Abstract: A system configured for stabilizing or balancing objects in an upright state. The system includes a motion system with an upper support surface for receiving an object that is positionable in a vertical state. The system includes a sensor assembly with at least one sensor generating sensor data by tracking at least one of three dimensional (3D) position and angular movement for the object. The system includes a controller with a stabilizing module to process the sensor data to determine when the object is tipping from the vertical state, and, in response to the tipping away of the object from the vertical state, the stabilizing module generates control signals to modify operations of the motion system to move at least a portion of the upper support surface in contact with a lower contact surface of the object through stabilizing movements, whereby the object remains balanced in the vertical state.

Abstract: An embodiment provides a monopod jib for cameras, including: a pole; a multi-axis gimbal disposed at one end of the pole; and a user interface comprising: a first user interface element having a first plurality of camera controls; and a second user interface element having a second plurality of camera controls. Other embodiments are shown and described.

Abstract: Systems and corresponding control methods providing a ballistic robot that flies on a trajectory after being released (e.g., in non-powered flight as a ballistic body) from a launch mechanism. The ballistic robot is adapted to control its position and/or inflight movements by processing data from onboard and offboard sensors and by issuing well-timed control signals to one or more onboard actuators to achieve an inflight controlled motion. The actuators may move an appendage such as an arm or leg of the robot or may alter the configuration of one or more body links (e.g., to change from an untucked configuration to a tucked configuration), while other embodiments may trigger a drive mechanism of an inertia moving assembly to change/move the moment of inertia of the flying body. Inflight controlled movements are performed to achieve a desired or target pose and orientation of the robot during flight and upon landing.

Abstract: A modular floor with active tiles that utilize numerous friction or contact disks each with a raised segment or portion on their edges that together provide a planar contact surface for the active tile. Each disk is oriented at a fixed tilt angle to define which part of the disk's outer surfaces act as the raised portion, and each disk is oriented to position where the raised surface is located so as to define the direction that a supported object is moved over the modular floor. The drive system typically includes, for each disk assembly, a disk orienting mechanism along with a disk rotation mechanism to rotate the disk at a rotation rate about its central axis. The controller of the motion system operates the disk orienting mechanism to orient the disk so that a particular location on the disk behaves as the raised portion where an object is contacted.

Abstract: The apparatus of one embodiment of the present invention is comprised of a flexible sheath instrument, a flexible guide instrument, and a tool. The flexible sheath instrument comprises a first instrument base removably coupleable to an instrument driver and defines a sheath instrument working lumen. The flexible guide instrument comprises a second instrument base removably coupleable to the instrument driver and is threaded through the sheath instrument working lumen. The guide instrument also defines a guide instrument working lumen. The tool is threaded through the guide instrument working lumen. For this embodiment of the apparatus, the sheath instrument and guide instrument are independently controllable relative to each other.

Abstract: A system for providing a user of a virtual reality (VR) system with physical interactions with an object in the real world or in the surrounding physical space while they are concurrently interacting in the virtual world with a corresponding virtual object. The real world object is dynamic with the system including a physical interaction system that includes a robot with a manipulator for moving, positioning, and/or orienting the real world object so as to move it into contact with the user. For example, the physical object is moved into contact with a tracked body part of the user, such as a hand, a tracked contact surface on the user's body, and so on, at a time that is accurately synchronized with a time of an interaction event occurring in the virtual world being created by the VR system.

Abstract: A teleoperated system includes a master grip and a ratcheting system coupled to the master grip. The ratcheting system is configured to be coupled to a slave instrument. The ratcheting system is further configured to align the master grip with the slave instrument by determining a commanded angular velocity for the slave instrument based on a command from the master grip, determining a current alignment error between an alignment of the master grip and an alignment of the slave instrument, and altering the commanded angular velocity for the slave instrument based on the current alignment error. In some embodiments, the ratcheting system is further configured to introduce a control system error to alter the commanded angular velocity. In some embodiments, the current alignment error is a rotation angle error between the alignment of the master grip and the alignment of the slave instrument.

Abstract: A minimally-invasive surgical system includes a slave surgical instrument having a slave surgical instrument tip and a master grip. The slave surgical instrument tip has an alignment in a common frame of reference and the master grip, which is coupled to the slave surgical instrument, has an alignment in the common frame of reference. An alignment error, in the common frame of reference, is a difference in alignment between the alignment of the slave surgical instrument tip and the alignment of the master grip. A ratcheting system (i) coupled to the master grip to receive the alignment of the master grip and (ii) coupled to the slave surgical instrument, to control motion of the slave by continuously reducing the alignment error, as the master grip moves, without autonomous motion of the slave surgical instrument tip and without autonomous motion of the master grip.

Abstract: Systems and methods for performing robotically-assisted surgical procedures on a patient enable an image display device to provide an operator with auxiliary information related to the surgical procedure, in addition to providing an image of the surgical site itself. The systems and methods allow an operator to selectively access and reference auxiliary information on the image display device during the performance of a surgical procedure.

Abstract: Systems and methods for performing robotically-assisted surgical procedures on a patient enable an image display device to provide an operator with auxiliary information related to the surgical procedure, in addition to providing an image of the surgical site itself. The systems and methods allow an operator to selectively access and reference auxiliary information on the image display device during the performance of a surgical procedure.

