Abstract: A provisional desired motion trajectory of an object is determined based on a moving plan of the object. Then, it is determined whether a robot leg motion can satisfy a necessary requirement. The requirement is related to a position/posture relationship between the object and the robot, and a determination of whether the requirement can be satisfied is made at a future, predetermined step. A restrictive condition related to robot leg motion is satisfied at each step up to the predetermined number of steps. If the requirement is satisfied, then a desired gait is generated on the basis of the provisional desired motion trajectory. Otherwise, a desired gait is generated on the basis of a desired motion trajectory of the object according to a corrected moving plan.

Abstract: A state estimating apparatus permits efficient, highly accurate estimation of the state of an object. A particle in a state variable space defined by a second state variable preferentially remains or increases as the likelihood thereof relative to a current measured value of a first state variable is higher, while a particle is preferentially extinguished as the likelihood thereof is lower. A particle which transitions in the state variable space according to a state transition model with a high probability of being followed by an object (a high-likelihood model) as a next model tends to increase. On the other hand, although in a small quantity, there are particles having models (low-likelihood models) which are different from the high-likelihood model as their unique models.

Abstract: A controller of a mobile robot that moves an object such that the position of a representative point of the object and the posture of the object follow a desired position and posture trajectory is provided. The desired posture trajectory of the object includes the desired value of the angular difference about a yaw axis between a reference direction, which is a direction orthogonal to the yaw axis of the object, and the direction of the moving velocity vector of the representative point of the object, defined by the desired position trajectory. The controller has a desired angular difference setting means which variably sets the desired value of the angular difference according to at least a required condition related to a movement mode of the object. This allows the object to be moved at a posture which meets the required condition of the movement mode.

Abstract: The present invention provides a motion control system control a motion of a second motion body by considering an environment which a human contacts and a motion mode appropriate to the environment, and an environment which a robot actually contacts. The motion mode is learned based on an idea that it is sufficient to learn only a feature part of the motion mode of the human without a necessity to learn the others. Moreover, based on an idea that it is sufficient to reproduce only the feature part of the motion mode of the human without a necessity to reproduce the others, the motion mode of the robot is controlled by using the model obtained from the learning result. Thereby, the motion mode of the robot is controlled by using the motion mode of the human as a prototype without restricting the motion mode thereof more than necessary.

Abstract: In a legged mobile robot, each hip joint that connects a body with a thigh link comprises a first rotary shaft that provides a degree of freedom to rotate about a yaw axis, a second rotary shaft that provides a degree of freedom to rotate about a roll axis, and a third rotary shaft that provides a degree of freedom to rotate about a pitch axis, and in addition thereto, a fourth rotary shaft that provides a redundant degree of freedom. Owing to this configuration, the amount of body bending and the movable range of the legs can be increased, thereby improving the degree of posture and gait freedom.

Abstract: A gait generating system of a legged mobile robot is provided with a device for determining a desired trajectory of an external force to be applied to a robot 1, a device for determining a parameter of a desired gait (current time gait) for a predetermined period on the basis of a desired trajectory of an external force or the like, a device for determining a parameter of a virtual cyclic gait that follows the current time gait on the basis of the desired trajectory of the external force or the like, a device for correcting the current time gait parameter such that a body motion trajectory of the robot 1 of the current time gait converges to a body motion trajectory of the cyclic gait, and a device for sequentially determining an instantaneous value of the current time gait on the basis of the corrected current time gait parameter.

Abstract: When a new desired gait of a robot is generated, it is determined, on the assumption that the trajectory of an acting force between the robot and an object at a predetermined time point in the future changes to a trajectory different from a desired trajectory, whether a predetermined dynamical restrictive condition can be satisfied when a desired gait after the predetermined time point is generated. If the condition cannot be satisfied, then a moving schedule for the object is corrected, the desired trajectory or the like of the acting force between the robot and the object is re-determined, and a new desired gait is generated using the re-determined desired trajectory. With this arrangement, the gait of the robot to cause the robot to perform an operation for moving the object is generated such that the stability of the posture of the robot can be secured even if an acting force between the robot and the object in the future deviates from a desired value.

Abstract: A gait generator determines a desired motional trajectory and a desired object reaction force trajectory of an object 120 for a predetermined period after the current time by using an object dynamic model while supplying, to the object dynamic model, a model manipulated variable (estimated disturbance force) for bringing a behavior of the object 120 on the object dynamic model close to an actual behavior, and provisionally generates a gait of a robot 1 for a predetermined period by using the aforesaid determined trajectories. Based on the gait and an object desired motion trajectory, a geometric restrictive condition, such as interference between the robot 1 and the object 120, is checked, and a moving plan for the object 120 or a gait parameter (predicted landing position/posture or the like) of the robot1 is corrected as appropriate according to a result of the check, so as to generate a gait of the robot 1.

