Add to ORKGHuman sensorimotor control exhibits remarkable speed and accuracy, as celebrated in Fitts' law for reaching. Much less studied is how this is possible despite being implemented by neurons and muscle components with severe speed-accuracy tradeoffs (SATs). Here we develop a theory that connects the SATs at the system and hardware levels, and use it to explain Fitts' law for reaching and related laws. These results show that diversity between hardware components can be exploited to achieve both fast and accurate control performance using slow or inaccurate hardware. Such “diversity sweet spots'' (DSSs) are ubiquitous in biology and technology, and explain why large heterogeneities exist in biological and technical components and how both engin...
© 2019 ACM. This is the author's version of the work. It is posted here by permission of ACM for you...
The modern view of the nervous system as layering distributed computation and communication for the ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
Human sensorimotor control exhibits remarkable speed and accuracy, as celebrated in Fitts' law for r...
Nervous systems sense, communicate, compute, and actuate movement using distributed components with ...
The tradeoff between speed and accuracy of human movements has been exploited from many different pe...
Fitts' law describes the fundamental trade-off between movement accuracy and speed: It states that t...
For decisions made under time pressure, effective decision making based on uncertain or ambiguous ev...
Fitts' Law describes the speed-accuracy trade-off of human movements, and it is an elegant strategy ...
In order to generate skilled and efficient actions, the motor system must find solutions to several ...
An intrinsic property of human motor behaviour is a trade-off between speed and accuracy. This is cl...
Fitts ’ law describes the fundamental trade-off between movement accuracy and speed: it states that ...
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...
This article describes two neural network modules that form part of an emerging theory of how adapti...
© 2019 ACM. This is the author's version of the work. It is posted here by permission of ACM for you...
The modern view of the nervous system as layering distributed computation and communication for the ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
Human sensorimotor control exhibits remarkable speed and accuracy, as celebrated in Fitts' law for r...
Nervous systems sense, communicate, compute, and actuate movement using distributed components with ...
The tradeoff between speed and accuracy of human movements has been exploited from many different pe...
Fitts' law describes the fundamental trade-off between movement accuracy and speed: It states that t...
For decisions made under time pressure, effective decision making based on uncertain or ambiguous ev...
Fitts' Law describes the speed-accuracy trade-off of human movements, and it is an elegant strategy ...
In order to generate skilled and efficient actions, the motor system must find solutions to several ...
An intrinsic property of human motor behaviour is a trade-off between speed and accuracy. This is cl...
Fitts ’ law describes the fundamental trade-off between movement accuracy and speed: it states that ...
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...
This article describes two neural network modules that form part of an emerging theory of how adapti...
© 2019 ACM. This is the author's version of the work. It is posted here by permission of ACM for you...
The modern view of the nervous system as layering distributed computation and communication for the ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...