Abstract: A control device for a mobile body makes it possible to smoothly correct the deviation of an actual posture of a base body of a mobile body, which travels with the base body thereof moving up and down, from a desired posture of the base body while restraining an overshoot or an undershoot from occurring. To determine a required manipulated variable according to a feedback control law in order to converge a state amount deviation related to the posture of the base body of the mobile body to zero, the feedback gain of the feedback control law is determined by using the time series in a period from current time to predetermined time in the future in the time series of a desired inertial force of the mobile body or the base body. The required manipulated variable is determined by the calculation of the feedback control law on the basis of the determined feedback gain and an observed value of the state amount deviation.

Abstract: When the placement of the elements (mass points, links having inertia, etc.) of a model expressing a robot 1 is determined according to a first geometric restrictive condition from an instantaneous desired motion of the robot 1 that has been created using a dynamic model, this placement is defined as a first placement, and the placement determined according to a second geometric restrictive condition from a corrected instantaneous desired motion that has been obtained by correcting the instantaneous desired motion is defined as a second placement. The corrected instantaneous desired motion is determined such that the moment component calculated from the difference between the first and the second placements approximates a predetermined value. The instantaneous desired motion is created using a dynamic model of the robot.

Abstract: A method of controlling a power assist device that includes an operating handle, a force sensor, a robot arm, an actuator that drives the robot arm, and a conveying portion for conveying the robot arm. When a body in motion, the conveying portion is controlled to move in synchronization with the body, and when the motion of the body is stopped or has resumed, the drive of the robot arm is stopped for a predetermined time, and does not resume until after a predetermined time has elapsed.

Abstract: The inventive method consists in supplying motion instructions (300) at least including information about the path geometry (320) and load instructions (310) to a path generator (400), calculating an allied load signal (800), transmitting said applied load signal (800) to the path generator (400), calculating motion instructions (500) along the path in such a way that the deviation between the projection of the applied load on a tangent to said path and the projection of the instruction on said tangent is minimized and in transmitting said motion instructions (500) to means for actuating a robot (600). A device comprising means (200, 400, 700) for carrying out said control is also disclosed.

Abstract: A force sensor includes a base unit, an elastic supporting unit, an action unit supported by the elastic supporting unit, and a detection unit that detects at least one of an external force acting on the action unit and a moment acting on the action unit. The detection unit includes a light source, a diffraction grating, a photodetector array that receives an interference image formed by light that has been emitted from the light source and diffracted by the diffraction grating and outputs signals having different phases, and a calculation unit that calculates a displacement of the action unit with respect to the base unit on the basis of the signals and calculates at least one of the external force and the moment acting on the action unit on the basis of the displacement.

Abstract: A controller of a leg type moving robot determines an action force to be input to an object dynamic model 2 such that a motion state amount (object model velocity) of the object dynamic model 2 follows a desired motion state amount based on a moving plan of an object, and also determines a manipulated variable of the motion state amount (object model velocity) of the object dynamic model 2 such that the difference between an actual object position and a desired object position approximates zero, and then inputs the determined action force and manipulated variable to the object dynamic model 2 to sequentially determine the desired object position. Further, a desired object reaction force to a robot from the object is determined from the determined reaction force.

Abstract: Systems and methods are presented that enable a legged robot to maintain its balance when subjected to an unexpected force. In the reflex phase, the robot withstands the immediate effect of the force by yielding to it. In one embodiment, during the reflex phase, the control system determines an instruction that will cause the robot to perform a movement that generates a negative rate of change of the robot's angular momentum at its centroid in a magnitude large enough to compensate for the destabilizing effect of the force. In the recovery phase, the robot recovers its posture after having moved during the reflex phase. In one embodiment, the robot returns to a statically stable upright posture that maximizes the robot's potential energy. In one embodiment, during the recovery phase, the control system determines an instruction that will cause the robot to perform a movement that increases its potential energy.

