Abstract: Functional electrical stimulation (FES) cycling devices and associated methods are generally described. An FES cycling device may comprise a crank, two or more pedals connected to the crank, one or more sensors adapted to measure position and/or velocity of the crank, and one or more electrodes configured to deliver electrical stimulation to a person associated with the cycling device. In some cases, the FES cycling device further comprises a controller configured to receive input signals from the one or more sensors and deliver output signals to the one or more electrodes. In certain cases, the controller may dynamically generate a control signal to deliver an amount of electrical stimulation to a muscle group (e.g., quadriceps femoris, gluteal muscles, hamstring muscles) based on the value of a determined torque transfer ratio between a joint of the person and the crank of the cycling device. The electrical stimulation may, in some cases, cause the person to pedal the cycling device.

Abstract: Hybrid orthotic devices configured to apply electrical stimulation to one or more body parts of a person are generally described. A hybrid orthotic device may comprise one or more sensors, one or more electrodes, and a controller configured to receive input signals from the one or more sensors and deliver output signals to the one or more electrodes. In certain cases, the controller may be configured to store one or more programs associated with functional activities (e.g., standing, sitting, and/or walking), and the programs may be configured to enable one or more body parts of the person to track a desired trajectory. In some embodiments, a program may implement a Robust Integral of the Sign of the Error (RISE) control method. The program may further implement control methods to compensate for electromechanical delay and/or muscle fatigue. In certain embodiments, a program may further implement neural network (NN)-based methods.

Abstract: Functional electrical stimulation (FES) cycling devices and associated methods are generally described. An FES cycling device may comprise a crank, two or more pedals connected to the crank, one or more sensors adapted to measure position and/or velocity of the crank, and one or more electrodes configured to deliver electrical stimulation to a person associated with the cycling device. In some cases, the FES cycling device further comprises a controller configured to receive input signals from the one or more sensors and deliver output signals to the one or more electrodes. In certain cases, the controller may dynamically generate a control signal to deliver an amount of electrical stimulation to a muscle group (e.g., quadriceps femoris, gluteal muscles, hamstring muscles) based on the value of a determined torque transfer ratio between a joint of the person and the crank of the cycling device. The electrical stimulation may, in some cases, cause the person to pedal the cycling device.

Abstract: Hybrid orthotic devices configured to apply electrical stimulation to one or more body parts of a person are generally described. A hybrid orthotic device may comprise one or more sensors, one or more electrodes, and a controller configured to receive input signals from the one or more sensors and deliver output signals to the one or more electrodes. In certain cases, the controller may be configured to store one or more programs associated with functional activities (e.g., standing, sitting, and/or walking), and the programs may be configured to enable one or more body parts of the person to track a desired trajectory. In some embodiments, a program may implement a Robust Integral of the Sign of the Error (RISE) control method. The program may further implement control methods to compensate for electromechanical delay and/or muscle fatigue. In certain embodiments, a program may further implement neural network (NN)-based methods.