The present invention relates to methods for learning a robot task and robots systems using the same. A robot system may include a robot configured to perform a task, and detect force information related to the task, a haptic controller configured to be manipulatable for teaching the robot, the haptic controller configured to output a haptic feedback based on the force information while teaching of the task to the robot is performed, a sensor configured to sense first information related to a task environment of the robot and second information related to a driving state of the robot, while the teaching is performed by the haptic controller for outputting the haptic feedback, and a computer configured to learn a motion of the robot related to the task, by using the first information and the second information, such that the robot autonomously performs the task.

The technology disclosed herein enables presentation of haptic alerts to a user (e.g., agent, supervisor, or other human resource of a contact center) regarding events of a contact center. In a particular embodiment, a method provides identifying a first event at a user system operated by the user. The first event is associated with operation of a contact center staffed with a plurality of agents. The method further provides determining that a first haptic alert corresponds to the first event and directing a haptic device in contact with the user's body to generate the first haptic alert for the user.

An intuitive control system for lifting equipment is described. The intuitive control system translates user defined inputs into machine expressions of movement that are in turn used to control a construction lift or similar piece of construction equipment. Orientation and relative position sensors may be incorporated into the translation and control system for correct user control of the lifting equipment in various operating conditions.

The application relates to a haptic system comprising a haptic device that has an end effector terminal and a transmission structure which can generate a translational movement as an output variable, said translational movement extending from the transmission structure to the end effector terminal via a boom such that the end effector terminal moves in a manner that is perceptible to a user, the transmission structure being formed by means of driven linear shafts. The application further relates to a method for operating a haptic system comprising a haptic device.

The various embodiments herein relate to robotic surgical systems and devices that use force and/or torque sensors to measure forces applied at various components of the system or device. Certain implementations include robotic surgical devices having one or more force/torque sensors that detect or measure one or more forces applied at or on one or more arms. Other embodiments relate to systems having a robotic surgical device that has one or more sensors and an external controller that has one or more motors such that the sensors transmit information that is used at the controller to actuate the motors to provide haptic feedback to a user.

The various embodiments herein relate to robotic surgical systems and devices that use force and/or torque sensors to measure forces applied at various components of the system or device. Certain implementations include robotic surgical devices having one or more force/torque sensors that detect or measure one or more forces applied at or on one or more arms. Other embodiments relate to systems having a robotic surgical device that has one or more sensors and an external controller that has one or more motors such that the sensors transmit information that is used at the controller to actuate the motors to provide haptic feedback to a user.

Systems and methods for minimal haptic implementation are disclosed. For example, one disclosed system includes: an actuator; and a control-circuit in communication with the actuator, the control circuit configured to: receive a haptic signal including a first bit indicating a power state; and transmit a power signal based on the haptic signal, the power signal configured to cause the actuator to operate at an actuation state at a fixed power.

An intuitive control system for lifting equipment is described. The intuitive control system translates user defined inputs into machine expressions of movement that are in turn used to control a construction lift or similar piece of construction equipment. Orientation and relative position sensors may be incorporated into the translation and control system for correct user control of the lifting equipment in various operating conditions.

The various embodiments herein relate to robotic surgical systems and devices that use force and/or torque sensors to measure forces applied at various components of the system or device. Certain implementations include robotic surgical devices having one or more force/torque sensors that detect or measure one or more forces applied at or on one or more arms. Other embodiments relate to systems having a robotic surgical device that has one or more sensors and an external controller that has one or more motors such that the sensors transmit information that is used at the controller to actuate the motors to provide haptic feedback to a user.

Systems and methods for minimal haptic implementation are disclosed. For example, one disclosed system includes: an actuator; and a control-circuit in communication with the actuator, the control circuit configured to: receive a haptic signal including a first bit indicating a power state; and transmit a power signal based on the haptic signal, the power signal configured to cause the actuator to operate at an actuation state at a fixed power.