Abstract: A mobile surgical control console is provided and includes a base housing, a lower frame assembly, a plurality of vertical supports, a monitor, and an upper frame assembly. The lower frame assembly further includes a proximal end, a distal end and an opening defined therethrough which extends through the proximal end thereof. The lower frame assembly is coupled to the base housing. The plurality of vertical supports each have an inferior end and a superior end, and each vertical support is attached to the base housing. The monitor is attached to the superior end of each vertical support. The upper frame assembly includes an upper frame and a mobile section. The upper frame includes a proximal end, a distal end and an opening defined therethrough. The upper frame is supported on each vertical support. The mobile section is supported by the upper frame.

Abstract: A robotic cleaner includes a cleaning assembly for cleaning a surface and a main robot body. The main robot body houses a drive system to cause movement of the robotic cleaner and a microcontroller to control the movement of the robotic cleaner. The cleaning assembly is located in front of the drive system and a width of the cleaning assembly is greater than a width of the main robot body. A robotic cleaning system includes a main robot body and a plurality of cleaning assemblies for cleaning a surface. The main robot body houses a drive system to cause movement of the robotic cleaner and a microcontroller to control the movement of the robotic cleaner. The cleaning assembly is located in front of the drive system and each of the cleaning assemblies is detachable from the main robot body and each of the cleaning assemblies has a unique cleaning function.

Abstract: An articulated robot including a base, an arm supported so as to be rotatable about a predetermined axis with respect to the base and rotatable within a rotational angle range smaller than ±180°, and a hollow shaft that is disposed outside the rotational angle range and stands upward from the base to be parallel to the axis. A cable body is wired from the base to the arm through an inside of the shaft. The articulated robot includes a stopper embedded in a side surface of the shaft, the stopper against which a side surface of the arm rotated beyond the rotational angle range abuts.

Abstract: An Autonomous Vehicle (AV) system is described. The AV system is capable of determining at motor control command associated with an AV trajectory. The AV system includes a content generating device, a system controller, and an AV sensor. The content generating device collects target data associated with a target. The system controller is communicatively coupled to the content generating device. The system controller extracts target features from the target data. Also, the system controller compares the extracted target features to target model data to determine a target pose. Additionally, the system controller determines the AV trajectory by comparing the target pose with at least one target objective. The AV sensor determines an AV state. The system controller determines a motor control command associated with the AV trajectory based on the AV state, the target objective, and the AV trajectory.

Abstract: Provided is an autonomous coverage robot including: a chassis; a set of wheels; a plurality of sensors; and a mopping assembly including: a fluid reservoir for storing a cleaning fluid; a cloth for receiving the cleaning fluid, wherein the cloth is oriented toward a work surface; a means to move at least the cloth of the mopping assembly up and down in a plane perpendicular to the work surface, wherein the means to move at least the cloth of the mopping assembly up and down is controlled automatically based on input provided by at least one of the plurality of sensors; and a means to move at least a portion of the mopping assembly back and forth in a plane parallel to the work surface.

Abstract: According to an embodiment of the present disclosure, a mobile robot may include a body provided with a driving unit, a body display unit positioned on an upper side of a front portion of the body, extending vertically, and provided with a display on a front surface thereof, a supporter extending vertically inside the body display unit and having a lower end supported by the body, and an interface module supported by the supporter and electrically connected to the display.

Abstract: Legged robots and methods for controlling legged robots are disclosed. In some examples, a mobile robot includes a frame, legs, and a control system. The mobile robot includes, for each leg, a motor coupled to the frame, the motor comprising a motor arm and a spring attachment point, the motor being configured to rotate the motor arm and the spring attachment point. The mobile robot includes, for each leg, a spring coupled to the spring attachment point of the motor and the leg, wherein the leg includes a track shaped to receive the motor arm, and wherein the leg is coupled to the spring such that the motor arm is within the track. The control system is configured, e.g., by virtue of appropriate programming, to control the motors to cause the mobile robot to move.

