Patent application number | Description | Published |
20090308668 | Walking robot and method of controlling the same - Disclosed are a walking robot and a method of controlling the same, in which impedance control and torso tilt control are achieved complementarily such that impedance can be adjusted according to the tilt of a torso or the tilt of the torso can be adjusted according to the impedance. The method includes measuring a moment of a foot; measuring a tilt of a torso; adjusting the scale of the measured moment based on the tilt of the torso, and controlling the foot based on the scale-adjusted moment; and adjusting the scale of the measured tilt based on a ZMP variation amount of the foot, and controlling the tilt of the torso based on the scale-adjusted ZMP variation amount. | 12-17-2009 |
20090319082 | ROBOT AND METHOD OF CONTROLLING WALKING THEREOF - A method of controlling walking a biped robot to generate a walking pattern maximally similar to that of a human includes generating a walking pattern, calculating a walking pattern similarity corresponding to the walking pattern, and comparing the walking pattern similarity with a predetermined reference pattern similarity, and changing the walking pattern based on a result of the comparison. When the robot walks, a knee is maximally stretched and a horizontal movement of a waist is minimized such that the walking pattern of the robot is maximally similar to that of a human, thus enhancing an affinity for a human being and increasing energy efficiency. | 12-24-2009 |
20120143372 | ROBOT AND METHOD FOR PLANNING PATH OF THE SAME - A robot and a method for planning a path of the robot. The method includes storing coordinates of a base cell in a queue structure, setting a plurality of cells adjacent to the base cell as scan cells, calculating a movement direction of the robot from the base cell to each of the scan cells, calculating movement cost of each of the scan cells according to the calculated movement direction, comparing the calculated movement cost and movement cost previously stored in each of the scan cells and determining whether or not coordinates of each of the scan cells are stored in the queue structure, and repeatedly performing a process of recording the movement direction and the movement cost in each of the scan cells and building a map of the movement space of the robot if the coordinates of each of the scan cells are stored in the queue structure. | 06-07-2012 |
20130175956 | APPARATUS AND METHOD TO CONTROL BLDC MOTOR - An apparatus and method to control a brushless direct current (BLDC) motor, which accurately detect driving current. To this end, the BLDC motor control apparatus includes a BLDC motor, a driver to generate driving current to drive the BLDC motor, a current measurer to measure the driving current, a pulse width modulator to change a driving voltage to drive the BLDG motor; and a controller to control the BLDC motor. The controller detects the amount of the driving current in synchronization with pulse width modulation of the pulse width modulator and determines current with a minimum change due to a variation of counter electromotive force, among currents flowing through a plurality of coils, as the driving current, thereby accurately detecting the driving current. | 07-11-2013 |
20130178868 | SURGICAL ROBOT AND METHOD FOR CONTROLLING THE SAME - A surgical robot includes a console and a manipulator assembly. The manipulator assembly includes at least one arm having a plurality of links and a motor provided between links adjacent to each other among the plurality of links, and a control unit configured to determine whether a mode is changed between a tele-operation mode and a manual mode. The control unit sets output data of the motor provided before the mode is changed as input data of the motor provided after the mode is changed, if it is determined that the mode is changed between the tele-operation mode and the manual mode, thereby preventing the vibration and the rapid change of the posture from occurring at the arm of the surgical robot during the change of the mode between the manual mode and the tele-operation mode, thereby increasing stability of the surgical robot. | 07-11-2013 |
20150088269 | WEARABLE ROBOTS AND CONTROL METHODS THEREOF - A wearable robot may comprise: a robot unit including machinery configured to assist a wearer's muscular strength; at least one first sensor provided on the wearer's knees and configured to detect the wearer's motion of pressing the wearer's knees; and/or a controller configured to judge whether or not the wearer intends to stand up based on information detected using the at least one first sensor, and configured to transmit a control signal to assist corresponding muscular strength to the robot unit upon judging that the wearer intends to stand up. | 03-26-2015 |
20150134080 | WEARABLE ROBOT AND METHOD FOR CONTROLLING THE SAME - A wearable robot may include a gear part having an exoskeleton structure to be worn on legs of a user, a sensor part including a first electromyogram (EMG) sensor attached at a first location of at least one leg of the user, and a second EMG sensor attached at a second location, and a controller to detect a walking assist starting point to assist the user with walking, based on a first EMG signal detected by the first EMG sensor and a second EMG signal detected by the second EMG sensor. | 05-14-2015 |
20160113830 | SUPPORTING MODULE, MOTION ASSISTANCE APPARATUS INCLUDING THE SUPPORTING MODULE, AND METHOD OF CONTROLLING THE MOTION ASSISTANCE APPARATUS - Supporting modules, motion assistance apparatuses including the supporting module, and/or methods of controlling the motion assistance apparatus may be disclosed. The supporting module including a supporting member configured to cover at least a portion of a support object, and a sensor module configured to sense information regarding whether the support object is out of a neutral position with respect to the supporting member may be provided. | 04-28-2016 |