The analytical results for several models are given: a first order model where it is assumed that the hand velocity can be directly controlled, and a second order model where it is assumed that the hand acceleration can be directly controlled. Two different types of control-laws are investigated. One is linear function of the hand error and error rate; the other is the time-optimal control law. Results show that the first and second order models with the linear control-law produce a movement time (MT) function with the exact form of the Fitts' Law. The control-law interpretation implies that the effect of target width on MT must be a result of the vertical motion which elevates the hand from the starting point and drops it on the target at ...
Fitts ’ law is a well known empirically-based relation which predicts aimed-movement time (MT) from ...
International audienceThe lawful continuous linear relation between movement time and task difficult...
Fitts’ law predicts the human movement response time for a specific task through a simple linear for...
Fitts’ law is a well established empirical formula, known for encapsulating the “speed-accuracy trad...
Fitts' (1954) classic theorem asserts that the movement time (MT) of voluntary reaches is determined...
There are circumstances in which humans are required to move in environments wherein accuracy should...
Fitts' law is an empirical rule of thumb which predicts the time it takes people, under time pressur...
Recent technological developments have made viable a man-machine interface heavily dependent on grap...
Reaching to interact with an object requires a compromise between the speed of the limb movement and...
We tested a hypothesis that the classical relation between movement time and index of difficulty (ID...
International audienceBackground: The inverse relationship between movement speed and accuracy in go...
It is proposed that the speed of aiming movements is the optimized outcome of a stochastic, oscillat...
While movement is essential to human wellbeing, we are still unable to reproduce the deftness and ro...
A simulated automobile driving environment was used to assess the validity of Fitts' Law under dual-...
Abstract—Human motion models for reaching and pointing tasks are used by designers of software, cell...
Fitts ’ law is a well known empirically-based relation which predicts aimed-movement time (MT) from ...
International audienceThe lawful continuous linear relation between movement time and task difficult...
Fitts’ law predicts the human movement response time for a specific task through a simple linear for...
Fitts’ law is a well established empirical formula, known for encapsulating the “speed-accuracy trad...
Fitts' (1954) classic theorem asserts that the movement time (MT) of voluntary reaches is determined...
There are circumstances in which humans are required to move in environments wherein accuracy should...
Fitts' law is an empirical rule of thumb which predicts the time it takes people, under time pressur...
Recent technological developments have made viable a man-machine interface heavily dependent on grap...
Reaching to interact with an object requires a compromise between the speed of the limb movement and...
We tested a hypothesis that the classical relation between movement time and index of difficulty (ID...
International audienceBackground: The inverse relationship between movement speed and accuracy in go...
It is proposed that the speed of aiming movements is the optimized outcome of a stochastic, oscillat...
While movement is essential to human wellbeing, we are still unable to reproduce the deftness and ro...
A simulated automobile driving environment was used to assess the validity of Fitts' Law under dual-...
Abstract—Human motion models for reaching and pointing tasks are used by designers of software, cell...
Fitts ’ law is a well known empirically-based relation which predicts aimed-movement time (MT) from ...
International audienceThe lawful continuous linear relation between movement time and task difficult...
Fitts’ law predicts the human movement response time for a specific task through a simple linear for...