Abstract: In a method for operating a machine tool system with a machine tool for machining a workpiece using a tool, a control device is connected to the machine tool for generating a relative movement between the workpiece and the tool using a program executable by the control device. The control device includes an operating unit having a display device, allowing an operator to interact with the control device. The operator can manually alter with the operating unit a technology parameter. However, the operator generally does not know how a manual alteration of a technology parameter will affect productivity. Therefore, a measure for a change to production-related characteristics variable resulting from the manual alteration is determined and displayed to the operator on the display device directly or in relation to an associated relative measure.

Abstract: A mechanism for holding surgical instruments includes a carrier mounted on a machine tool and multiple holding modules mounted on the carrier. At least one of the holding modules is selected to be used during surgical operation. A swing element of the selected holding module enables a guidance sleeve to be swung to allow a guidance hole on the guidance sleeve to face toward a surgical operation region. The guidance sleeve is provided to hold one surgical instrument for surgical operation.

Abstract: A powered user interface for a robotic surgical system includes a base, a handle mounted to the base and moveable relative to the base in at least six degrees of freedom, and actuators. The interface operates in accordance with a first mode of operation in which the actuators are operated to constrain predetermined ones of the joints to permit motion of the handle in only 4DOF with respect to the base, and a second mode of operation in which the actuators permit motion of the handle in at least 6DOF with respect to the base.

Abstract: The invention relates to a method for testing the plausibility of output signals (u1, u2) of a resolver (21), by means of which an angular position of two elements (3-7) of a machine (R) can be determined in relation to each other.

Abstract: A user interface device of a remote control system for a robot and a method using the same are provided. The user interface device includes: a radio frequency (RF) unit for receiving, from a remote control robot, camera data and at least one sensor data detecting a distance; a display unit having a main screen and at least one auxiliary screen; and a controller having an environment evaluation module for determining whether the received camera data are in a normal condition, and having a screen display mode change module for displaying, if the received camera data are in a normal condition, the camera data on the main screen and displaying, if the received camera data are in an abnormal condition, the sensor data on the main screen.

Abstract: A surgical system performs a surgical procedure on a patient with manipulators and an endoscope. The surgical system has a display unit for simultaneously displaying a plurality of items of information including an endoscopic image captured by the endoscope, and a wireless image processor for transmitting information to the display unit and processing the plurality of items of information to be displayed by the display unit. The information about the endoscopic image is transmitted from the endoscope to the wireless image processor through a link including at least a portion based on wireless communications.

Abstract: A numerical controller capable of visually and accurately analyzing a change of the tool trajectory before and after changing a processing condition, whereby a parameter of a drive axis can be properly adjusted. The numerical controller comprises a numeric controlling part which controls each drive axis based on a predetermined position command; a position data obtaining part which obtains position data of each drive axis controlled by the numerical controlling part; a tool coordinate calculating part which calculates a coordinate of a tool center point based on position feedback or obtained position data of each drive axis and information of a mechanical structure of a machine tool; a tool trajectory storing part which stores the calculated coordinate of the tool center point as a feedback trajectory; and a displaying part which displays the stored feedback trajectory on a display.

Abstract: A medical robotic system includes an entry guide with articulatable instruments extending out of its distal end, an entry guide manipulator providing controllable four degrees-of-freedom movement of the entry guide, and a controller configured to limit joint velocities in the entry guide manipulator so as to prevent movement of tips of the articulatable instruments from exceeding a maximum allowable linear velocity when the entry guide manipulator is being used to move the entry guide.

Abstract: A robotic mount is configured to move an entertainment element such as a video display, a video projector or a staircase. The robotic mount is movable in three-dimensions, whereby the associated entertainment element is moveable in three-dimensional space. In one embodiment, a unitary display comprises a plurality of closely spaced individual displays which are mounted to robotic mounts, whereby the configuration of the unitary display may be altered by changing the position of one or more of the displays relative to the others.

