Magnetic tracking systems have been widely investigated in biomedical engineering due to the transparency of the human body to static magnetic fields. We recently proposed a novel human-machine interface for prosthetic application, namely the myokinetic interface. This controls multi-articulated prostheses by tracking magnets implanted in the residual muscles of individuals with amputation. Previous studies in this area focused solely on the choice and tuning of the localization algorithm. Here, we addressed the role of the intrinsic properties of the sensors, by analysing their effects on the tracking accuracy and on the computation time of the localization algorithm, through experimentally-verified computer simulations. We observed that t...
Human movement is accomplished through muscle contraction, yet there does not exist a portable syste...
In a magnetic tracking system, the position and orientation of a coil is determined by its low frequ...
Myocontrol is the use of a human machine interface based on muscle signals in order to control a rob...
Magnetic tracking systems have been widely investigated in biomedical engineering due to the transpa...
We recently introduced the concept of a new human-machine interface (the myokinetic control interfac...
Objective: The quest for an intuitive and physiologically appropriate human-machine interface for th...
In this work, we focus on a blind localization strategy for the myokinetic interface, that is a nove...
Abstract Background and Objectives Magnetic tracking involves the use of magnetic sensors to localiz...
In an attempt to overcome the several limitations of currently available/investigated human-machine ...
Deprivation of a limb, mainly due to vascular problems or trauma, strongly affects the amputee’s qua...
Upper limb amputation deprives individuals of their innate ability to manipulate objects. Such disab...
We live in an era of wearable sensing, where our movement through the world can be continuously moni...
Human movement is accomplished through muscle contraction, yet there does not exist a portable syste...
In a magnetic tracking system, the position and orientation of a coil is determined by its low frequ...
Myocontrol is the use of a human machine interface based on muscle signals in order to control a rob...
Magnetic tracking systems have been widely investigated in biomedical engineering due to the transpa...
We recently introduced the concept of a new human-machine interface (the myokinetic control interfac...
Objective: The quest for an intuitive and physiologically appropriate human-machine interface for th...
In this work, we focus on a blind localization strategy for the myokinetic interface, that is a nove...
Abstract Background and Objectives Magnetic tracking involves the use of magnetic sensors to localiz...
In an attempt to overcome the several limitations of currently available/investigated human-machine ...
Deprivation of a limb, mainly due to vascular problems or trauma, strongly affects the amputee’s qua...
Upper limb amputation deprives individuals of their innate ability to manipulate objects. Such disab...
We live in an era of wearable sensing, where our movement through the world can be continuously moni...
Human movement is accomplished through muscle contraction, yet there does not exist a portable syste...
In a magnetic tracking system, the position and orientation of a coil is determined by its low frequ...
Myocontrol is the use of a human machine interface based on muscle signals in order to control a rob...