Abstract: A method is provided for distributing tension among tendons of a tendon-driven finger in a robotic system, wherein the finger characterized by n degrees of freedom and n+1 tendons. The method includes determining a maximum functional tension and a minimum functional tension of each tendon of the finger, and then using a controller to distribute tension among the tendons, such that each tendon is assigned a tension value less than the maximum functional tension and greater than or equal to the minimum functional tension. The method satisfies the minimum functional tension while minimizing the internal tension in the robotic system, and satisfies the maximum functional tension without introducing a coupled disturbance to the joint torques. A robotic system includes a robot having at least one tendon-driven finger characterized by n degrees of freedom and n+1 tendons, and a controller having an algorithm for controlling the tendons as set forth above.

Abstract: A robotic system includes a robot having manipulators for grasping an object using one of a plurality of grasp types during a primary task, and a controller. Hie controller controls the manipulators dining the primary task using a multiple-task control hierarchy, and automatically parameterizes the internal forces of the system for each grasp type in response to an input signal. The primary task is defined at an object-level of control e.g., using a closed-chain transformation, such that only select degrees of freedom are commanded for the object. A control system for the robotic system has a host machine and algorithm for controlling the manipulators using the above hierarchy. A method for controlling the system includes receiving and processing the input signal using the host machine, including defining the primary task at the object-level of control, e.g., using a closed-chain definition, and parameterizing the internal forces for each of grasp type.

Abstract: A process and a device are provided for determining the pose as the entirety of the position and the orientation of an image reception device. The process is characterized in that the pose of the image reception device is determined with the use of at least one measuring device that is part of a robot. The device is characterized by a robot with an integrated measuring device that is part of the robot for determining the pose of the image reception device.

Abstract: It is possible to provide a power assist device which can maintain a stable contact state without causing an oscillation phenomenon even if a robot is brought into contact with an environment. A method for controlling the power assist device is also provided. The power assist device includes: an inner force sensor which detects an operation force applied by an operator; an operation handle having the inner force sensor; a robot arm which supports the operation handle; an actuator which drives the robot arm; the actuator and a control device which measure or estimate a force applied when the robot arm is brought into contact with an environment; and the actuator and the control device which detect or estimate a motion speed of the operation handle.

Abstract: A robotic system that includes a robot and a remote station. The remote station can generate control commands that are transmitted to the robot through a broadband network. The control commands can be interpreted by the robot to induce action such as robot movement or focusing a robot camera. The robot can generate reporting commands that are transmitted to the remote station through the broadband network. The reporting commands can provide positional feedback or system reports on the robot.

Abstract: A haptic device for telerobotic surgery, including a base; a linkage system having first and second linkage members coupled to the base; a motor that provides a motor force; a transmission including first and second driving pulleys arranged such that their faces form an angle and their axes form a plane, first and second idler pulleys offset from the plane and arranged between the first and second driving pulleys such that their axes divide the angle between the first and second driving pulleys, and a cable that traverses the first and second driving pulleys and the set of idler pulleys and transfers the motor force to the linkage system; an end effector coupled to distal ends of the first and second linkage members and maneuverable relative to the base; and a controller that modulates the motor force to simulate a body part at a point portion of the end effector.

Abstract: A control device for a cleaner that carries out a cleaning operation in home, is provided with a cleaning operation data base on which information relating to cleaning operations of a robot arm is recorded, a correcting operation type determination unit for determining a type of correction of the cleaning operation, a force detection unit for detecting a force of the hand of a person, and a cleaning operation correcting unit that corrects the cleaning operation in accordance with the force of the human hand and the type of correction during the cleaning job of the robot arm.

Abstract: A locomotion control system is constructed to input the quantity of materials in the real world, such as the quantity of motion state of a robot, external force and external moment, and environmental shapes, measured with sensors or the like. By integrating all calculations for maintaining a balance of the body into a single walking-pattern calculating operation, both a locomotion generating function and an adaptive control function are effectively served, the consistency of dynamic models is ensured, and interference between the dynamic models is eliminated. Calculations for generating a walking pattern of the robot can be performed in an actual apparatus and in real time in a manner in which parameters, such as a boundary condition concerning the quantity of motion state, external force and external moment, and the trajectory of the sole, are settable.

