Abstract: A robot operates accurately while canceling an affect of pitch-axis, rollaxis, and yaw-axis moments, these moments being applied on the robot body during a leg-moving operation such as walking. By calculating a pitch-axis moment and/or a roll-axis moment generated on the robot body at a preset ZMP by set motions of upper limbs, a trunk, and lower limbs, motions of the lower limbs and the trunk for canceling the pitch-axis moment and/or the roll-axis moment: are obtained. Then, by calculating a yaw-axis moment generated on the robot body lying at the preset ZMP by the calculated motions of the lower limbs and the trunk, a motion of the upper limbs for canceling the yaw-axis moment is obtained.

Abstract: A legged mobile robot possesses degrees of freedom which are provided at roll, pitch, and yaw axes at a trunk. By using these degrees of freedom which are provided at the trunk, the robot can smoothly get up from any fallen-down posture. In addition, by reducing the required torque and load on movable portions other than the trunk, and by spreading/averaging out the load between each of the movable portions, concentration of a load on a particular member is prevented from occurring. As a result, the robot is operated more reliably, and energy is used with greater efficiency during a getting-up operation. The invention makes it possible for the robot to independently, reliably, and smoothly get up from various fallen-down postures such as a lying-on-the-face posture, a lying-on-the-back posture, and a lying sideways posture.

Abstract: In a foot of a legged mobile robot, deformation of the foot is absorbed by a first concavity and the position and shape of a ground-contact portion hardly change. Accordingly, variation in a resistive force against the moment about the yaw axis can be reduced and a spinning motion can be prevented. In addition, when the foot is placed on a bump or a step, a flexible portion deforms and receives it, and a frictional retaining force is generated between the flexible portion and the bump. Thus, the foot is flexibly adapted to the road surface, and sliding caused by the bump and excessively fast motion are prevented. Accordingly, the foot can be adapted to various kinds of road surfaces such as surfaces having bumps and depressions, and the attitude stability can be increased.

Abstract: A predetermined action sequence is generated by using basic motion units which include time-sequential motion of each joint and compound motion units in which basic motion units are combined. Motion patterns of a robot including walking are classified into motion units, each motion unit serving as a unit of motion, and one or more motion units are combined to generate various complex motions. Dynamic motion units are defined on the basis of basic dynamic attitudes, and a desired action sequence can be generated by using the dynamic motion units. This is a basic control method necessary for a robot to autonomously perform a continuous motion, a series of continuous motions, or motions which are changed in real-time by commands.

Abstract: The lumbar part of a robot as a controlled-object point where the mass is moved to the largest extent is set as the origin of a local coordinate, an acceleration sensor is disposed at the controlled-object point to directly measure the attitude and acceleration at that position to control the robot to take a stable posture on the basis of a ZMP. Further, at each foot which touches the walking surface, there are provided a floor reaction force sensor and acceleration sensor to directly measure a ZMP and force, and a ZMP equation is formulated directly at the foot nearest to a ZMP position. Thus there can be implemented a stricter and quick control of the robot for a stable posture.

Abstract: The stability of attitude of a robot can be recovered by an ambulation control apparatus and an ambulation control method according to the invention if it is lost in the course of a gesture for which the upper limbs take a major role. The apparatus and the method obtain the pattern of movement of the entire body for walking by deriving the pattern of movement of the loins from an arbitrarily selected pattern of movement of the feet, the trajectory of the ZMP, the pattern of movement of the trunk and that of the upper limbs. Therefore, according to the invention, a robot can determine the gait of the lower limbs so as to realize a stable walk regardless if the robot is standing upright or walking. Particularly, if the robot is made to gesture, using the upper body half including the upper limbs and the trunk while standing upright, it can determine the gait of the lower limbs so as to make a stable walk in response to such a gait of the upper body half.

Abstract: The stability of attitude of a robot can be recovered by an ambulation control apparatus and an ambulation control method if it is lost in the course of a gesture for which the upper limbs take a major role. The apparatus and the method obtain the pattern of movement of the entire body for walking by deriving the pattern of movement of the loins from an arbitrarily selected pattern of movement of the feet, the trajectory of the ZMP, the pattern of movement of the trunk and that of the upper limbs. Therefore, a robot can determine the gait of the lower limbs so as to realize a stable walk regardless if the robot is standing upright or walking. Particularly, if the robot is made to gesture, using the upper body half including the upper limbs and the trunk while standing upright, it can determine the gait of the lower limbs so as to make a stable walk in response to such a gait of the upper body half.

Abstract: A ZMP equilibrium equation stating the relationship of various moments applied to a robot body of a robot, based on desirable motion data made up by trajectories of respective parts, imaginarily divided from the robot body, is generated, and moment errors in a ZMP equilibrium equation are calculated. A priority sequence of the parts, the target trajectories of which are corrected to cancel out the moment errors, is set. The target trajectories are corrected from one part to another, in a sequence corresponding to the priority sequence, to compensate the moment errors.

Abstract: To implement a dynamic, elegant motion performance of an actual robot, a motion editing system is provided which includes a motion editor to edit motions of an upper body and whole body of the robot and a foot trajectory editor to create a gait pattern and lower-body motion to stabilize the entire robot. The foot trajectory editor includes the same gait pattern generator and motion stabilized as those installed in the actual robot. Before performing the edited motions on the actual robot, the motions are created, corrected and stabilized on a 3D viewer.

Abstract: A legged mobile robot controls the posture of the body thereof in a stable manner using a ZMP stability determination criterion with a relatively long sampling period. The legged mobile robot has a stable ZMP region which is a supporting polygon formed of the ground contact point of a sole of a movable leg and a walking surface, and a ZMP behavior space in which a momentum of the robot body is generated so that the ZMP shifts to the approximate center of the stable ZMP region. In the ZMP behavior space, the momentum of the robot shifts in a positive direction or in a negative direction. In the negative direction, a space distortion shifts the ZMP to the periphery of the stable region, and in the positive direction, a space distortion shifts the ZMP to the center of the stable region.

