Keisuke Suga
Keisuke Suga, Aichi-Ken JP
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20080258669 | Walking Robot by Using Passive Changes in Joint Angles and Control Method Thereof - In a robot with two or more leg links having ankle joint respectively and pivotably linked to a torso, the robot walks naturally by making the ankle joint of a grounded leg link rotate freely by using passive movement. A controller executes controlling operation of calculating target joint angles of remaining joints other than the ankle joint of the grounded leg link based upon the measured joint angles of the ankle joint of the grounded leg link in the lateral and forward direction. The target joint angles of the remaining joints are calculated so as to satisfy the following condition that a tilting angle of the torso matches a target tilting angle determined based upon the measured joint angle of the ankle joint of the grounded leg link in the forward direction, a cycle period of the idle leg link from lifting to grounding, and a target stride of the idle leg link. | 10-23-2008 |
20090187275 | Legged Robot and Control Method Thereof - Technology is provided that can compute a center of gravity pathway for a robot in which the ZMP matches the target ZMP, even if the robot is caused to perform a crouching movement during a single leg ground phase. The robot of the present invention is a legged robot that moves the center of gravity in the vertical direction when one leg link is grounded by changing joint angles, and comprises means for generating the vertical pathway of the center of gravity, means for computing the horizontal pathway of the center of gravity, based upon the generated vertical pathway of the center of gravity, a tridiagonal equation which is a discretization of a ZMP equation, a target ZMP, and horizontal speeds of the center of gravity at the beginning and the completion of the vertical pathway, means for computing chronological data of target values of the joint angles, based upon the generated vertical pathway and the computed horizontal pathway of the center of gravity, and means for rotating the joints based upon the computed chronological data of the target values of the joint angles. | 07-23-2009 |
20090260472 | LEGGED ROBOT - A legged robot is provided whose trunk link is not prone to wobble in the front-back direction during walking. The legged robot is equipped with a trunk link and a pair of legs. Each leg has a pitch joint capable of rotating the connected links in a plane that intersects with a line extending in a lateral direction of the robot. Rotation centers of the pitch joints are located above a center of gravity of the trunk link. The legged robot walks mainly by swinging the legs backward and forward around such rotation centers. Hence, the trunk link wobbles mainly in the front-back direction around the rotation centers as the robot walks. Because the center of gravity of the trunk link is located below the rotation centers, the gravitational force acting on the trunk link acts in a direction to suppress swinging of the trunk link during walking. Due to this, the trunk link of the legged robot is not prone to wobble in the front-back direction during walking. | 10-22-2009 |
20100017028 | LEGGED ROBOT - A legged robot that runs while repeating a jump cycle including a ground-contact phase from a landing to a takeoff and an aerial phase from a takeoff to a landing is provided. The legged robot adjusts the landing timing after a jump in accordance with a planned timing, thereby attaining a smooth landing. A measuring unit of the legged robot measures an actual aerial phase period in a k-th jump cycle. A subtractor calculates a time difference between a target aerial phase period and the actual aerial phase period in the k-th jump cycle. A target velocity determining unit calculates a target vertical velocity of a center of gravity on a takeoff timing in a (k+1)-th jump cycle so as to eliminate the time difference. Motors in respective joints are controlled so as to realize the calculated target vertical velocity in the (k+1)-th jump cycle. As a result, the time difference generated in the k-th jump cycle in the (k+1)-th jump cycle can be compensated, thereby adjusting the landing timing with the planned landing timing, resulting in the jump motion with smooth landing. | 01-21-2010 |
Keisuke Suga, Toyota-Shi JP