Abstract: An assembly machine includes a support structure having a plurality of selectively moveable support members that facilitate manually manipulating a tool relative to a work piece. A controller continuously gathers position information regarding the support members to determine every position of the tool. The controller includes a teach mode that allows for storing selected tool activation positions in particular sequences for subsequent control of the tool according to necessary procedures for completing a variety of assembly processes. One example machine designed according to this invention includes selectively controlled biasing members that maintain a zero balance on the tool, provide an operator assist to moving the tool or both.

Abstract: In a control system of a legged mobile robot having a body and legs connected to the body and driven by a leg actuator, there is provided an operation controller which generates gaits based on an external force, more specifically gaits for walking by taking a hand of a human being or with the hand being taken by the hand of the human being and controls operation of at least the leg actuator based on the generated gaits. With this, it becomes possible to control the robot to come contact with a human being to establish communication therewith, while enabling to keep a stable posture during the contact.

Abstract: Surgical robots and other telepresence systems have enhanced grip actuation for manipulating tissues and objects with small sizes. A master/slave system is used in which an error signal or gain is artificially altered when grip members are near a closed configuration.

Abstract: To generate a desired gait of a robot 1 such that a permissible range of a predetermined component (a translational floor reaction force horizontal component or the like) of a floor reaction force acting on the mobile robot 1, a gait generating system for a mobile robot creates a provisional motion, which indicates a provisional value of a desired motion, and repeats processing for correcting the provisional motion by using a first dynamic model and a second dynamic model having a dynamic accuracy that is higher than that of the first dynamic model until a predetermined condition is satisfied, thereby obtaining a final corrected motion as the desired motion.

Abstract: Techniques are provided for controlling an exoskeleton actuator at a joint of a human-exoskeleton system by receiving system parameters for the human-exoskeleton system, receiving generalized coordinates for the human-exoskeleton system, and determining an equivalent joint torque for the exoskeleton actuator to compensate for a selected force. While providing partial or complete compensation of selected gravitational and external forces, one embodiment of the present invention mitigates the amount of interference between voluntary control and assist control, thereby allowing humans to quickly humans adapt to an exoskeleton system.

Abstract: A gait generating system for a mobile robot determines a gait parameter that defines a gait of a mobile robot 1 to be generated by updating a value of a priority parameter of the gait parameter such that it approaches in steps to an original required value from a value of a priority gait parameter of a predetermined base gait parameter until it agrees with the original required value. Each time the value is updated, a search object parameter among non-priority parameters other than the priority parameter is determined in an exploratory manner such that a boundary condition of a gait is satisfied on a dynamic model of the robot 1, and a gait parameter that includes the determined search object parameter and the updated priority parameter is newly determined. The gait of the mobile robot 1 is generated using a gait parameter newly determined when the priority parameter is finally made to agree with the required value, and the dynamic model.

Abstract: Disclosed is a method of absorbing an impact generated when a foot of a walking robot lands on the ground to perform the walking of the walking robot. When the foot of the walking robot lands on the ground, an F/T sensor installed on the sole or the ankle of the foot measures external force and the posture of the sole of the foot is adjusted in a direction of complying with the external force, and thus an impact transmitted to the walking robot in landing is absorbed. Further, the posture adjusting speed of the sole of the foot is adjusted according to walking speeds (stopped, walking, running).

Abstract: A system and method for providing multiple priority impedance control for a robot manipulator where impedance laws are realized simultaneously and with a given order of priority. The method includes a control scheme for realizing a Cartesian space impedance objective as a first priority while also realizing a joint space impedance objective as a second priority. The method also includes a control scheme for realizing two Cartesian space impedance objectives with different levels of priority. The method includes instances of the control schemes that use feedback from force sensors mounted at an end-effector and other instances of the control schemes that do not use this feedback.

