Wearable and mobile devices, such as smartphones, smartwatches, wearable medical
devices, etc., have become an important part of our daily life. Most of these devices are …

Wireless sensor networks (WSNs) have aroused the conspectus attention of scholars due to
their extensive deployment in the emerging fields of the Internet of Things (IoT's) and self …

Evolutionary pressures have led humans to walk in a highly efficient manner that conserves
energy, making it difficult for exoskeletons to reduce the metabolic cost of walking. Despite …

Lower-limb wearable robotic devices can improve clinical gait and reduce energetic
demand in healthy populations. To help enable real-world use, we sought to examine how …

The harvesting of energy from human motion for portable and wearable electronic devices
has received considerable attention. This letter describes a lightweight macrofiber …

Generating electricity by a biomechanical energy harvester whose input energy is human
joint mechanical energy can reduce user requirements to carry backup batteries. In this …

Aim We analyzed the biomechanical response (joint angles, moments, and powers) to
running with added leg mass. These data may help guide the design of wearable locomotor …

Biomechanical energy harvesters are designed to generate electrical energy from human
locomotion (eg, walking) with minimal or no additional effort by the users. These harvesters …

Harvesting energy from human motions is a promising solution to the power issue for
wearable electronics. Recently, various energy harvesters were developed to capture the …

Researchers and engineers have developed exoskeletons capable of reducing the
energetic cost of walking by decreasing the force their users' muscles are required to …