Abstract: A robot to operate accurately while canceling an affect of pitch-axis, roll-axis, and yaw-axis moments, these moments being applied on the robot body during a leg-moving operation such as walking. First, by calculating a pitch-axis moment and/or a roll-axis moment generated on the robot body at a preset ZMP by set motions of upper limbs, a trunk, and lower limbs, motions of the lower limbs and the trunk for canceling the pitch-axis moment and/or the roll-axis moment are obtained. Then, by calculating a yaw-axis moment generated on the robot body lying at the preset ZMP by the calculated motions of the lower limbs and the trunk, a motion of the upper limbs for canceling the yaw-axis moment is obtained.

Abstract: In a foot of a legged mobile robot, deformation of the foot is absorbed by a first concavity and the position and shape of a ground-contact portion hardly change. Accordingly, variation in a resistive force against the moment about the yaw axis can be reduced and a spinning motion can be prevented. In addition, when the foot is placed on a bump or a step, a flexible portion deforms and receives it, and a frictional retaining force is generated between the flexible portion and the bump. Thus, the foot is flexibly adapted to the road surface, and sliding caused by the bump and excessively fast motion are prevented. Accordingly, the foot can be adapted to various kinds of road surfaces such as surfaces having bumps and depressions, and the attitude stability can be increased.

Abstract: A legged mobile robot gives up a normal walking motion and starts a tumbling motion when an excessively high external force or external moment is applied thereto and a behavior plan of a foot part thereof is disabled. At this time, the variation amount ?S/?t of the area S of a support polygon of the body per time t is minimized and the support polygon when the body drops onto a floor is maximized to distribute an impact which acts upon the body from the floor when the body drops onto the floor to the whole body to suppress the damage to the body to the minimum. Further, the legged mobile robot autonomously restores a standing up posture from an on-floor posture thereof such as a supine posture or a prone posture.

Abstract: The present invention allows a robot to operate accurately while canceling an affect of pitch-axis, roll-axis, and yaw-axis moments, these moments being applied on the robot body during a leg-moving operation such as walking. First, by calculating a pitch-axis moment and/or a roll-axis moment generated on the robot body at a preset ZMP by set motions of upper limbs, a trunk, and lower limbs, motions of the lower limbs and the trunk for canceling the pitch-axis moment and/or the roll-axis moment are obtained. Then, by calculating a yaw-axis moment generated on the robot body lying at the preset ZMP by the calculated motions of the lower limbs and the trunk, a motion of the upper limbs for canceling the yaw-axis moment is obtained.

Abstract: A predetermined action sequence is generated by using basic motion units which include time-sequential motion of each joint and compound motion units in which basic motion units are combined. Motion patterns of a robot including walking are classified into motion units, each motion unit serving as a unit of motion, and one or more motion units are combined to generate various complex motions. Dynamic motion units are defined on the basis of basic dynamic attitudes, and a desired action sequence can be generated by using the dynamic motion units. This is a basic control method necessary for a robot to autonomously perform a continuous motion, a series of continuous motions, or motions which are changed in real-time by commands.

Abstract: A legged mobile robot possesses degrees of freedom which are provided at roll, pitch, and yaw axes at a trunk. By using these degrees of freedom which are provided at the trunk, the robot can smoothly get up from any fallen-down posture. In addition, by reducing the required torque and load on movable portions other than the trunk, and by spreading/averaging out the load between each of the movable portions, concentration of a load on a particular member is prevented from occurring. As a result, the robot is operated more reliably, and energy is used with greater efficiency during a getting-up operation. The robot independently, reliably, and smoothly gets up from various fallen-down postures such as a lying-on-the-face posture, a lying-on-the-back posture, and a lying sideways posture.

Abstract: A legged mobile robot is adaptively controlled in its attitude against variable external forces to continue the operation without inversion. When the legged mobile robot kicks an object having a certain mass, such as a ball, the robot is to be prevented from being fallen down by the reactive force from the object. Even if the mass or the repulsion coefficient of the object kicked is unknown, the operation of kicking the object at a sufficiently low speed is carried out at the outset to predict the reactive force produced on actual kicking in order to predict the reactive force produced on actual kicking. The result is that the stability in attitude can be maintained on kicking at an arbitrary speed. The legged mobile robot is able to take part as one of the players in athletic games, such as soccer games, in which each player performs his or her role as the or she is subjected to an external force.

Abstract: A legged mobile robot itself is responsive to the result of error detection during robot operations to perform error avoiding processing autonomously. In detecting an error, requested commands are all blocked by the internal processing within the robot so that an input to an actuating system does not affect the robot. The type of the error that has occurred is also notified to the actuating system so that feedback to an inputting system 32 may be applied in a manner specific to the error type. When the error is eliminated, that effect is notified to the actuating system to enable re-initiation of the usual command input from the remote operating system.

Abstract: A legged mobile robot having having at least a plurality of movable legs. This robot includes, in addition to a road surface touching sensor for confirming the ground touching state between the foot part and the road surface, a relative movement measurement sensor for measuring the relative movement between the foot part and the road surface. The robot has its operation controlled on the basis of the amount of relative movement between the foot part and the road surface, so that, when an offset is produced between the intended or scheduled trajectory and the actual trajectory, the operation may be controlled adaptively to execute the robot operation.

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 &Dgr;S/&Dgr;t as a reference in controlling the falldown motions of the robot body to increase the motion stability.