Patents by Inventor Yonatan Gefen
Yonatan Gefen has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Publication number: 20240091953Abstract: A method for controlling a robotic system includes determining a location and/or a pose of a power system component based on data received from one or more sensors, and determining a mapping of a location of a robotic system within a model of an external environment of the robotic system based on the data. The model of the external environment provides locations of objects external to the robotic system. A sequence of movements of components of the robotic system is determined to perform maintenance on the power system component based on the locations of the objects external to the robotic system and/or the location or pose of the power system component. One or more control signals are communicated to remotely control movement of the components of the robotic system based on the sequence or movements of the components to perform maintenance on the power system component.Type: ApplicationFiled: November 30, 2023Publication date: March 21, 2024Inventors: Romano Patrick, Shiraj Sen, Arpit Jain, Huan Tan, Yonatan Gefen, Shuai Li, Shubao Liu, Pramod Sharma, Balajee Kannan, Viktor Holovashchenko, Douglas Forman, John Michael Lizzi, Charles Burton Theurer, Omar Al Assad, Ghulam Ali Baloch, Frederick Wilson Wheeler, Tai-Peng Tian
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Patent number: 11865732Abstract: A robotic system includes a controller configured to obtain image data from one or more optical sensors and to determine one or more of a location and/or pose of a vehicle component based on the image data. The controller also is configured to determine a model of an external environment of the robotic system based on the image data and to determine tasks to be performed by components of the robotic system to perform maintenance on the vehicle component. The controller also is configured to assign the tasks to the components of the robotic system and to communicate control signals to the components of the robotic system to autonomously control the robotic system to perform the maintenance on the vehicle component.Type: GrantFiled: April 30, 2021Date of Patent: January 9, 2024Assignee: Transportation IP Holdings, LLCInventors: Romano Patrick, Shiraj Sen, Arpit Jain, Huan Tan, Yonatan Gefen, Shuai Li, Shubao Liu, Pramod Sharma, Balajee Kannan, Viktor Holovashchenko, Douglas Forman, John Michael Lizzi, Charles Burton Theurer, Omar Al Assad, Ghulam Ali Baloch, Frederick Wilson Wheeler, Tai-Peng Tian
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Publication number: 20210252712Abstract: A robotic system includes a controller configured to obtain image data from one or more optical sensors and to determine one or more of a location and/or pose of a vehicle component based on the image data. The controller also is configured to determine a model of an external environment of the robotic system based on the image data and to determine tasks to be performed by components of the robotic system to perform maintenance on the vehicle component. The controller also is configured to assign the tasks to the components of the robotic system and to communicate control signals to the components of the robotic system to autonomously control the robotic system to perform the maintenance on the vehicle component.Type: ApplicationFiled: April 30, 2021Publication date: August 19, 2021Inventors: Romano Patrick, Shiraj Sen, Arpit Jain, Huan Tan, Yonatan Gefen, Shuai Li, Shubao Liu, Pramod Sharma, Balajee Kannan, Viktor Holovashchenko, Douglas Forman, John Michael Lizzi, Charles Burton Theurer, Omar Al Assad, Ghulam Ali Baloch, Frederick Wilson Wheeler, Tai-Peng Tian
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Patent number: 11020859Abstract: A robotic system includes a controller configured to obtain image data from one or more optical sensors and to determine one or more of a location and/or pose of a vehicle component based on the image data. The controller also is configured to determine a model of an external environment of the robotic system based on the image data and to determine tasks to be performed by components of the robotic system to perform maintenance on the vehicle component. The controller also is configured to assign the tasks to the components of the robotic system and to communicate control signals to the components of the robotic system to autonomously control the robotic system to perform the maintenance on the vehicle component.Type: GrantFiled: January 4, 2019Date of Patent: June 1, 2021Assignee: TRANSPORTATION IP HOLDINGS, LLCInventors: Romano Patrick, Shiraj Sen, Arpit Jain, Huan Tan, Yonatan Gefen, Shuai Li, Shubao Liu, Pramod Sharma, Balajee Kannan, Viktor Holovashchenko, Douglas Forman, John Michael Lizzi, Charles Burton Theurer, Omar Al Assad, Ghulam Ali Baloch, Frederick Wilson Wheeler, Tai-Peng Tian
