A robot arm includes a wrist, an end effector, and an adjustable joint coupling the end effector to the wrist. The adjustable joint includes a member received in a socket. In one example, the member is a ball. In another example, the member is a tang. In both examples, an upper flange and a lower flange can be used to couple the wrist to a forearm.

In some embodiments, torque compensation in a clamping instrument includes control electronics obtaining an initial torque limit for the clamping instrument, adjusting the initial torque limit based on a temperature of a motor assembly used to operate the clamping instrument, and clamping the clamping instrument according to the adjusted torque limit. The adjusted torque limit corresponds to a maximum torque that may be applied by the clamping instrument to perform the clamping. In some embodiments, torque compensation in a stapling instrument includes control electronics obtaining an initial torque limit for the stapling instrument, adjusting the initial torque limit based on a number of times the stapling instrument has been fired, and firing the stapling instrument according to the adjusted torque limit. The adjusted torque limit corresponds to a maximum torque that may be applied by the stapling instrument to perform the firing.

A wrist joint, such as for a surgical instrument, may include a first disc, a second disc adjacent the first disc, a drive tendon connecting the first disc and the second disc. The first disc and the second disc may include respective opposing gear features that intermesh with one another. The first disc and the second disc may further include opposing load bearing surfaces. In response to tensioning the drive tendon, the first and second discs rotate relative to each other. The first and second discs may have a maximum rotational range of motion greater than about +/45 degrees relative to each other.

A collaborative robot motion gauge determines a motion of a collaborative robot and includes: a bar; a dextral metrology member disposed on the bar; a dextral motion coupler moveably disposed on the bar; a dextral displacement sensor disposed on the dextral metrology member in communication with the dextral motion coupler; a dextral arm coupler disposed on the dextral motion coupler and that: couples to a dextral arm of the collaborative robot to the dextral motion coupler; communicates motion of the dextral arm to the dextral displacement sensor; and moves the dextral motion coupler in response to motion of the dextral arm; a sinistral metrology member disposed on the bar at a sinistral position; a sinistral motion coupler; a sinistral displacement sensor in communication with the sinistral motion coupler; and a sinistral arm coupler that couples a sinistral arm to the sinistral motion coupler.

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 medical instrument may include multiple joint members and at least two pairs of tendons connected with the joint members and adapted to move at least one of the joint members relative to at least one other joint member. Each joint member may include a main structural body that may be a single piece and includes at least one convex contact surface. A main portion of each tendon contacts the medical instrument only on the convex contact surfaces.

A medical instrument may include multiple joint members and at least two pairs of tendons connected with the joint members and adapted to move at least one of the joint members relative to at least one other joint member. Each joint member may include a main structural body that may be a single piece and includes at least one convex contact surface. A main portion of each tendon contacts the medical instrument only on the convex contact surfaces.

A wrist joint, such as for a surgical instrument, may include a first disc, a second disc adjacent the first disc, and a drive tendon that extends through the first disc and the second disc. The first disc and the second disc may include respective opposing joint features that intermesh with one another. The first disc and the second disc may further include opposing load bearing surfaces separate from the joint features. The drive tendon may exert a force on at least one of the first and second discs to cause relative rotation between the first and second discs. The first and second discs may have a maximum rotational range of motion greater than about +/45 degrees relative to each other.

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 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.