Abstract: An exoskeleton system and associated components are described herein. The exoskeleton system assists a user in lifting and/or bending to perform various operations. Components of the exoskeleton system can include a force device, a release mechanism, and a leg differential system. The force device includes a gas spring and a compression spring to store and release energy to assist a user of the exoskeleton system, the force device having a smooth force profile with no initial loading. The release mechanism disengages and re-engages the force device when actuated by a user. The leg differential system enables walking while wearing the exoskeleton system and equally loads different force devices of the exoskeleton system when a user's legs are displaced relative to one another.

Abstract: An exoskeleton system and associated components are described herein. The exoskeleton system assists a user in lifting and/or bending to perform various operations. Components of the exoskeleton system can include a force device, a release mechanism, and a leg differential system. The force device includes a gas spring and a compression spring to store and release energy to assist a user of the exoskeleton system, the force device having a smooth force profile with no initial loading. The release mechanism disengages and re-engages the force device when actuated by a user. The leg differential system enables walking while wearing the exoskeleton system and equally loads different force devices of the exoskeleton system when a user's legs are displaced relative to one another.

Abstract: Orthopedic devices may include rigid members for coupling to portions of a limb that includes a joint, and a cable that couples to the rigid members and extends up to a powered element. The orthopedic devices are configured to produce beneficial forces using the rigid member and the cable, which beneficial forces are translated to the wearer. The orthopedic devices include control systems that generate control signals for controlling the powered element.

Abstract: Systems and methods for providing assistance with human motion, including hip and ankle motion, are disclosed. Sensor feedback is used to determine an appropriate profile for actuating a wearable robotic system to deliver desired joint motion assistance. Variations in user kinetics and kinematics, as well as construction, materials, and fit of the wearable robotic system, are considered in order to provide assistance tailored to the user and current activity.

Abstract: Systems and methods for providing assistance with human motion, including hip and ankle motion, are disclosed. Sensor feedback is used to determine an appropriate profile for actuating a wearable robotic system to deliver desired joint motion assistance. Variations in user kinetics and kinematics, as well as construction, materials, and fit of the wearable robotic system, are considered in order to provide assistance tailored to the user and current activity.

Abstract: Orthopedic devices are provided that include rigid members for coupling to portions of a limb that includes a joint, and a cable that couples to the rigid members and extends up to a powered element. The orthopedic devices are configured to produce beneficial forces using the rigid member and the cable, which beneficial forces are translated to the wearer. The orthopedic devices include control systems that generate control signals for controlling the powered element.

Abstract: A biologically inspired climbing device with toes and spines is provided. The device has toes capable of moving independently from each other. Each toe distinguishes a compliant linkage, which has non-compliant parts and compliant parts. Spines are distributed over each of the toes. The spines have a diameter that is less than or equal to a diameter of an asperity of a surface. The toes with spines could be arranged into one or more feet. The feet could then be organized in legs enabling the device to climb a surface in a gait pattern. The device uses low power and is quiet, leaves no traces or tracks behind, works well on smooth, rough, uneven, porous and dirty surfaces, and is able to carry and support its own body weight.

Abstract: A biologically inspired climbing device with toes and spines is provided. The device has toes capable of moving independently from each other. Each toe distinguishes a compliant linkage, which has non-compliant parts and compliant parts. Spines are distributed over each of the toes. The spines have a diameter that is less than or equal to a diameter of an asperity of a surface. The toes with spines could be arranged into one or more feet. The feet could then be organized in legs enabling the device to climb a surface in a gait pattern. The device uses low power and is quiet, leaves no traces or tracks behind, works well on smooth, rough, uneven, porous and dirty surfaces, and is able to carry and support its own body weight.

Abstract: An apparatus and method of calibrating a signal sourcing device having a plurality of signal sources to reduce errors between signals generated by the signal sources by categorizing the signal sources into groups based on the amount of error in the signal generated by the signal sources and selecting the signal sources from the groups in a manner which reduces the overall error in selecting signals. For example, the signal sourcing device may be a digital to analog converter having a plurality of current sources that output currents which may have an error. Such an improved digital to analog converter would categorize the current sources into groups based on the amount of error in the current generated by the current sources and selecting the current sources from the groups in a manner which reduces the overall error in selecting signals for the conversion process. The groups may include a center group that straddles the median current generated by the current sources.