Abstract: A robot controller capable of automatically preparing a job program for a workpiece configured of a plurality of job elements is disclosed. A plurality of teaching programs for teaching the job for each job element making up the workpiece are stored in advance. Each teaching program has registered therein attribute information including the item number (identification information) and the sequence of application of the teaching program to each workpiece. The robot controller retrieves teaching programs having registered therein, as attribute information, the same item number as the input item number of the workpiece and prepares a main program such that the retrieved teaching programs are called sequentially as subprograms in accordance with the application sequence specified by the attribute information. Further, commands for moving to the job starting position and the job end position are added before and after the main program thereby to complete the main program.

Abstract: Based upon a force in a vertical direction exerted between an object and a hand and an angle made by the hand relative to a horizontal face, a transporting force estimation unit estimates a transporting force applied in the vertical direction by a person, and based upon the estimated force, a force controlling operation is carried out so as to set a force in the vertical direction of the robot arm of a robot system to a predetermined force.

Abstract: A compact, lightweight manipulation system that excels in operability and has a force feedback capability is provided. When automatic operation of a slave manipulator 105 that follows manual operation of a master manipulator 101 is bilaterally controlled by means of communication, the force acting on the slave manipulator is fed back to the master manipulator by operating the master manipulator primarily under electrically-driven speed control and the slave manipulator primarily under pneumatically-driven force control. Therefore, in the master manipulator, it is not necessary to compensate for the dynamics and the self-weight of the master manipulator in the motion range of a user, allowing highly accurate, broadband positional control, which is specific to an electrically-driven system, and in the slave manipulator, nonlinearity characteristics specific to a pneumatically-driven system presents passive softness, provides a high mass-to-output ratio, and produces a large force.

Abstract: A vertical component or the like of a floor reaction force moment to be applied to a robot 1 is defined as a restriction object amount, and the permissible range of the restriction object amount is set. A provisional motion of the robot that satisfies a predetermined dynamic balance condition is determined on a predetermined dynamic model, and if a restriction object amount determined by the provisional motion deviates from the permissible range, then the motion of a desired gait is determined by correcting the provisional motion by changing the angular momentum changing rate of the robot from the provisional motion while limiting the restriction object amount to the permissible range on the dynamic model.

Abstract: By using a first dynamic model of a moving robot 1, a provisional motion, which indicates a provisional value of a desired motion of the robot 1, is created such that a desired value of a floor reaction force moment horizontal component and a permissible range of a translational floor reaction force horizontal component are satisfied on the first dynamic model. The difference between a floor reaction force produced on a second dynamic model, which has a dynamic accuracy that is higher than that of the first dynamic model, by the provisional motion and a floor reaction force produced on the first dynamic model is defined as a floor reaction force error. Based on this floor reaction force error, the provisional motion is corrected on the first dynamic model to generate a desired motion. The desired motion is generated such that the value obtained by adding the floor reaction force error to the floor reaction force generated on the first dynamic model satisfies the aforesaid desired value and permissible range.

Abstract: The placement of the elements (mass points or rigid bodies having inertia) of a model expressing a robot 1 determined according to a first geometric restrictive condition from an instantaneous desired motion of the robot 1 is defined as a first placement, and provisional corrected instantaneous desired motions corresponding to a second placement and a third placement having predetermined relationships with the first placement are determined. The position/posture of a predetermined part 3 (body) of the robot 1 are determined by weighted averages of the position/posture of the aforesaid provisional corrected instantaneous desired motions. Thus, the motion of an instantaneous desired gait created using a dynamic model is properly corrected thereby achieving both improved dynamic accuracy between the motion and a floor reaction force of the instantaneous desired gait and a minimized change in the posture of a predetermined part, such as the body, of the robot without using a dynamic model.