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Patent number: 10675765Abstract: Systems and methods are provided for an automation system. The systems and methods calculate a motion trajectory of a manipulator and an end-effector. The end-effector is configured to grasp a target object. The motion trajectory defines successive positions of the manipulator and the end-effector along a plurality of via-points toward the target object. The systems and methods further acquire force/torque (F/T) data from an F/T sensor associated with the end-effector, and adjusts the motion trajectory based on the F/T data.Type: GrantFiled: March 4, 2019Date of Patent: June 9, 2020Assignee: GENERAL ELECTRIC COMPANYInventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Romano Patrick, Balajee Kannan, Yonatan Gefen
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Publication number: 20200039076Abstract: A robotic system is provided that includes a base, an articulable arm, a visual acquisition unit, and a controller. The articulable arm may extend from a base and is movable toward a target. The visual acquisition unit can be mounted to the arm or the base and to acquire image data. The controller is operably coupled to the arm and the visual acquisition unit, and can derive from the image data environmental information corresponding to at least one of the arm or the target. The controller further can generate at least one planning scheme using the environmental information to translate the arm toward the target, select at least one planning scheme for implementation, and control movement of the arm toward the target using the at least one selected planning scheme.Type: ApplicationFiled: October 8, 2019Publication date: February 6, 2020Inventors: Huan Tan, Balajee Kannan, Yonatan Gefen, Romano Patrick, Omar Al Assad, Douglas Forman, Charles Theurer, John Lizzi, Bradford Wayne Miller, James D. Brooks, Neeraja Subrahmaniyan
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Patent number: 10471595Abstract: A robot system is provided that includes a base, an articulable arm, a visual acquisition unit, and at least one processor. The articulable arm extends from the base and is configured to be moved toward a target. The visual acquisition unit is mounted to the arm or the base, and acquires environmental information. The at least one processor is operably coupled to the arm and the visual acquisition unit, the at least one processor configured to: generate an environmental model using the environmental information; select, from a plurality of planning schemes, using the environmental model, at least one planning scheme to translate the arm toward the target; plan movement of the arm toward the target using the selected at least one planning scheme; and control movement of the arm toward the target using the at least one selected planning scheme.Type: GrantFiled: October 14, 2016Date of Patent: November 12, 2019Assignee: GE GLOBAL SOURCING LLCInventors: Huan Tan, Balajee Kannan, Yonatan Gefen, Romano Patrick, Omar Al Assad, Douglas Forman, Charles Theurer, John Lizzi
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Publication number: 20190193275Abstract: Systems and methods are provided for an automation system. The systems and methods calculate a motion trajectory of a manipulator and an end-effector. The end-effector is configured to grasp a target object. The motion trajectory defines successive positions of the manipulator and the end-effector along a plurality of via-points toward the target object. The systems and methods further acquire force/torque (F/T) data from an F/T sensor associated with the end-effector, and adjusts the motion trajectory based on the F/T data.Type: ApplicationFiled: March 4, 2019Publication date: June 27, 2019Inventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Romano Patrick, Balajee Kannan, Yonatan Gefen
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Publication number: 20190134821Abstract: A robotic system includes a controller configured to obtain image data from one or more optical sensors and to determine one or more of a location and/or pose of a vehicle component based on the image data. The controller also is configured to determine a model of an external environment of the robotic system based on the image data and to determine tasks to be performed by components of the robotic system to perform maintenance on the vehicle component. The controller also is configured to assign the tasks to the components of the robotic system and to communicate control signals to the components of the robotic system to autonomously control the robotic system to perform the maintenance on the vehicle component.Type: ApplicationFiled: January 4, 2019Publication date: May 9, 2019Inventors: Romano Patrick, Shiraj Sen, Arpit Jain, Huan Tan, Yonatan Gefen, Shuai Li, Shubao Liu, Pramod Sharma, Balajee Kannan, Viktor Holovashchenko, Douglas Forman, John Michael Lizzi, Charles Burton Theurer, Omar Al Assad, Ghulam Ali Baloch, Frederick Wilson Wheeler, Tai-Peng Tian
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Patent number: 10272573Abstract: Systems and methods are provided for an automation system. The systems and methods calculate a motion trajectory of a manipulator and an end-effector. The end-effector is configured to grasp a target object. The motion trajectory defines successive positions of the manipulator and the end-effector along a plurality of via-points toward the target object. The systems and methods further acquire force/torque (F/T) data from an F/T sensor associated with the end-effector, and adjusts the motion trajectory based on the F/T data.Type: GrantFiled: March 2, 2016Date of Patent: April 30, 2019Assignee: GE GLOBAL SOURCING LLCInventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Romano Patrick, Balajee Kannan, Yonatan Gefen
