Exemplary embodiments relate to user-assisted robotic control systems, user interfaces for remote control of robotic systems, vision systems in robotic control systems, and modular grippers for use by robotic systems. Systems, methods, apparatuses and computer-readable media instructions are disclosed for interactions with and control of robotic systems, in particular, pick and place systems using soft robotic actuators to grasp, move and release target objects.

Exemplary embodiments relate to user-assisted robotic control systems, user interfaces for remote control of robotic systems, vision systems in robotic control systems, and modular grippers for use by robotic systems. Systems, methods, apparatuses and computer-readable media instructions are disclosed for interactions with and control of robotic systems, in particular, pick and place systems using soft robotic actuators to grasp, move and release target objects.

A robot includes: a turning part rotated about a first axis; a first arm part rotatably connected to the turning part about a second axis perpendicular to the first axis; a second arm part rotatably connected to the first arm part about a third axis; a distal-end swing part rotatably connected to the second arm part about a fourth axis; actuators rotating the first arm part, the second arm part, and the distal-end swing part about the second to fourth axes, which are parallel to each other, respectively; and a cable for the actuators. The turning part, the first arm part, the second arm part, and the distal-end swing part are alternately arranged at one or the other side in the direction of the second axis. The cable is disposed along side surfaces at the one side. The actuators are disposed close to side surfaces at the other side.

Provided is a robot arm including an upper arm, a forearm installed at the distal end of the upper arm, a wrist element installed at the distal end of the forearm to be rotatable around an axis line and having a hollow part through which the axis line penetrates, a motor installed in the forearm and rotating the element around the axis line, and a mechanism transmitting rotation of the motor to the element while reducing speed of rotation. The motor includes a rotation center axis extending obliquely downward on the opposite side of the upper arm. The mechanism includes a hypoid gear set including an output hypoid gear fixed to the element coaxially with the axis line and an input hypoid gear, and a gear set including a gear wheel fixed to the input hypoid gear and a pinion fixed to the motor.

Medical instrument (60, 160, 260, 360) comprising at least one first, second and third joint member (71, 72, 73), at least two pairs of tendons (90, 190, 191, 192) connected with the same joint member and adapted to move said third member (73) with respect to said second member (72), pulling it; and wherein each of said joint member (71, 72, 73) comprises a main structural body comprising in a single piece one or more convex contact surfaces (40, 80, 86, 140, 180), all said convex contact surfaces (40, 80, 86, 140, 180) defining with their prolongations thereof at least partially a single convex volume for each joint member; and wherein the main portion of each tendon is in contact with said jointed device (70, 170, 270) only on said convex contact surfaces; and wherein at least two tendons of said at least two pairs of tendons (90, 190, 191, 192) are in contact with a same convex contact surface.

A programmable motion system is disclosed that includes a dynamic end effector system. The dynamic end effector system includes an end effector that is coupled via a dynamic coupling to the programmable motion system, wherein the dynamic coupling provides that at least a portion of the end effector may spin with respect to an other portion of the end effector.

A traveling robot includes a mobile unit, an arm and an electronic control unit. The electronic control unit is configured to set a target position to which the traveling robot intends to travel. The electronic control unit is configured to calculate a center of gravity of the traveling robot. The electronic control unit is configured to plan a motion of a movable part of the mobile unit and/or arm to the set target position. The electronic control unit is configured to, in the case where the traveling robot is close to the set target position, plan the motion of the movable part of the mobile unit and/or arm such that a limitation on a range of the center of gravity is relaxed as compared to a limitation on the range of the center of gravity in the case where the traveling robot is far from the set target position.

A gripping device for a robotic manipulation device that grips and attaches teat cups to an animal. The gripping device for each teat cup to be gripped and attached includes a holding member configured to releasably hold a teat cup, and a power member configured to move the holding member from a base position (p1) to a raised position (p2) in which the teat cup can be attached to a teat. The gripping device for each teat cup to be gripped and attached includes a movable cover portion movably arranged between a covering position, in which it covers the opening of the teat cup, and a non-covering position, in which the opening of the teat cup is exposed. When power member lifts the holding member from the base position to the raised position, the movable cover portion moves from the covering position to the non-covering position.

A robot includes a first arm unit and a second arm unit. The robot includes a first drive part provided within the first arm unit and rotating the first arm unit about a first axis, and a second drive part provided within the first arm unit and rotating the second arm unit about a second axis. At least one of the first drive part and the second drive part contains a piezoelectric body.

Methods, apparatus, and systems for operating a surgical system. In accordance with a method, a position of a surgical instrument is measured, the surgical instrument being included in a mechanical assembly having a plurality of joints and a first number of degrees of freedom, the position of the surgical instrument being measured for each of a second number of degrees of freedom of the surgical instrument. The method further includes estimating a position of each of the joints, where estimating the position of each joint includes applying the position measurements to at least one kinematic model of the mechanical assembly, the kinematic model having a third number of degrees of freedom greater than the first number of degrees of freedom. The method further includes controlling the mechanical assembly based on the estimated position of the joints.