Abstract: First of all, in a first step S1, each actuator command value for position command value and posture command value of an end-effector is determined. Next, in a second step S2, rotational resistance values of a first and a second universal joints are obtained, and in a third step S3, the force and the moment exerted to each of the second universal joints are computed using this, and in a fourth step S4, the resultant force and the resultant moment exerted to the end-effector are determined from these. Then, in the fifth step, the elastic deformation amount of a mechanism is computed using these, and a compensation amount of the actuator command value is computed using these values. And then, in the sixth step, the actuator command values determined in the first step are updated with the compensation amount determined in the fifth step taken into account.

Abstract: A fitting device for fitting a fitting workpiece, which is held by a robot, to a workpiece to be fitted by force control, comprises: a force detecting portion for detecting a force and moment acting on a control point of the fitting workpiece; a judging portion for judging whether or not clogging is caused between the fitting workpiece and the workpiece to be fitted at the time of fitting; and a changing portion for changing a position of the control point according to a distance by which the fitting workpiece enters the workpiece to be fitted and for pressing the fitting workpiece against the workpiece to be fitted in a direction perpendicular to the fitting direction so as to adjust a posture of the fitting workpiece on the basis of the control point that has been changed, in the case where it is judged by the judging portion that clogging is caused.

Abstract: The safety in robotic operations is enhanced and the floor space in a factory or the like is effectively utilized. A virtual safety barrier 50 including the trajectory of movement of a work or tool 7 mounted on a wrist 5 of a robot 1 in operation is defined in a memory. At least two three-dimensional spatial regions S (S1 to S3) including a part of the robot including the work or tool are defined. Predicted positions of the defined three-dimensional spatial regions obtained by trajectory calculations are matched with the virtual safety barrier 50, and if the predicted position of any one of the defined three-dimensional spatial regions based on trajectory calculations is included in the virtual safety barrier 50, a control is effected to stop the movement of the robot arms 3 and 4.

Abstract: Techniques are provided for controlling a human-exoskeleton system including an ankle-foot orthosis by receiving system parameters for the human-exoskeleton system, receiving generalized coordinates such as an orientation of the foot, and determining a joint torque for controlling the ankle-foot orthosis to compensate for one or more components of forces acting on the foot. Forces selected for compensation include gravitational forces as well as external forces such as ground reaction forces. Techniques are provided for determining an ankle joint torque for partial or complete compensation of forces acting on the foot about an axis of rotation. The provided techniques mitigate the amount of interference between voluntary control and assist control, thereby allowing humans to quickly humans adapt to an exoskeleton system.

Abstract: While a biped walking mobile body is in a motion, such as level-ground walking, the position of the center of gravity (G0) of the biped walking mobile body, the position of an ankle joint (12) of each leg (2), and the position of a metatarsophalangeal joint (13a) of a foot (13) are successively grasped. The horizontal position of any one of the center of gravity (G0), the ankle joint (12), and the metatarsophalangeal joint (13a) is estimated as the horizontal position of a floor reaction force acting point on the basis of the combination of the contact or no contact with the ground at a spot directly below the metatarsophalangeal joint 13a of the foot 13 and a spot directly below the ankle joint 12, which is detected by ground contact sensors 51f and 51r, respectively, provided on the sole of the foot 13. The vertical position of the floor reaction force acting point is estimated on the basis of the vertical distance from the ankle joint (12) to a ground contact surface.

Abstract: A method for estimating joint load at a joint of a segment. The method comprises the steps of receiving kinematic data, determining a modified acceleration using at least the kinematic data, estimating a joint load using at least the modified acceleration; and determining simulated kinematic data for the segment using at least the joint load. The method addresses the problems with conventional inverse dynamics analysis by providing a forward dynamics solution for estimation of joint loads that is stable, guaranteed to converge, computationally efficient, and does not require acceleration computations. According to one embodiment, a joint load is estimated recursively.

