A muscle sleeve includes: a sleeve-formed fabric; a plurality of first actuating muscles disposed next to each other and in parallel with each other on a first side of the sleeve-formed fabric; a plurality of second actuating muscles disposed next to each other and in parallel with each other on a second side of the sleeve-formed fabric; a plurality of fasteners that secure ends of the first and second actuating muscles to the fabric; and a crimp secured to the fabric.

An approximation method and system are provided for more quickly controlling a prosthetic or other device by reducing computational processing time in a muscle model that can be used to control the prosthetic. For a given muscle, the approximation method can quickly compute polynomial structures for a muscle length and for each associated moment arms, which may be used to generate a torque for a joint position of a physics model. The physics model, in turn, produces a next joint position and velocity data for driving a prosthetic. The approximation method expands the polynomial structures as long as expansion is possible and sufficiently beneficial. The computations canbe performed quickly by expanding the polynomial structures in a way that constrains the muscle length polynomial to the moment arm polynomial structures, and vice versa.

A system and method for controlling a device, such as a virtual reality (VR) and/or a prosthetic limb are provided. A biomimetic controller of the system comprises a signal processor and a musculoskeletal model. The signal processor processes M biological signals received from a residual limb to transform the M biological signals into N activation signals, where M and N are integers and M is less than N. The musculoskeletal model transforms the N activation signals into intended motion signals. A prosthesis controller transforms the intended motion signals into three or more control signals that are outputted from an output port of the prosthesis controller. A controlled device receives the control signals and performs one or more tasks in accordance with the control signals.

In a biomimetic artificial muscle module, a biomimetic artificial muscle assembly having the biomimetic artificial muscle module, and a method of controlling the biomimetic artificial muscle module, the biomimetic artificial muscle module includes an operating part, an elastic part, a driving part, a locking part and first and second sensors. The operating part contracts or relaxes along a longitudinal direction. The elastic part is connected to a first end of the operating part, and behaves elastically behave according to an external force. The driving part is connected to a second end of the operating part, and drives the operating part to be contracted or relaxed. The locking part selectively blocks a length of the operating part from being changed. The first and second sensors respectively sense the elastic part and the operating part.

A shear force actuator is described, including: two substantially parallel first structural components disposed along a first axis; a plurality of substantially parallel second structural components disposed between and bridging the two first structural components; a plurality of joint sections each joining the second structural component with the first structural components at an oblique angle of between 0 and 90 degrees to define a plurality of cells, each capable of being connected with a fluid inflation or deflation source; an elastic surface covering the remaining surfaces of the cells in a fluid-tight manner, wherein at least one of the joint section, the first structural components, and the second structural components is elastic so that cell collapses upon removal of fluid from the cell to generate a linear force along the first axis.

An actuation system includes a virtual or computer-modeled portion that is coupled to a physical portion. The virtual portion is a computer model that models or otherwise simulates a function or action, such as a physiological function or action, including for example an action potential, a calcium transient, and/or a chemical reaction. The computer model may model or simulate a chemical action, a mechanical action (such as movement of a wing) or any other action. The virtual portion drives or controls one or more physical actuators, which can be sized on a microscopic scale, such as on a nanometer scale. The actuation system can be used as or part of an artificial anatomical structure or organ, such as an artificial heart.

An artificial muscle fiber includes an external fiber and an internal fiber. The external fiber includes a first linear array of actuators having protrusions directed in a first direction. The internal fiber includes a second linear array of actuators having protrusions directed in a second direction opposite to the first direction. Protrusions of the first linear array of actuators and protrusions of the second linear array of actuators are separated by a non-zero gap, and each actuator of the first linear array of actuators and the second linear array of actuators includes a soft magnetic material.

An actuator includes a base to which first and second fluid couplings are fixed, a rotation member rotatably supported by the base, and McKibben-type first and second artificial muscles wound around the rotation member. The first and second artificial muscles are arranged in an antagonistic manner. One ends of the first and second artificial muscles are fixed to the rotation member. The other ends of the first and second artificial muscles are respectively connected to the first and second fluid couplings.

A tendon-driven robotic gripper is disclosed for performing fingertip and enveloping grasps. One embodiment comprises two fingers, each with two links, and is actuated using a single active tendon. During unobstructed closing, the distal links remain parallel, creating exact fingertip grasps. Conversely, if the proximal links are stopped by contact with an object, the distal links start flexing, creating a stable enveloping grasp. The route of the active tendon and the parameters of the springs providing passive extension forces are optimized in order to achieve this behavior. An additional passive tendon is disclosed that may be used as a constraint preventing the gripper from entering undesirable parts of the joint workspace. A method for optimizing the dimensions of the links in order to achieve enveloping grasps of a large range of objects is disclosed and applied to a set of common household objects.

An acoustically stealthy, soft-bodied underwater propulsion system includes a central chord member and a series of successive muscle layers each having a skeletal mechanism and a set of actuators. Each skeletal mechanism includes a central vertebra, two or more actuator arms extending radially outward from the central vertebra and disposed axially symmetrically about the central chord member, and an actuator plate extending from a radially outward end of each actuator arm and oriented substantially transverse to the actuator arm. Each actuator is situated between an actuator plate from a first muscle layer of the series and a second muscle layer of the series.