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Patent number: 10029372Abstract: A system includes a machine assembly, an imaging sensor, an encoder, and one or more processors. The machine assembly is movable to actuate a brake lever of a vehicle in order to open a valve of an air brake system of the vehicle. The imaging sensor acquires perception information of a working environment that includes the brake lever. The encoder detects a displaced position of the machine assembly relative to a reference position of the machine assembly. The one or more processors detect a position of the brake lever relative to the machine assembly based on the acquired perception information and the detected displacement of the arm. The one or more processors generate a motion trajectory for the machine assembly that provides a path to the brake lever. The one or more processors drive movement of the machine assembly along the motion trajectory towards the brake lever.Type: GrantFiled: December 11, 2015Date of Patent: July 24, 2018Assignee: GENERAL ELECTRIC COMPANYInventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Mauricio Castillo-Effen, Romano Patrick, Balajee Kannan, Yonatan Gefen
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Patent number: 9902071Abstract: A system is provided that includes a machine assembly, a first imaging sensor, an encoder, and one or more processors. The machine assembly is movable to actuate a brake lever of a vehicle in order to open a valve of an air brake system. The first imaging sensor is positioned to acquire two-dimensional perception information of a working environment that includes the brake lever during movement of the machine assembly towards the brake lever. The encoder detects a displacement of the machine assembly relative to a reference position of the machine assembly. The one or more processors estimate a target position of the brake lever relative to the machine assembly during movement of the machine assembly based on the two-dimensional perception information and the displacement. The one or more processors drive the movement of the machine assembly towards the target position of the brake lever.Type: GrantFiled: March 2, 2016Date of Patent: February 27, 2018Assignee: General Electric CompanyInventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Romano Patrick, Balajee Kannan, Yonatan Gefen
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Publication number: 20170341236Abstract: A robotic system includes a controller configured to obtain image data from one or more optical sensors and to determine one or more of a location and/or pose of a vehicle component based on the image data. The controller also is configured to determine a model of an external environment of the robotic system based on the image data and to determine tasks to be performed by components of the robotic system to perform maintenance on the vehicle component. The controller also is configured to assign the tasks to the components of the robotic system and to communicate control signals to the components of the robotic system to autonomously control the robotic system to perform the maintenance on the vehicle component.Type: ApplicationFiled: October 13, 2016Publication date: November 30, 2017Inventors: Romano Patrick, Shiraj Sen, Arpit Jain, Huan Tan, Yonatan Gefen, Shuai Li, Shubao Liu, Pramod Sharma, Balajee Kannan, Viktor Holovashchenko, Douglas Forman, John Michael Lizzi, Charles Burton Theurer, Omar Al Assad, Ghulam Ali Baloch, Frederick Wheeler
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Publication number: 20170341231Abstract: A robot system is provided that includes a base, an articulable arm, a visual acquisition unit, and at least one processor. The articulable arm extends from the base and is configured to be moved toward a target. The visual acquisition unit is mounted to the arm or the base, and acquires environmental information. The at least one processor is operably coupled to the arm and the visual acquisition unit, the at least one processor configured to: generate an environmental model using the environmental information; select, from a plurality of planning schemes, using the environmental model, at least one planning scheme to translate the arm toward the target; plan movement of the arm toward the target using the selected at least one planning scheme; and control movement of the arm toward the target using the at least one selected planning scheme.Type: ApplicationFiled: October 14, 2016Publication date: November 30, 2017Inventors: Huan Tan, Balajee Kannan, Yonatan Gefen, Romano Patrick, Omar Al Assad, Douglas Forman, Charles Theurer, John Lizzi