Abstract: There is provided an actuator control device for force-controlling a joint driving actuator according to a commanded joint force command value ?a. The actuator control device includes a joint value detecting means for detecting a joint value q at an output stage of the actuator, an action force detecting means for detecting an action force ?e in a joint driving direction at the output stage of the actuator, and a driving force determining means for determining an instructed driving force ? to the actuator, on the basis of an ideal response model of the actuator which specifies the relationship of a joint value acceleration target value achieved as the actuator responds ideally when the joint force command value ?a, the action force ?e, and a joint value velocity obtained by time-differentiating the joint value q are given.

Abstract: Ground contact portions 10 are classified into a tree structure such that each of the ground contact portions 10 of a mobile body 1 (mobile robot) equipped with three or more ground contact portions 10 becomes a leaf node and that an intermediate node exists between the leaf node and a root node having all the leaf nodes as its descendant nodes. On each node (a C-th node) having child nodes, the correction amounts of the desired relative heights of the ground contact portions 10 of the C-th node are determined such that the relative relationship among the actual node floor reaction forces of the child nodes of the C-th node approximates the relative relationship among the desired node floor reaction forces of the child nodes of the C-th node, and joints of the mobile body 1 are operated so that a desired relative height obtained by combining the correction amounts is satisfied.

Abstract: A robot simulation device is provided. It includes a virtual robot working environment in which a virtual robot has a task of transferring a virtual object from a start point to a goal point, the simulation device determining the path of travel. A task simulation is executed in response to the virtual robot working environment and the path of travel. The task simulation determines a robot activity region where the virtual robot can operate and an interference region where the virtual robot encounters obstacles. Thereafter the device creates a desired executed simulation in which the virtual robot can operate without encountering obstacles.

Abstract: Ground contact portions are categorized in a tree structure manner such that all of the ground contact portions of a mobile body (mobile robot) equipped with three or more ground contact portions become leaf nodes and that an intermediate node exists between the leaf nodes and a root node having all the leaf nodes as its descendant nodes. On each node (a C-th node) having child nodes, the correction amounts of the desired relative heights of the ground contact portions of the C-th node are determined such that at least the difference between an actual posture inclination and a desired posture inclination of a predetermined portion, such as a base body, (posture inclination difference) is approximated to zero, and joints of the mobile body 1 are operated so that a desired relative height obtained by combining the correction amounts is satisfied.

Abstract: A storage media library device includes a media drive unit which writes and reads information on storage media, a media storage unit which stores the storage media, a robot which transports the storage media between the media drive unit and the media storage unit, a robot control unit which controls the storage media transport operation of the robot, and a vibration detection unit which detects occurrence of vibrations. The robot control unit is controlled by a library control unit, wherein if occurrence of vibrations is detected by the vibration detection unit during the robot transports the storage media, the robot control unit causes the robot to stop the storage media transport operation, and when subsidence of the vibrations is detected within a predefined time period preset in a storage media transport command and monitored by the library control unit, the robot control unit causes the robot to resume.

Abstract: A method of controlling a power assist device including a workpiece holding device, a handle, a force sensor that measures operating force of a worker that acts on the handle, a robot arm that supports the workpiece holding device, and a control device that controls an action of the robot arm based on a measurement result of the force sensor. The workpiece holding device includes an angle sensor that measures an inclination angle of the workpiece holding device. An action of robot arm is controlled by the control device based on measurement results of the angle sensor and of the force sensor.

Abstract: A robot displacement device for use with a robotic frame shaped to approximate and be coupleable to at least a portion of the human body and configured to mimic movement of the human body. The device employs a plurality of force sensors which are attached to the robotic frame which detect a baseline controlling interface force status relationship between the sensors and the extremities of the human operator. Based on the output force signal from the sensors and the force and direction of gravity relative to the robotic frame, the computation system calculates at least a rotational force required to maintain the controlling force status relationship. That system then generates and transmits an actuation signal to a drive system attached to the robotic frame which displaces a portion of the robotic frame in order to maintain the controlling force status relationship.