Abstract: A robot configured to provide accurate control over the rate of spin or rotation of the robot. To control the rate of spin, the robot includes an inertia shifting (or moving) assembly positioned within the robot's body so that the robot can land on a surface with a target orientation and “stick the landing” of a gymnastic maneuver. The inertia shifting assembly includes sensors that allow the distance from the landing surface (or height) to be determined and that allow other parameters useful in controlling the robot to be calculated such as present orientation. In one embodiment, the sensors include an inertial measurement unit (IMU) and a laser range finder, and a controller processes their outputs to estimate orientation and angular velocity. The controller selects the right point of the flight to operate a drive mechanism in the inertia shifting assembly to achieve a targeted orientation.

Abstract: A system designed to provide a dynamic physical interaction for a user during a virtual reality (VR) experience in a VR experience space. The system includes a VR system having a headset with a display screen and a VR rendering module generating a video output, and the display screen displays an image of a virtual world using the video output. The system includes an object delivery system delivering a physical object into the VR experience space to move toward or near to the user wearing the headset. The system includes, in the VR system, an interaction module generating a predicted trajectory for the physical object in the VR experience space. The image of the virtual world includes a virtual object corresponding to the physical object, and the image of the virtual object follows a virtual object trajectory in the virtual world differing from the predicted trajectory for the physical object.

Abstract: A robot with an elastic, spherically-shaped body with controlled bouncing locomotion. This robot may be called “a robotic bouncing ball.” The robotic bouncing ball can be used to provide a new class of robotic characters that are ball-like, and these new robotic characters bounce in place and from one location to another. The spherical body will typically be formed with a thin wall of elastic material such as a rubber or the like, and a drive or actuator assembly along with a local controller and a power source are positioned in the interior space of the hollow body. The controller controls the drive assembly to cause the spherical body to bounce up and down vertically and to provide horizontal/lateral movement of the spherical body through the applications of deforming and/or reforming forces on the elastic outer wall.

Abstract: A modular floor with active tiles that utilize numerous friction or contact disks each with a raised segment or portion on their edges that together provide a planar contact surface for the active tile. Each disk is oriented at a fixed tilt angle to define which part of the disk's outer surfaces act as the raised portion, and each disk is oriented to position where the raised surface is located so as to define the direction that a supported object is moved over the modular floor. The drive system typically includes, for each disk assembly, a disk orienting mechanism along with a disk rotation mechanism to rotate the disk at a rotation rate about its central axis. The controller of the motion system operates the disk orienting mechanism to orient the disk so that a particular location on the disk behaves as the raised portion where an object is contacted.

Abstract: A multi-user medical robotic system for collaboration or training in minimally invasive surgical procedures includes first and second master input devices, a first slave robotic mechanism, and at least one processor configured to generate a first slave command for the first slave robotic mechanism by switchably using one or both of a first command indicative of manipulation of the first master input device by a first user and a second command indicative of manipulation of the second master input device by a second user. To facilitate the collaboration or training, both first and second users communicate with each other through an audio system and see the minimally invasive surgery site on first and second displays respectively viewable by the first and second users.

Abstract: Systems and methods for performing robotically-assisted surgical procedures on a patient enable an image display device to provide an operator with auxiliary information related to the surgical procedure, in addition to providing an image of the surgical site itself. The systems and methods allow an operator to selectively access and reference auxiliary information on the image display device during the performance of a surgical procedure.

Abstract: An embodiment provides a monopod jib for cameras, including: a pole; a multi-axis gimbal disposed at one end of the pole; and a user interface comprising: a first user interface element having a first plurality of camera controls; and a second user interface element having a second plurality of camera controls. Other embodiments are shown and described.

Abstract: Devices, systems, and methods for compensate for friction within powered automatic systems, particularly for telesurgery and other telepresence applications. Dynamic friction compensation may comprise applying a continuous load in the direction of movement of a joint, and static friction compensation may comprise applying alternating loads in positive and negative joint actuation directions whenever the joint velocity reading falls within a low velocity range.

Abstract: A minimally-invasive surgical system includes a slave surgical instrument having a slave surgical instrument tip and a master grip. The slave surgical instrument tip has an alignment in a common frame of reference and the master grip, which is coupled to the slave surgical instrument, has an alignment in the common frame of reference. An alignment error, in the common frame of reference, is a difference in alignment between the alignment of the slave surgical instrument tip and the alignment of the master grip. A ratcheting system (i) coupled to the master grip to receive the alignment of the master grip and (ii) coupled to the slave surgical instrument, to control motion of the slave by continuously reducing the alignment error, as the master grip moves, without autonomous motion of the slave surgical instrument tip and without autonomous motion of the master grip.

Abstract: A multi-user medical robotic system for collaboration or training in minimally invasive surgical procedures includes first and second master input devices, a first slave robotic mechanism, and at least one processor configured to generate a first slave command for the first slave robotic mechanism by switchably using one or both of a first command indicative of manipulation of the first master input device by a first user and a second command indicative of manipulation of the second master input device by a second user. To facilitate the collaboration or training, both first and second users communicate with each other through an audio system and see the minimally invasive surgery site on first and second displays respectively viewable by the first and second users.