Systems and methods are provided for supporting a head of a user, e.g., while the user inclines their head downward, leans forward, and the like, for extended periods of time. In an exemplary embodiment, a harness is provided that is configured to be worn on a body of a user, the harness including a shoulder harness configured to be worn over or around one or both shoulders of the user, and a head support. The head support may include a support bracket including a first end mounted to the harness, and a rest member coupled to a second end of the support bracket such that the rest member extends across a forehead of the user and/or at least partially around the user's head when the harness is worn for supporting the user's forehead.

A capacitive sensor for characterizing force or torque includes a first plurality of non-patterned conductive regions and a first plurality of patterned conductive regions, and a second plurality of non-patterned conductive regions and a second plurality of patterned conductive regions. The first and second pluralities of non-patterned conductive regions are facing and the first and second pluralities of patterned conductive regions are facing.

Various embodiments include a fastening unit for fastening a tendon to a system. The fastening unit comprises: a head with a first opening; a shaft with a second opening and an external thread; and a channel extending from the first opening along the head to the second opening at least partly along the shaft. The external thread and the channel in each case accommodate the tendon.

[Object] To provide a hybrid actuator attaining both driving force and responsiveness, capable of reducing inertia of a movable portion.

[Solution] A pneumatic air muscle has a cylinder (112) provided in a flexible member (100) forming a pneumatic artificial muscle. At the center of an upper lid element (109) of the cylinder, a through hole is opened, and an inner wire (103) of a Bowden cable passes through this through hole and is coupled by means of a spring (106) to a bottom portion of the cylinder. When the pneumatic artificial muscle contracts, the inner wire (103) and the pneumatic air muscle move together because of the stopper (105), and the contraction force is transmitted. In contrast, when the pneumatic air muscle extends, the stopper (105) is disengaged, while the tension of inner wire (103) is kept by the spring (106) to prevent slacking.

A control system for a continuum robot includes a kinematics calculation unit configured to calculate a length of a wire in a bendable portion. The kinematics calculation unit includes a wire length calculation unit configured to calculate, for each of a plurality of minute sections obtained by dividing the bendable portion in a longitudinal direction thereof, a length of the wire in the minute section based on a bending angle, a turning angle, and a torsional angle of the minute section, and an addition unit configured to add the lengths of the wire in the plurality of minute sections obtained by the wire length calculation unit to calculate the length of the wire in the bendable portion.

A robot hand includes: a first link; a first fixed pulley and a second fixed pulley, respectively provided at a proximal end pivot part of the first link and rotatable around a first axis; a second link, supported at an intermediate pivot part by the first link to be rotatable around a second axis; a lever link, supported by the proximal end pivot part of the first link to be rotatable around the first axis; a lever pulley, supported by the lever link; a hanging cable, hung on the first fixed pulley, the lever pulley, and the second fixed pulley; a conversion mechanism, connecting the lever link and the second link, and converting rotation of the lever link into rotation of the second link; and a second link driving mechanism, rotating the lever link around the first axis by pulling the hanging cable.

Disclosed is a transcranial magnetic stimulation treatment apparatus applicable to the technical field of medical devices, comprising a TMS coil, a support, a mechanical arm, a controller, and a positioning device. The positioning device detects the position of a human head and the TMS coil and sends positional information to the controller; the controller controls six driving mechanisms of the mechanical arm to rotate to a corresponding angle. Because the mechanical arm has six degrees of freedom, the TMS coil is capable of stimulating each cerebral region of the brain, and the positioning device is capable of detecting an accurate position of the human head, thereby controlling the mechanical arm to accurately position the TMS coil on the human head, and to reduce manual operation.

The present invention relates to a static compliance performance testing device applied to an industrial robot, comprising a loading direction adjusting component and a loading force adjusting component, wherein the force applying end of the loading direction adjusting component is connected with an end mechanical interface of the industrial robot, and is configured to adjust a force bearing direction of the end mechanical interface. The loading force adjusting component comprises a lever, a first-stage weight and a second-stage weight, the lever is provided with a fixing part and is rotatable around the fixing part, the force bearing end of the loading direction adjusting component is connected with the lever, the first-stage weight is suspended on the lever, the second-stage weight is suspended on the lever and is movable along the lever, the weight of the first-stage weight is larger than the weight of the second-stage weight.

A device to regulate tension of an actuation element for actuating movement of a surgical instrument includes an elastically deformable body configured to be coupled to the actuation element. The deformable body is configured to elastically deform in response to a state of slack occurring in the actuation element. As slack occurs in the actuation element, the deformable body is configured to divert a path of the actuation element to accommodate the slack so the path of the actuation element differs from an axis the actuation element follows prior to the actuation element developing slack. A force transmission mechanism for a teleoperated surgical instrument includes a chassis, an actuation input mechanism, an actuation element, and a tension regulator coupled to the actuation element to compensate for slack of the actuation element.

A self-aligning, self-drawing coupler for coupling body assemblies together improves usability of a wearable robotic device. A self-contained removable actuator cassette improves the ease of manufacture and of replacing parts in the field. A tensioning retention system designed for one handed operation makes donning and doffing a wearable robotic device easier. A two-stage attachment system increases the range of sizes a wearable robotic device will fit. A removable, integrated ankle-foot orthotic system makes donning and doffing a wearable robotic device easier. An infinitely adjustable, integrated ankle-foot orthotic system increases the range of sizes a wearable robotic device will fit. A manually-removable hip-wing attachment system makes field changes easier, and protecting such a system from inadvertent disengagement during operation increases safety.