Abstract: An industrial robot including a manipulator, a control unit for controlling the manipulator, a portable operating unit for teaching and manually operating the robot, which operating unit is adapted for wireless communication with the control unit, and an emergency stop unit. The emergency stop unit is arranged movable and the portable operating unit includes a first receiving member for receiving the emergency stop unit.

Abstract: Kinematic singular points in a process system are handled. In one embodiment, a numerically controlled (NC) processing system includes materials processing installation having a multi-axis kinematic linkage operable to position a tip portion of the linkage along a predetermined process path. The system also includes a processor having a compensation system operable to detect a singular point in the process path and to improve the accuracy tip portion positioning near the singular point.

Abstract: A micro-manipulator has grippers for gripping micro-material; an actuator for driving the grippers; a drive amount detection device for detecting a drive amount of the actuator; a power control device for controlling power supplied to the actuator so that a difference in a target drive amount of the input actuator and a drive amount detected by the drive amount detection device is small, after at least the grippers touch the micro-material; a gripping determination device for determining that grippers have gripped the micro-material based on the difference; and a resilience value calculation device for calculating a resilience value that represents a degree of softness of the micro-material by dividing the actuator drive force that is equivalent to the repulsive force of micro-material gripped by the grippers in proportion to power supplied to the actuator via the power control device.

Abstract: An apparatus and method of controlling a mobile body that travels around a sound source which generates a sound. This apparatus includes a traveling information producer for producing traveling information, which is information about traveling of the mobile body; a direction estimator for estimating a direction in which the mobile body is located with respect to the sound source; and a position determiner for determining a position of the mobile body using the traveling information and the estimated direction of the mobile body.

Abstract: An actuator and a robot are capable of properly adjusting the compliance of the motions of links in response to external forces according to an environment or application. The actuator sets a drive command angular velocity on the basis of a desired motor angular velocity, which is the resultant angular velocity of a desired link angular velocity and a desired driven angular velocity. The component of the desired link angular velocity included in a resultant desired velocity imparts stiffness to the motion of a link, while the component of the desired driven angular velocity included in the resultant desired velocity imparts flexibility to the motion of the link. Thus, the balance between the stiffness and the flexibility of the motion of the link is adjusted by adjusting the resultant ratio between the desired link angular velocity and the desired driven angular velocity.

Abstract: At present, the molybdenum sampling process in maxibags is carried out manually and it has the disadvantage of being carried out manually which causes the system efficiency to decrease due to the less representativeness of the samples obtained. Due to the above, a robot system and method have been developed for the sample taking of molybdenum in an automatic way so as to ensure the representativeness of the sampling as well as the control over the product to be commercialized. The robotic system is composed mainly of a robotic manipulator (1) of at least 5 degrees of freedom, and a gripping mechanism (2) which allows to take the sampling device (3) from a tool holder (4) located at on of its sides, moving it through a defined path to the sampling area (5), where the sampling process will take place, in a sequential and programmed way, to certain number of maxibags faces to be defined (7).

Abstract: In a robot arm controlling device, a mechanical impedance set value of the arm is set by an object property-concordant impedance setting device based on information of an object property database in which information associated with properties of an object being gripped by the arm is recorded, and a mechanical impedance value of the arm is controlled to the set mechanical impedance set value by an impedance controlling device.

Abstract: A driving force calculating device (1) includes: a setting information acquiring section (23) which acquires (a) muscle specifying information that specifies a target muscle, which is a muscle whose function is assisted or resisted by a driving section and (b) a target value of muscle force to be produced by the target muscle at the time of rotational motion under assistance or resistance of the driving section; and a target muscle force evaluating section (24) which acquires an estimated muscle force table (58) and musculoskeletal model data (53) and evaluates the feasibility of the target value of the target muscle. With this arrangement, it is possible to reduce time required to calculate a driving force of the driving section of the power assisting device.