Haptic feedback provides an eective means of transferring information through tactile stimulation. In this work we look into the use of tactors for haptic feedback in body-worn contexts where individuals are allowed to move around. In this context it is crucial to design low power systems that al- low the activation of multiple tactors at the same time with limited battery power. We investigate how to minimize tac- tor power consumption by tuning the characteristics of their excitatory signal and present an activation policy to maxi- mize the number of tactors that can be simultaneously pow- ered by a battery under a tight peak current constraint.The proposed optimizations reduce power consumption and al- low a much higher number of simultaneously active tactors. Furthermore, we provide a design strategy whereby design- ers can tune the maximum number of simultaneously allowed active tactors based on battery and system requirements.
Battery-Aware Power Management Techniques for Wearable Haptic Nodes / M. Rofouei; M.Sarrafzadeh; E. Farella; D. Brunelli; L. Benini. - ELETTRONICO. - (2010), pp. 1-5. (Intervento presentato al convegno The Fifth International Conference on Body Area Networks, BodyNets 2010 tenutosi a Corfu, Greece nel September 10-12, 2010).
Battery-Aware Power Management Techniques for Wearable Haptic Nodes
FARELLA, ELISABETTA;BRUNELLI, DAVIDE;BENINI, LUCA
2010
Abstract
Haptic feedback provides an eective means of transferring information through tactile stimulation. In this work we look into the use of tactors for haptic feedback in body-worn contexts where individuals are allowed to move around. In this context it is crucial to design low power systems that al- low the activation of multiple tactors at the same time with limited battery power. We investigate how to minimize tac- tor power consumption by tuning the characteristics of their excitatory signal and present an activation policy to maxi- mize the number of tactors that can be simultaneously pow- ered by a battery under a tight peak current constraint.The proposed optimizations reduce power consumption and al- low a much higher number of simultaneously active tactors. Furthermore, we provide a design strategy whereby design- ers can tune the maximum number of simultaneously allowed active tactors based on battery and system requirements.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
