A disarticulated compression socket configured to secure a residual limb. The disarticulated compression socket may include a rigid socket frame having one or more compression apertures each having one or more disarticulated compression inserts. Each disarticulated compression insert may be coupled with and/or responsive to a compression band configured to compress the disarticulated compression inserts and thereby secure a residual limb within the rigid socket frame.

A prosthesis socket having a proximal insertion opening and an inner circumference which at least partially surrounds a limb stump, at least one connection device for a prosthesis component, which is connectable to the prosthesis socket, at least one actuator, by means of which the inner circumference of the prosthesis socket is changeable, and at least one sensor coupled to a control device, wherein the control device is connected to the actuator and activates or deactivates same, depending on the received sensor signals, and to a method for adjusting the inner circumference.

Embodiments of the invention provide for a prosthesis guided training system that includes a plurality of sensors for detecting electromyographic activity. A computing device, which can include a processor and memory, can extract data from the electromyographic activity. A real-time pattern recognition control algorithm and an autoconfiguring pattern recognition training algorithm can be stored in the memory. The computing device can determine movement of a prosthesis based on the execution of the real-time pattern recognition control algorithm. The computing device can also alter operational parameters of the real-time pattern recognition control algorithm based on execution of the autoconfiguring pattern recognition training algorithm.

A prosthetic ankle and foot combination has an ankle joint mechanism constructed to allow damped rotational movement of a foot component relative to a shin component. The mechanism provides a continuous hydraulically damped range of ankle motion during walking with dynamically variable damping resistances, and with independent variation of damping resistances in the plantar-flexion and dorsi-flexion directions. An electronic control system coupled to the ankle joint mechanism includes at least one sensor for generating signals indicative of a kinetic or kinematic parameter of locomotion, the mechanism and the control system being arranged such that the damping resistances effective over the range of motion of the ankle are adapted automatically in response to such signals. Single and dual piston hydraulic damping arrangements are disclosed, including arrangements allowing independent heel-height adjustment.

The invention relates to a prosthesis to replace a missing extremity of a living being, which has: one or more prosthetic links driven by actuators, first sensors, which sense a current state ZUS(t) of the prosthesis; an interface to second sensors, which sense biosignals SIG.sub.BIO(t) of the living being to control the missing extremity; third sensors for sensing data D.sub.UMG(t), which describe a current environment of the prosthesis; a prediction unit, which determines, based on the biosignals SIG.sub.BIO(t) and on the state ZUS(t) of the prosthesis and of the data D.sub.UMG(t), a model MA(t) of an action A to be executed with the prosthesis and predicts motions Beweg(M.sub.A(t)), dependent on the model M.sub.A(t), of the prosthetic links for a period of time [t, t+t]; an evaluating unit, by which the discrete decision E to replace the action A with another action A(E) can be determined on the basis of an evaluation of the biosignals SIGBIO(t), of the state ZUS(t), of the data D.sub.UMG(t), and of the predicted motions B.sub.eweg(M.sub.A(t)) in accordance with a specified evaluation scheme, wherein the action A(E) can define a reflexive motion and/or protective motion of the prosthesis that is autonomously controlled in an open-loop/closed-loop manner, and wherein, if the action A(E) does not define such a reflexive motion and/or protective motion of the prosthesis that is autonomously controlled in an open-loop/closed-loop manner, the prediction unit determines a model M.sub.A(t) of the action A to be performed by the prosthesis and predicts motions B.sub.eweg(M.sub.A(t)), dependent on the model M.sub.A(t), of the prosthetic links for a time period [t, t+t]; and a control unit, which derives control signals Sig(t), based on the currently valid, predicted motions B.sub.eweg(M.sub.A(t)) or B.sub.eweg(M.sub.A(t)) or based on the reflexive and/or protective motion autonomously controlled in an open-loop/closed-loop manner, for controlling the actuators and controls/regulates the actuators based on the control signals Sig(t).

The present invention discloses a system and method for motion recognition and control of a prosthetic device. The system of the present invention uses a movement detector for detecting dimensional motion of a non-disabled physical appendage and generating motion information based on this detecting. The system further includes a microcontroller adapted to be connected to the movement detector for receiving and processing the motion information transmitted from the one or more movement detectors. The system controls a prosthetic device which has actuators that are configured to actuate motion of the prosthetic device based on the processing of the motion information.

The present invention relates to a prosthesis for an arm or a leg, comprising a flexible sleeve for receiving a residual limb, a constrictor on the flexible sleeve for tightening the sleeve around the residual limb, and a rigid mount secured to the sleeve and spaced axially along the sleeve from the constrictor for mounting a tool. A sensor is provided in the mount to measure a physical parameter associated with the function performed by the tool. The prosthesis further comprises an actuator connected to the constrictor and a control circuit acting on the actuator to vary the force tightening the sleeve around the residual limb in dependence upon the measured parameter.

Disclosed is a method of controlling a prosthetic device. The method includes acquiring electromyographic (EMG) signals from one or more active electrodes configured to be in physical contact with a user, analyzing the acquired electromyographic (EMG) signals to determine the intent of the user and measuring one or more positional covariates associated with the user's residual limb. The method further includes controlling the prosthetic device in proportional response to the determined intent, wherein signal variations caused due to the positional covariates are compensated and providing multi-point sensory feedback to the user in response to the dynamics of the device, wherein the sensory feedback is provided via a wearable device that can be donned on or off by the user.

Various aspects of the present disclosure characterize apparatuses and/or methods as may be implemented with a variety of prosthetic components and applications. As may be consistent with one or more embodiments described herein, movement parameters pertaining to movement of a user of a prosthetic foot are sensed as the user travels along a surface, with the prosthetic foot having a front ball region and a rear heel region for respectively contacting the surface. A state of movement of the user, including a speed at which the user is travelling along the surface, is determined based on the sensed movement parameters. Utilizing a mechanical actuator, the prosthetic foot is dynamically positioned in response to the speed at which the user is travelling along the surface, by manipulating the mechanical actuator to move the rear heel region relative to the front ball region based on changes in the speed.

A prosthesis with controlled linear motion and methods for adapting the device to multiple amputation points are described. The device is designed to shorten during the swing phase to prevent striking the surface of the ground, and extend at the beginning and end of the swing to provide forward propulsion and begin to transfer bodyweight load from the opposing leg. The prosthesis includes an actuator to provide linear motion, a battery, sensors, and a controller.