Abstract: A medical robotic system includes an entry guide with articulatable instruments extending out of its distal end, an entry guide manipulator providing controllable four degrees-of-freedom movement of the entry guide, and a controller configured to limit joint velocities in the entry guide manipulator so as to prevent movement of tips of the articulatable instruments from exceeding a maximum allowable linear velocity when the entry guide manipulator is being used to move the entry guide.

Abstract: A medical robotic system includes an entry guide with articulatable instruments extending out of its distal end, an entry guide manipulator providing controllable four degrees-of-freedom movement of the entry guide, and a controller configured to limit joint velocities in the entry guide manipulator so as to prevent movement of tips of the articulatable instruments from exceeding a maximum allowable linear velocity when the entry guide manipulator is being used to move the entry guide.

Abstract: A robotic system that includes a remote controlled robot. The robot may include a camera, a monitor and a holonomic platform all attached to a robot housing. The robot may be controlled by a remote control station that also has a camera and a monitor. The remote control station may be linked to a base station that is wirelessly coupled to the robot. The cameras and monitors allow a care giver at the remote location to monitor and care for a patient through the robot. The holonomic platform allows the robot to move about a home or facility to locate and/or follow a patient.

Abstract: A mobile robot guest for interacting with a human resident performs a room-traversing search procedure prior to interacting with the resident, and may verbally query whether the resident being sought is present. Upon finding the resident, the mobile robot may facilitate a teleconferencing session with a remote third party, or interact with the resident in a number of ways. For example, the robot may carry on a dialogue with the resident, reinforce compliance with medication or other schedules, etc. In addition, the robot incorporates safety features for preventing collisions with the resident; and the robot may audibly announce and/or visibly indicate its presence in order to avoid becoming a dangerous obstacle. Furthermore, the mobile robot behaves in accordance with an integral privacy policy, such that any sensor recording or transmission must be approved by the resident.

Abstract: Time information t and positional information about each axis are obtained, and the three-dimensional coordinates of tool center point Pe at time t are calculated to display the path of the tool center point Pe at time t. Then, whether a fixed time has elapsed or not is decided. If the fixed time has elapsed, the coordinates of the tool vector start point Ps at time t are calculated to display a line segment connecting between tool vector start point Ps and tool center point Pe, which is the end point of the tool vector. This display enables the orientation of the tool at each tool center point to be grasped at a glance.

Abstract: A system for moving robots in accordance with a predetermined algorithm. The system includes: a surface having a position-coding pattern which identifies the surface; mobile robots for moving across the surface, each robot being configured for sensing and decoding the position-coding pattern; and a computer system in communication with the mobile robots. The computer system is configured to send instructions for moving each mobile robot relative to the surface in response to position information corresponding to that mobile robot. Further, the computer system is configured to determine instructions for moving each mobile robot using a predetermined algorithm. The predetermined algorithm is selected on the basis of the identity of the surface.

Abstract: A medical robotic system comprises a number of components that may be monitored to determine their preventive maintenance needs by recording usage-related information for the monitored components into associated non-volatile memories. When usage of the component exceeds a specified usage threshold, the system displays a warning message on its display screen to have preventive maintenance performed for the component. If the usage continues without such maintenance and exceeds a higher usage threshold, the system displays an error message on its display screen and the system transitions into an error state during which medical procedures are not allowed to be performed. The usage-related information may also be communicated to a remote computer which gathers and processes usage-related information from a number of medical robotic systems to estimate resource requirements for timely performing preventive maintenance on the medical robotic systems, and anticipated service revenues from such maintenance.

Abstract: A vehicle-mounted display device comprises a display mounted to a shaft, and operable to revolve with the rotation of the shaft; a transmission mechanism for coupling an output shaft of a motor with the shaft; a control module for controlling the motor; a baffle plate located at any position that enables it to rotate in synchronism with the rotation of the display, and a detection module for detecting the baffle plate. During the rotation of the display, when the detecting module does not detect the baffle plate in a predetermined period of time, the control module causes the motor to stop running or to turn in a reverse direction. This vehicle-mounted display device not only is reliably operable and electronically controllable, but also has anti-clamping and self-protection functions and has a simple structure and low cost.

