A wire-driven manipulator including a driver, a first deforming section including a first distal member, a plurality of first guide members, and a plurality of first wires, and a second deforming section provided between the first deforming section and the driver with the second deforming section including a second distal member, a plurality of second guide members, and a plurality of second wires. The plurality of first wires are fixed to the first distal member, and at least one of the plurality of first wires is further fixed to the plurality of first guide members and other wires of the plurality of the first wires are slidable with respect to the plurality of first guide members. The plurality of second wires are fixed to the second distal member, and at least one of the plurality of second wires is further fixed to the plurality of second guide members and the other wires of the plurality of the first wires are slidable with respect to the plurality of second guide members. In addition, the length of the first deforming section is shorter than the length of the second deforming section.

Systems and methods for an actuation system including a plurality of single actuation units for modular control of a tendon-driven robotic mechanism are disclosed.

Methods of controlling a hyper redundant manipulator, the hyper redundant manipulator including: a plurality of sections comprising a first free end section and a second end section; and a base arranged to receive the plurality of sections in a coiled configuration, the base being coupled to the second end section of the plurality of sections, the method comprising: receiving a trajectory for movement of the plurality of sections; determining an error in position and/or orientation relative to the trajectory for one or more sections of the plurality of sections, the error being caused at least in part by the coiled configuration; and controlling movement of the one or more sections using the determined error to compensate for the error in position and/or orientation of the one or more sections.

Methods and systems are described for controlling movement and an applied force at the tip of the continuum robot that includes a plurality of independently controlled segments along its length. An estimated force at the tip of the continuum robot is determined based on measurements of loads and positions of each segment. A reference position command and a force command are received from a user interface. The reference position command indicates a desired movement for the distal end of the continuum robot and the force command indicates a desired force to be applied by the tip of the continuum robot to a tissue surface. The position of the continuum robot is adjusted to cause the tip of the continuum robot to apply the desired force to the tissue surface based on the estimated force at the tip of the continuum robot, the reference position command, and the force command.

Device coordinated robotic control technology is described. A network of robotic devices is established. An anthropomorphic motion is sensed from an operator. One or more signals are generated that are representative of at least a portion of the anthropomorphic motion. The one or more signals are converted into a collective set of commands to actuate the network of robotic devices. The collective set of commands is functionally equivalent to the anthropomorphic motion.

Methods and systems are described for controlling movement of a continuum robot that includes a plurality of independently controlled segments along the length of the continuum robot. The continuum robot is inserted into a cavity of unknown dimensions or shape. A plurality of forces acting upon the continuum robot by the surrounding cavity are estimated. A positioning command indicating a desired movement of the distal end of the continuum robot is received from a manipulator control. The desired movement is augmented based, at least in part, on the estimated plurality of forces acting on the continuum robot such that movement is restricted to within safe boundaries of the surrounding cavity. The positioning of the continuum robot is then adjusted based on the augmented desired movement.

In a wire-driven continuum robot, in accordance with a profile of a first bending angle regarding a bending angle of a follow-up bending section that corresponds to a forward movement of a continuum robot, and is set in accordance with an input first target bending angle of a distal bending section, a bending angle of the following-up bending section is controlled to reach the first target bending angle. Before a movement amount of a forward movement reaches a first movement amount, the control is performed as follows. More specifically, a profile of a second bending angle that is different from the profile of the first bending angle is set, and by a further forward movement of the continuum robot, a bending angle of the following-up bending section reaches the second target bending angle in accordance with the profile of the second bending angle.

A wire-driven manipulator including a driver, a first deforming section including a first distal member, a plurality of first guide members, and a plurality of first wires, and a second deforming section provided between the first deforming section and the driver with the second deforming section including a second distal member, a plurality of second guide members, and a plurality of second wires. The plurality of first wires are fixed to the first distal member, and at least one of the plurality of first wires is further fixed to the plurality of first guide members and other wires of the plurality of the first wires are slidable with respect to the plurality of first guide members. The plurality of second wires are fixed to the second distal member, and at least one of the plurality of second wires is further fixed to the plurality of second guide members and the other wires of the plurality of the first wires are slidable with respect to the plurality of second guide members. In addition, the length of the first deforming section is shorter than the length of the second deforming section.