-alternative forced-ch...
Several plausible theories of the neural implementation of speed/accuracy trade‐off (SAT), the pheno...
Optimal decision-making requires balancing fast but error-prone and more accurate but slower decisio...
When people make decisions quickly, accuracy suffers. Traditionally, speed-accuracy tradeoffs (SATs)...
Evolutionary pressures suggest that choices should be optimised to maximise rewards, by appropriatel...
Intelligent agents balance speed of responding with accuracy of deciding. Stochastic accumulator mod...
SummaryIntelligent agents balance speed of responding with accuracy of deciding. Stochastic accumula...
Everyone is familiar with the speed-accuracy trade-off (SAT). To make good choices, we need to balan...
The speed and accuracy of decision-making have a well-known trading relationship: hasty decisions ar...
The ability to dynamically and rapidly adjust task performance based on its outcome is fundamental t...
When people make decisions quickly, accuracy suffers. Traditionally, speed–accuracy tradeoffs (SATs)...
For decisions made under time pressure, effective decision making based on uncertain or ambiguous ev...
Processing speed is an important construct in understanding cognition. This study was aimed to contr...
It has been suggested that differential neural activity in imaging studies is most informative if it...
People are able to trade off speed and accuracy when performing a task; that is, they can either foc...
Recent computational models and physiological studies suggest that simple, two-alternative forced-ch...
Several plausible theories of the neural implementation of speed/accuracy trade‐off (SAT), the pheno...
Optimal decision-making requires balancing fast but error-prone and more accurate but slower decisio...
When people make decisions quickly, accuracy suffers. Traditionally, speed-accuracy tradeoffs (SATs)...
Evolutionary pressures suggest that choices should be optimised to maximise rewards, by appropriatel...
Intelligent agents balance speed of responding with accuracy of deciding. Stochastic accumulator mod...
SummaryIntelligent agents balance speed of responding with accuracy of deciding. Stochastic accumula...
Everyone is familiar with the speed-accuracy trade-off (SAT). To make good choices, we need to balan...
The speed and accuracy of decision-making have a well-known trading relationship: hasty decisions ar...
The ability to dynamically and rapidly adjust task performance based on its outcome is fundamental t...
When people make decisions quickly, accuracy suffers. Traditionally, speed–accuracy tradeoffs (SATs)...
For decisions made under time pressure, effective decision making based on uncertain or ambiguous ev...
Processing speed is an important construct in understanding cognition. This study was aimed to contr...
It has been suggested that differential neural activity in imaging studies is most informative if it...