Abstract: An entertainment system is for a vehicle and includes a vehicle environment sensor apparatus that captures data indicative of the vehicle's environment and that generates a vehicle environment data feed. A video game console is electronically coupled to the vehicle environment sensor apparatus and has an application program interface. The video game console receives the vehicle environment data feed, operates a game medium, and generates a video output signal based on both the game medium and the vehicle environment data feed. At least one controller is communicatively coupled to the video game console and directs the operation of the game medium. A display unit communicatively coupled with the application program interface receives the video output signal and displays images dependent upon the video output signal.

Abstract: A data processing apparatus for processing data described in a welding operation program of an arc welding robot system.

Abstract: There is provided a travel time display device for an industrial robot which can display travel time on the screen such that time taken for moving a work from any designated starting point to any other point can be seen at a glance. The travel time display device includes: a display for displaying on the screen the location of the industrial robot and an area in which the industrial robot can transport the work; a position designator for designating a travel starting point of the industrial robot at an arbitrary position on the display screen; a calculator for setting a plurality of time intervals with respect to necessary travel time from the travel starting point and calculating a travelable area, to be displayed on the display screen; and a display for depicting the travelable areas with a visual discrimination between the travelable areas.

Abstract: An industrial robot includes a first member, a positioning member arranged to be attached to the first member, a second member arranged to rotate relative to the first member, and a first joint for coupling the first member with the second member. The second member has a contact point arranged to contact the positioning member. An indication for requesting to enable the positioning member to contact the contact point is displayed. The second member rotates at the first joint relatively to the first member while the positioning member can contact the contact point. It is detected whether or not the contact point of the second member contacts the positioning member. A position of the second member is stored as an origin when it is detected that the contact point of the second member contacts the positioning member. This method prevents a possible failure of the attaching of the positioning member, and decreases a work load on an operator.

Abstract: It is an object of the present invention to provide a parking assisting apparatus for assisting a vehicle driver in parking a vehicle more easily than the conventional apparatuses.

Abstract: An electronic display configured to display visual information is mounted to a display mount. The display mount is movable in three-dimensions, whereby the associated display may be moved in three-dimensional space. In one embodiment, a unitary display comprises a plurality of closely spaced individual displays which are mounted to movable display mounts, whereby the configuration of the unitary display may be altered by changing the position of one or more of the displays relative to the others.

Abstract: In a master-slave manipulator system capable of presenting an obstacle and a limit to an operating range as a force feed-back with no use of a motor in an operation input device and having high reliability, a small size and good operability, the system comprises a manipulator having an arm, an operation input device for moving the arm of the manipulator, and a controller for controlling the manipulator and the operation input device, and the operation input device is provided on joints with a mode change-over mechanism having three modes: of which, in a first mode, power is not transmitted; in a second mode, power is transmitted in one direction and is not transmitted in a reverse direction thereof; and in a third mode, power is transmitted in the reverse direction and is not transmitted in the one direction, selecting one of the above modes and changing over from one mode to the selected mode.

Abstract: The characteristics of actuators themselves and the characteristics of controllers for the actuators are dynamically or statically controlled to achieve stable and highly efficient movements. In a stage in which a leg in the flight state is uplifted such that the reactive force from the floor received by the foot sole of the leg is zero, the characteristics of the respective actuators for the knee joint pitch axis and the ankle pitch and roll axes of the leg in the flight state are set for decreasing the low range gain, increasing the quantity of phase lead and for decreasing the viscous resistance of the actuators, in order to impart mechanical passiveness and fast response characteristics. The followup control for the high frequency range may be achieved as the force of impact at the instant of touchdown is buffered.

Abstract: A mobile robot communication system includes a remote unit, a repeater module and a control station. A cable connects the repeater module to the control station. The remote unit has a wireless receiver/transmitter for sending and receiving commands. The repeater module has a wireless receiver/transmitter for sending and receiving commands from the mobile unit. The control station is operable in communication with the repeater module for remotely sending and receiving signals. The cable is attached between the repeater module and control station for transmitting signals therebetween.