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: A legged mobile robot, a legged mobile robot controller and a legged mobile robot control method are provided to perform a loading operation to load a gripped object in parallel on a target place having a height where a stretchable range of arm portions of the legged mobile robot is enhanced with no operator's handling. The legged mobile robot includes the arm portions having links for gripping an object, and leg portions having links for moving, and the arm and the leg portions are joined to a body thereof. The legged mobile robot controller includes a data acquisition unit, a whole-body cooperative motion control unit and a loading detection unit, and controls motions of the legged mobile robot based on posture/position data regarding a posture/position of each link of the legged mobile robot and on an external force data regarding an external force affecting the arm portions.

Abstract: A control method for a legged mobile robot includes exercising a body of a robot such that a center of gravity of the robot obtains a momentum or the body obtains an angular momentum in a direction in which an object is to be moved while restraining a force from being applied to the object from the robot in a state wherein the robot opposes the object, and applying a force to the object from a hand of an arm body provided in the body of the robot so as to start moving the object in a state wherein the center of gravity has obtained the momentum or the body has an angular momentum. With this arrangement, when moving an object by a robot, a motion of the robot can be smoothly changed while preventing a significant change in ZMP before and after starting to move the object.

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: 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 legged mobile robot, a legged mobile robot controller and a legged mobile robot control method are provided to perform a loading operation to load a gripped object in parallel on a target place having a height where a stretchable range of arm portions of the legged mobile robot is enhanced with no operator's handling. The legged mobile robot includes the arm portions having links for gripping an object, and leg portions having links for moving, and the arm and the leg portions are joined to a body thereof. The legged mobile robot controller includes a data acquisition unit, a whole-body cooperative motion control unit and a loading detection unit, and controls motions of the legged mobile robot based on posture/position data regarding a posture/position of each link of the legged mobile robot and on an external force data regarding an external force affecting the arm portions.

Abstract: A model's ZMP (full-model's ZMP) is calculated using a dynamic model (inverse full-model) 100c2 that expresses a relationship between a robot movement and floor reaction, a ZMP-converted value of full model's corrected moment about a desired ZMP is calculated or determined based on a difference (full-model ZMP's error) between the calculated model's ZMP and the desired ZMP, whilst a corrected desired body position is calculated or determined. Since the robot posture is corrected by the calculated ZMP-converted value and the corrected desired body position, the corrected gait can satisfy the dynamic equilibrium condition accurately.

Abstract: In a legged mobile robot, each hip joint that connects a body with a thigh link comprises a first rotary shaft that provides a degree of freedom to rotate about a yaw axis, a second rotary shaft that provides a degree of freedom to rotate about a roll axis, and a third rotary shaft that provides a degree of freedom to rotate about a pitch axis, and in addition thereto, a fourth rotary shaft that provides a redundant degree of freedom. Owing to this configuration, the amount of body bending and the movable range of the legs can be increased, thereby improving the degree of posture and gait freedom.

Abstract: A model's ZMP (full-model's ZMP) is calculated using a dynamic model (inverse full-model) 100c2 that expresses a relationship between a robot movement and floor reaction, a ZMP-converted value of full model's corrected moment about a desired ZMP is calculated or determined based on a difference (full-model ZMP's error) between the calculated model's ZMP and the desired ZMP, whilst a corrected desired body position is calculated or determined. Since the robot posture is corrected by the calculated ZMP-converted value and the corrected desired body position, the corrected gait can satisfy the dynamic equilibrium condition accurately.

Abstract: A posture control system for a mobile robot. When an unexpected external force acts, the system is configured to control and stabilize the posture of the robot driving an arm link such that, in response to a first external force that is a component in a predetermined direction of an unexpected external force, a second external force acts on the arm link in a direction orthogonal to the predetermined direction. With this, when the mobile robot receives a reaction force, even if the posture becomes unstable or the robot receives an unexpected reaction force, it becomes possible to preserve the dynamic balance and to maintain a stable posture.

Abstract: A model's ZMP (full-model's ZMP) is calculated using a dynamic model (inverse full-model) 100c2 that expresses a relationship between a robot movement and floor reaction, a ZMP-converted value of full model's corrected moment about a desired ZMP is calculated or determined based on a difference (full-model ZMP's error) between the calculated model's ZMP and the desired ZMP, whilst a corrected desired body position is calculated or determined. Since the robot posture is corrected by the calculated ZMP-converted value and the corrected desired body position, the corrected gait can satisfy the dynamic equilibrium condition accurately.

Abstract: A floor shape estimation system for a legged mobile robot, in particular a biped walking robot, which estimates a foot-to-foot floor inclination difference based on at least a control error of the total floor reaction force's moment and corrects a feet compensating angle based on the estimated value. Further, the system estimates a foot floor inclination difference based on at least a control error of the foot floor reaction force about a desired foot floor reaction force central point and corrects a foot compensating angle based on the estimated value. Furthermore, it determines whether it is in a situation where the accuracy of estimation is liable to degrade based on at least a time of the gait of the robot and when it is in the situation, the system interrupts the estimation. With this, the system can accurately estimate the shape of floor with which the robot is in contact.