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20090276997 | METHOD OF PRODUCING COIL MADE UP OF RECTANGULAR WAVE-SHAPED WINDINGS - A method of producing a coil which comprises steps of bending each of straight coil wires into a rectangular wave shape including in-slot portions to be disposed in slots of a stator core and turned portions connecting between the in-slot portions, turning a coil bend-forming portion that is one of the in-slot portions of each coil wire which becomes a folded bend of a phase winding by 180° around an axis thereof, twisting the turned portions of the coil wires together to weave the coil wires into a wire bundle, and folding the wire bundle at the coil bend-forming portions of the coil wires to place sides of the wire bundle to overlap each other to make the coil, thereby eliminating the 180° twisting of the coil bend-forming portions to produce the coil without any undesirable deformation of the phase windings. | 11-12-2009 |
Keisuke Suga, Nishikamo-Gun JP
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20090069940 | LEGGED ROBOT AND ITS CONTROL METHOD - There is provided a legged robot that performs motion by changing a joint angle, which includes a section of generating a center-of-gravity trajectory of the legged robot based on a trinomial equation obtained by discretizing a ZMP equation and a target ZMP, a section of calculating time-varying data of a target value of the joint angle based on the generated center-of-gravity trajectory, and a section of rotating a joint of the legged robot based on the calculated time-varying data of a target value of the joint angle, wherein the ZMP equation involves an angular momentum according to a center-of-gravity velocity. | 03-12-2009 |
20090069941 | LEGGED ROBOT AND ITS CONTROL METHOD - There is provided a legged robot that performs motion by changing a joint angle, which includes a trajectory generating section to calculate a center-of-gravity trajectory in designated stepping motion from the stepping motion including at least one of walking motion, running motion and stopping motion, and generate a center-of-gravity trajectory by superimposing a designated travel velocity onto a travel velocity of a center of gravity in the calculated center-of-gravity trajectory in stepping motion, and a trajectory updating section to store the generated center-of-gravity trajectory and update all the stored center-of-gravity trajectories so as to be continuous, and a trajectory reproducing section to calculate time-varying data of a target value of the joint angle based on the updated center-of-gravity trajectory, and a joint driving section to rotate a joint of the legged robot based on the calculated time-varying data of a target value of the joint angle. | 03-12-2009 |
Keisuke Suga, Aichi JP
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20090009124 | Legged Robot - A legged robot that can ensure a large step length while keeping the height of a body trunk at a low position without increasing a moment that is generated due to the gravitational force acting on the trunk and acting on roll joints of legs when standing on one leg is realized. In the legged robot, a pair of legs is connected so as to be able to rotate around a pitch axis (Y-axis) at lateral surfaces of a trunk. Thereby, it is possible to make the height H | 01-08-2009 |
Keisuke Suga, Minamitsuru-Gun JP
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20120296469 | SUCKING-CONVEYING DEVICE HAVING VISION SENSOR AND SUCTION UNIT - A sucking-conveying device capable of sequentially and efficiently taking out and conveying a workpiece one-by-one, even when a taking-out means attached to the robot is not correctly positioned relative to a workpiece to be taken out. The sucking-conveying device includes a robot and a vision sensor capable of detecting a plurality of workpieces randomly located in a container. A suction nozzle, configured to suck and take out the workpieces one-by-one, is mounted on the robot. By attaching the nozzle to a robot arm, the position and orientation of the nozzle may be changed. The suction nozzle is fluidly connected to a suction unit via a blow member. The suction unit sucks air through the nozzle, and generates suction force at the nozzle for sucking a target workpiece to be taken out toward the nozzle, whereby the nozzle can suck and hold the target workpiece. | 11-22-2012 |
Keisuke Suga, Yamanahsi JP
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20150231785 | ROBOT SYSTEM FOR PREVENTING ACCIDENTAL DROPPING OF CONVEYED OBJECTS - A robot system comprises a robot provided with a robot arm and a robot hand, and a control device for controlling the motion of the robot, wherein a permitted area where a teaching operation for the robot hand should be permitted is preset within a maximum area which the robot hand can reach. The control device is provided with a judging part which judges if the robot hand as a whole is present in the permitted area, based on robot hand position information, and a teaching operation restricting part which permits a teaching operation for the robot hand when it is judged that the robot hand as a whole is present in the permitted area and prohibits a teaching operation for the robot hand when it is judged that the robot hand as a whole is not present in the permitted area. | 08-20-2015 |