Abstract: A reference signal is transmitted from one of a plurality of robot control devices connected by communication connecting device to the other robot control device. The timing of generation of an operation basic period signal in each of the other robot control devices is synchronized with the timing of generation of an operation basic period signal in the one of the plurality of robot control devices, based on a time interval from generation of the operation basic period signal until transmission of the reference signal in the one of the plurality of robot control devices, a time interval from generation of the operation basic period signal until reception of the reference signal in each of the other robot control devices, and a communication delay time required for communication between the one of the plurality of robot control devices and each of the other robot control devices.

Abstract: An external force estimation system for estimating an external force acting upon a robot apparatus which includes a machine body which in turn includes a plurality of movable joints is disclosed which includes a distribution type contacting state detection section, an actuator current state measurement section, a motion state measurement section, a motion equation setting section, a known term calculation section, and an external force estimation section.

Abstract: An apparatus calculates, based on unimproved behavior amounts, behavior amount variations of living behaviors when each of living behaviors increases by one unit behavior amount, calculates environmental load variation of living behavior when the living behavior increases by one unit behavior amount, by calculating sum of values each obtained by multiplying one of behavior amount variations by corresponding one of basic units, to obtain environmental load variations of living behaviors, assigns messages to living behaviors based on environment load variations of living behaviors, calculates environmental load reduction of living behavior by (a) calculating variation between one of unimproved behavior amounts and one of improved behavior amounts of living behavior, and (b) multiplying variation by environmental load variation of living behavior, to obtain environmental load reductions of living behaviors, and selects one of messages which is assigned to one of living behaviors has the largest environmental loa

Abstract: According to the hand control system (2), the position and posture of a palm (10) are controlled such that the object reference point (Pw) and the hand reference point (Ph) come close to each other and such that the i-th object reference vector (?wi) and the i-th hand reference vector (?hi) come close to each other. During the controlling process of the position and posture of the palm, the operation of a specified finger mechanism is controlled such that the bending posture of the specified finger mechanism gradually changes (for example, such that the degree of bending gradually increases). This ensures accurate grasping of an object of an arbitrary shape.

Abstract: A robot system that includes a robot and a remote station. The remote station includes a head worn device worn on the head of a user. The head worn device senses movement of the user's head and generates corresponding input signals. The input signals are processed into robot movement commands and transmitted to the robot, typically through a broadband network. The robot movement commands move a camera of the robot. The camera movement tracks movement of the user's head so that the user can scan the visual field without having to generate separate input commands for the robot.

Abstract: A remote controlled robot system that includes a robot and a remote control station. A user can control movement of the robot from the remote control station. The remote control station may generate robot control commands that are transmitted through a broadband network. The robot has a camera that generates video images that are transmitted to the remote control station through the network. The user can control movement of the robot while viewing the video images provided by the robot camera. The robot can automatically stop movement if it does not receive a robot control command within a time interval. The remote control station may transmit a stop command to the robot if the station does not receive an updated video image within a time interval.

Abstract: A robot system is provided and includes an autonomous mobile robot. In the system in which monitoring is performed using the autonomous mobile robot which travels along a predetermined path, an interval between the time when a user requests transmission of images and the time when the user obtains the images may be reduced. The autonomous mobile robot travels along a predetermined path at predetermined times, a camera takes photographs at predetermined locations during the travel along the predetermined path, images taken by the camera are stored, and the stored images are sent to a requesting cell phone in response to a transmission request from the cell phone.

Abstract: A manual-mode operating system for a robot provided with an end-effector.

Abstract: A robotic storage library is provided for reducing the transition time to reach an operational state following a transition from a power-off to a power-on state. The robotic storage library can generally include a transport unit for moving data cartridges, or other storage elements, between a location in a shelf system and a drive, or data transfer interface, to complete storage operations for a host computer. The library can further include a controller for causing an audit to be performed to create an inventory of the locations. The audit can be stored in nonvolatile memory prior to the power transition. The inventory information can be transmitted to a host computer after the power transition.

