Abstract: A method of controlling a mobility device and related device including at least one drive component that drives at least one joint component is described. The control method may include executing a control application with an electronic controller to perform: receiving sensor information from sensors corresponding to a state and/or mode of the mobility device; analyzing the sensor information and determining a control mode of operation based on the sensor information; generating a control signal to output an alert via electronic indicators corresponding to the determined control mode; and controlling at least one drive component of the mobility device to selectively configure and modulate at least one joint component in accordance with the determined control mode of operation. Different alerts may be outputted by the electronic indicators depending on the nature or severity of the alert condition, accompanied by respective device control operations in accordance with the alert condition.

Abstract: A method of controlling a mobility device and related device including at least one drive component that drives at least one joint component is described. The control method may include executing a control application with an electronic controller to perform: receiving sensor information from sensors corresponding to a state and/or mode of the mobility device; analyzing the sensor information and determining a control mode of operation based on the sensor information; generating a control signal to output an alert via electronic indicators corresponding to the determined control mode; and controlling at least one drive component of the mobility device to selectively configure and modulate at least one joint component in accordance with the determined control mode of operation. Different alerts may be outputted by the electronic indicators depending on the nature or severity of the alert condition, accompanied by respective device control operations in accordance with the alert condition.

Abstract: A method of controlling a mobility device including at least one drive component that drives at least one joint component is described. The control may include providing said mobility device, providing an electronic communication device having a control application to be executed by the electronic control device, receiving an input of settings information to the electronic communication device, the settings information being stored by the control application, electronically connecting the electronic communication device to the mobility device, and executing the control application with the electronic communication device to perform a session of using the mobility device. The electronic communication device executes the control application to control the at least one drive component of the mobility device to selectively configure and modulate the at least one joint component in accordance with the settings information.

Abstract: A method of controlling an exoskeleton device of a user performs fall mitigation operations. The control method may be performed by executing program code stored on a non-transitory computer readable medium. The exoskeleton device may be a powered legged mobility device including a plurality of drive components that drive joint components including at least knee joint components and hip joint components. The control method includes detecting a fall state including a direction and an extent of a fall; classifying the fall state based on the direction and the extent of the fall; and controlling the drive components of the exoskeleton device to selectively modulate one or more joint components in accordance with the fall classification to perform a fall mitigation operation. The control method further may include controlling the drive components to perform a recovery operation to aid the user in returning to standing position after the fall.

Abstract: A jointed mechanical device is provided. The device includes at least one element (204) having a fixed end and a deflectable end. The device also includes at least one actuating structure (206) having a first end coupled to at least the deflectable end of the element, where the actuating structure includes at least one elastic element (214) in series with at least one non-elastic element. The device further includes at least one force actuator (202) configured to apply an actuator force to a second end of the actuating structure. Additionally, the device includes a control system (315) for adjusting an operation of the force actuator based at least one actuation input, an amount of the actuator force, and an amount of displacement generated by the force actuator.

Abstract: Systems and methods for controlling jointed mechanical devices are is provided, where the device is controlled based on a topographic state (300) map having one or more motion axes (D1, D2) and defining a plurality of poses and a plurality of transitions in parallel with one of the motion axes, In the map, each motion axis is associated with complementary types of motion in the device and each of the transitions associated with at least two of the poses. A method includes the steps of receiving a control signal and determining a mechanical state of the device within the topographic state map. The method further includes identifying potential transitions associated with the mechanical state based on the topographic state map. The method also includes adjusting the mechanical state based on the control signal if the control signal is associated with a type of motion associated with one of the identified transitions.

Abstract: A jointed mechanical device is provided. The device includes at least one element (204) having a fixed end and a deflectable end. The device also includes at least one actuating structure (206) having a first end coupled to at least the deflectable end of the element, where the actuating structure includes at least one elastic element (214) in series with at least one non-elastic element. The device further includes at least one force actuator (202) configured to apply an actuator force to a second end of the actuating structure. Additionally, the device includes a control system (315) for adjusting an operation of the force actuator based at least one actuation input, an amount of the actuator force, and an amount of displacement generated by the force actuator.

Abstract: Systems and methods for controlling jointed mechanical devices are is provided, where the device is controlled based on a topographic state (300) map having one or more motion axes (D1, D2) and defining a plurality of poses and a plurality of transitions in parallel with one of the motion axes, In the map, each motion axis is associated with complementary types of motion in the device and each of the transitions associated with at least two of the poses. A method includes the steps of receiving a control signal and determining a mechanical state of the device within the topographic state map. The method further includes identifying potential transitions associated with the mechanical state based on the topographic state map. The method also includes adjusting the mechanical state based on the control signal if the control signal is associated with a type of motion associated with one of the identified transitions.