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Patent number: 9799198Abstract: Method includes executing a dynamic decision-making process that includes (a) receiving environmental data and (b) determining a fused ensemble based on the environmental data and a state parameters of a current state of a machine assembly. The fused ensemble includes communications from a system interface to the operator for the state parameters. The communications inform an operator about the state parameters and includes at least one of a visual signal, an audible signal, or a tactile signal from the system interface. The decision-making process also includes (c) communicating the fused ensemble to the operator through the system interface and (d) repeating (a)-(c) while the machine assembly is in the current state. The fused ensemble is configured to change based on changes in the environmental data.Type: GrantFiled: March 2, 2016Date of Patent: October 24, 2017Assignee: General Electric CompanyInventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Romano Patrick, Viktor Holovashchenko, Balajee Kannan, Yonatan Gefen
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Publication number: 20170173790Abstract: Systems and methods are provided for an automation system. The systems and methods calculate a motion trajectory of a manipulator and an end-effector. The end-effector is configured to grasp a target object. The motion trajectory defines successive positions of the manipulator and the end-effector along a plurality of via-points toward the target object. The systems and methods further acquire force/torque (F/T) data from an F/T sensor associated with the end-effector, and adjusts the motion trajectory based on the F/T data.Type: ApplicationFiled: March 2, 2016Publication date: June 22, 2017Inventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Romano Patrick, Balajee Kannan, Yonatan Gefen
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Publication number: 20170178485Abstract: Method includes executing a dynamic decision-making process that includes (a) receiving environmental data and (b) determining a fused ensemble based on the environmental data and a state parameters of a current state of a machine assembly. The fused ensemble includes communications from a system interface to the operator for the state parameters. The communications inform an operator about the state parameters and includes at least one of a visual signal, an audible signal, or a tactile signal from the system interface. The decision-making process also includes (c) communicating the fused ensemble to the operator through the system interface and (d) repeating (a)-(c) while the machine assembly is in the current state. The fused ensemble is configured to change based on changes in the environmental data.Type: ApplicationFiled: March 2, 2016Publication date: June 22, 2017Inventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Romano Patrick, Viktor Holovashchenko, Balajee Kannan, Yonatan Gefen
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Publication number: 20170173795Abstract: A system is provided that includes a machine assembly, a first imaging sensor, an encoder, and one or more processors. The machine assembly is movable to actuate a brake lever of a vehicle in order to open a valve of an air brake system. The first imaging sensor is positioned to acquire two-dimensional perception information of a working environment that includes the brake lever during movement of the machine assembly towards the brake lever. The encoder detects a displacement of the machine assembly relative to a reference position of the machine assembly. The one or more processors estimate a target position of the brake lever relative to the machine assembly during movement of the machine assembly based on the two-dimensional perception information and the displacement. The one or more processors drive the movement of the machine assembly towards the target position of the brake lever.Type: ApplicationFiled: March 2, 2016Publication date: June 22, 2017Inventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Romano Patrick, Balajee Kannan, Yonatan Gefen
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Publication number: 20170165839Abstract: A system includes a machine assembly, an imaging sensor, an encoder, and one or more processors. The machine assembly is movable to actuate a brake lever of a vehicle in order to open a valve of an air brake system of the vehicle. The imaging sensor acquires perception information of a working environment that includes the brake lever. The encoder detects a displaced position of the machine assembly relative to a reference position of the machine assembly. The one or more processors detect a position of the brake lever relative to the machine assembly based on the acquired perception information and the detected displacement of the arm. The one or more processors generate a motion trajectory for the machine assembly that provides a path to the brake lever. The one or more processors drive movement of the machine assembly along the motion trajectory towards the brake lever.Type: ApplicationFiled: December 11, 2015Publication date: June 15, 2017Inventors: Huan Tan, John Michael Lizzi, Douglas Forman, Charles Burton Theurer, Omar Al Assad, Mauricio Castillo-Effen, Romano Patrick, Balajee Kannan, Yonatan Gefen