Abstract: An assembling method and an apparatus for carrying out the method capable of efficiently, reliably and easily detecting an insertion and fitting position, for easy automatic assembly. In case a rod-like workpiece is inserted into a hole in an object, an insertable range is determined based an amount of clearance between the workpiece and the hole, an amount of chamfering of the hole, etc. The insertable range is defined as within a range centered at a hole center position 3cp and having a radium of r. A workpiece center position is indicated by 1cp. While the workpiece is moved once throughout a search range (XL-XU) in the X-axis direction, it is moved in the Y-axis direction by an amount equal to or less than an insertable range amount 2r. As shown by a dotted line, the workpiece center 1cp passes without fail through the insertable range during the motion throughout the search range (XL-XU, YL-YU).

Abstract: A robotic system that includes a plurality of robots that are linked to a plurality of remote stations. The robots have an input device and software that allows control of another robot. This allows an operator in close physical proximity to a robot to operate another robot. Each robot can be either a master or slave device.

Abstract: A robotic system that includes a remote controlled robot. The robot may include a camera, a monitor and a holonomic platform all attached to a robot housing. The robot may be controlled by a remote control station that also has a camera and a monitor. The remote control station may be linked to a base station that is wirelessly coupled to the robot. The cameras and monitors allow a care giver at the remote location to monitor and care for a patient through the robot. The holonomic platform allows the robot to move about a home or facility to locate and/or follow a patient.

Abstract: A robotic system that includes a mobile robot linked to a plurality of remote stations. The robot provides both audio and visual information to the stations. One of the remote stations, a primary station, may control the robot while receiving and providing audio and visual information with the remote controlled robot. The other stations, the secondary stations, may also receive the audio and visual information transmitted between the robot and the primary station. This allows operators of the secondary stations to observe, communicate and be trained through the robot and primary station. Such an approach may reduce the amount of travel required to train personnel.

Abstract: A robotic system that includes a remote controlled robot with at least five degrees of freedom and a teleconferencing function. The robot may include a camera, a monitor and a holonomic platform all attached to a robot housing. The robot may be controlled by a remote control station that also has a camera and a monitor. The remote control station may be linked to a base station that is wirelessly coupled to the robot. The cameras and monitors allow a care giver at the remote location to monitor and care for a patient through the robot. The holonomic platform provides three degrees of freedom to allow the robot to move about a home or facility to locate and/or follow a patient. The robot also has mechanisms to provide at least two degrees of freedom for the camera.

Abstract: A method for monitoring a patient with a robotic system that includes a remote controlled robot. The robot may include a camera, a monitor and a holonomic platform all attached to a robot housing. The robot may be controlled by a remote control station that also has a camera and a monitor. The remote control station may be linked to a base station that is wirelessly coupled to the robot. The cameras and monitors allow a care giver at the remote location to monitor and care for a patient through the robot. The holonomic platform allows the robot to move about a home or facility to locate and/or follow a patient.

Abstract: A robotic system that includes a remote controlled robot. The robot may include a camera, a monitor and a holonomic platform all attached to a robot housing. The robot may be controlled by a remote control station that also has a camera and a monitor. The remote control station may be linked to a base station that is wirelessly coupled to the robot. The cameras and monitors allow a care giver at the remote location to monitor and care for a patient through the robot. The holonomic platform allows the robot to move about a home or facility to locate and/or follow a patient.

Abstract: In a mobile robot, the actuator characteristics are dynamically or statically controlled, during motions of an entire robot body in the course of falldown or descent, to realize stable highly efficient motions. In each stage of the falldown motions, the characteristics of each joint site taking part in controlling the stable area are set so that the low range gain is low, the quantity of phase lead is large and the viscous resistance of the motor is large, in such a manner that these joint sites may be positioned to high accuracy in a controller manner to increase orientation stability. This assures the positioning accuracy of the joints as main component for controlling the quantity ?S/?t as a reference in controlling the falldown motions of the robot body to increase the motion stability.