An assistive device for stair-climbing assistance includes a powered rail-sliding platform that assists its user through a unique human interface. The device provides powered assistance (a gentle pulling force) and protection (through a safety belt) to help users climb or descend stairs.

An assist device includes a first body-worn unit, second body-worn units, an actuator, a sensor, and a controller including a processing unit configured to obtain a command value for assist torque based on a detection result of the sensor and using correspondence information indicating a relation between a forward swing speed of a leg and a torque compensation value including first and second torque compensation values. The processing unit is configured to perform an adjustment process of changing the first torque compensation value based on the forward swing angle of at least one of right and left legs of a user, in a case where the processing unit obtains the command value.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for generating, using, or both, exosuit historical data. In some implementations, (i) sensor data generated by sensors of an exosuit worn by a user and (ii) control data indicating actions performed by or control signals generated by the exosuit based on the sensor data while worn by the user are received. The sensor data and the control data are added to a database that includes historical data describing use of the exosuit over time by the user. A control scheme of the exosuit is customized for the user by updating the one or more machine learning models or settings that govern the application of the one or more machine learning models. Forces provided by one or more actuators of the exosuit are controlled using the updated one or more machine learning models or the updated settings.

A mobility device configurable in a first walk configuration and a second stair-climb configuration, including a frame with movable front leg portions, a leg-actuation system connected to the front leg portions and a safety-control device mounted to the frame. The safety-control device includes a configuration selector, and a lever connected to the leg-actuation system and configured to actuate the cable actuation system so as to cause the first and second movable leg portions to move from a first position to a second position. The lever remains locked in a first lever position such that the lever cannot be moved unless the configuration selector is in a depressed position, thereby preventing inadvertent movement of the leg portion.

As an example, a walker includes a first leg pair, a second leg pair and a cross beam connecting the first and second leg pairs in a parallel, spaced apart relationship. Each leg pair includes a U-shaped tube defining a front leg and a rear leg. A front strut is telescopically movable within the front leg and extends outwardly therefrom. A rear strut is telescopically movable within the rear leg and extends outwardly therefrom. A mechanical linear actuator includes a rotating element adapted to rotate relative to at least one of the front leg or the rear leg. The rotating element includes an interface with a track on the respective strut relative to which the rotating element rotates, whereby rotational motion of the rotating element translates to corresponding linear motion of the strut.

The invention relates to the field of the footwear industry, namely footwear (5) with a sole (6) of variable dimensions. The proposed method of dimensional change of the footwear sole (6) and the footwear (5) include a sole (6) of variable dimensions, the height of which may increase or decrease or return to the initial position, depending on the position of the sole (6) in contact with the supporting surface. The method of changing the height of the sole (6) of the footwear (5) proposed according to the invention facilitates climbing uphill, stairs, downhill, cycling by creating an effect of upward acting escalator without jerking or an effect of downward acting escalator without jerking, respectively.

A powered device augments a joint function of a human during a gait cycle using a powered actuator that supplies an augmentation torque, an impedance, or both to a joint. A controller estimates terrain slope and modulates the augmentation torque and the impedance, according to a phase of the gait cycle and the estimated terrain slope to provide at least a biomimetic response. The controller may also modulate a joint equilibrium. Accordingly, the device is capable of normalizing or augmenting human biomechanical function, responsive to a wearer's activity, regardless of speed and terrain, and can be used, for example, as a knee orthosis, prosthesis, or exoskeleton.

A motion assistance apparatus includes a waist frame configured to support a waist of a user, and a proximal support configured to support a proximal part of the user. A pressure applied to a thigh of the user by the proximal support in a sitting state in which the user is sitting may be greater than a pressure applied to the thigh of the user by the proximal support in a standing state in which the user is standing upright.

A powered device augments a joint function of a human during a gait cycle using a powered actuator that supplies an augmentation torque, an impedance, or both to a joint. A controller estimates terrain slope and modulates the augmentation torque and the impedance according to a phase of the gait cycle and the estimated terrain slope to provide at least a biomimetic response. The controller may also modulate a joint equilibrium. Accordingly, the device is capable of normalizing or augmenting human biomechanical function, responsive to a wearer's activity, regardless of speed and terrain, and can be used, for example, as a knee orthosis, prosthesis, or exoskeleton.

An autonomous wearable leg device employs an array of sensors embedded along a support area, whereby a controller can generate a controlling command and send a controlling command to a prosthetic, orthotic, exoskeletal or wearable component to thereby control the prosthetic, orthotic, exoskeletal or wearable component. A method for controlling autonomous wearable device collects kinetic signals from an array of sensors embedded in a prosthetic, orthotic or exoskeletal component, wherein all values are extracted from at least one feature of the collected kinetic signals, which are applied to a controller that generates a controlling command that is sent to the prosthetic, orthotic exoskeletal component to thereby control the prosthetic, orthotic or exoskeletal component during a portion of a gait cycle.