Abstract: A method identifies an anomaly condition in operating a hand-held, mechanically unconstrained master device for controlling a robotic system for medical or surgical teleoperation. The method includes detecting or calculating the velocity vector of a point belonging to or integral with the master device, or of a virtual point uniquely and rigidly associated with the master device. A detectable anomaly condition is identified and recognized and/or discriminated based on the detected velocity vector, or based on a vector component. The detectable anomalies include master device excessive angular or linear velocity, inability to follow by the slave device, excessive vibrations or involuntary or abnormal opening of the master device. Each detectable anomaly is associated with a system state change to be performed if the anomaly is detected. The state change includes exiting or suspension from the teleoperation state. A robotic system for medical or surgical teleoperation performs the method.

Abstract: A method is for identifying at least one anomaly condition in using a hand-held, mechanically unconstrained master device to control a robotic system for medical or surgical teleoperation. The method includes detecting, by sensor(s), the position vector of a point belonging to or integral with the master device, or of a virtual point uniquely and rigidly associated with the master device. A detectable anomaly is identified based on the detected position vector, or based on a component of the detected position vector. The detectable anomalies include at least an incorrect positioning of the master device with respect to a predetermined workspace of the master device. Each of such detectable anomalies is associated with a system state change to be performed if the anomaly is detected, in which the state change includes exiting from the teleoperation state. A robotic system for medical or surgical teleoperation performs the method.

Abstract: A method for identifies an anomaly condition in using a hand-held, mechanically unconstrained master device to control a robotic system for medical or surgical teleoperation. The method includes detecting and/or calculating, by sensors, the acceleration vector of a point belonging to or integral with a master device, or of a virtual point uniquely and rigidly associated with the master device; and then identifying a detectable anomaly condition based on a component or modulus of the detected and/or calculated acceleration vector. The detectable anomalies include one or more of the following: involuntary drop of the master device and/or excessive acceleration of the master device, and/or sudden and/or involuntary opening of the master device. Each of the detectable anomalies is associated with a system state change to be performed if the anomaly is detected. A master-slave robotic system for medical or surgical teleoperation is equipped to perform the method.

Abstract: A method verifies functional/structural integrity of a hand-held unconstrained master device to control a robotic system for medical or surgical teleoperation. The master device includes a body having two rigid parts constrained to relatively rotate or translate on a common axis. Position vectors of two-plus points are measured and/or detected, each belonging to a respective one of the two rigid parts, and measuring and/or detecting evolution of the position vectors. An orientation of each of the points, and the evolution of the orientations are measured and/or detected. Constraints from constructional/structural features of the master device are defined, deriving from degrees of freedom. Mathematical relations associated with each of the defined constraints are calculated based on detected and/or measured position vectors, orientations and evolutions.

Abstract: A method controls a robotic system for medical or surgical teleoperation. The robotic system includes a hand-held master device, mechanically unconstrained to the ground and moveable by an operator; and a slave device including a surgical instrument adapted to be controlled by the master device, so that movements of the slave device, or of the surgical instrument of the slave device, referred to one or more of a plurality of controllable degrees of freedom are controlled by respective movements of the master device, according to a master-slave control architecture. The method firstly includes the steps of defining a first enslaved state of the system and a second decoupled state of the system. A controller controls transitions between the first and second states. The controllable degrees of freedom include degrees of freedom of translation and of orientation. A master-slave robotic system for medical or surgical teleoperation performs the method.

Abstract: A method initiates and/or prepares and/or conducts teleoperation by a robotic system for medical or surgical teleoperation. The robotic system includes a master device, which is hand-held, mechanically unconstrained and moveable by an operator, and a slave device including a surgical instrument controlled by the master device. The master device is functionally symmetrical with respect to a predeterminable single, longitudinal axis of the master device. A local reference frame of the master device and the related longitudinal axis is detected, with respect to a main reference frame of the master device workspace; then, functionally equivalent local reference frames are detected. A corresponding target reference frame is mapped in a workspace of the slave device. An operating reference frame is detected according to criteria for optimization of the trajectory of the slave device. A robotic system for medical or surgical teleoperation is control led by the control method.

Abstract: A method initiates and/or prepares a teleoperation by a robotic system for medical or surgical teleoperation. A hand-held master device is mechanically unconstrained and moved by an operator. A slave device includes a microsurgical instrument controlled by the master device. The robotic system includes a man-machine interface allowing the operator to communicate the intention to teleoperate to the robot. The method includes initiating teleoperation preparation; then performing alignment between master device and slave device, in which the slave device moves to align orientation of the surgical instrument to the master device. Teleoperation is entered after the alignment master and slave devices has been completed. First checks are conducted for entering the alignment, and enabling start of the alignment only if all first checks are passed. Before entering the teleoperation, second checks are conducted for enabling alignment, and enabling entry into teleoperation only if all second checks are passed.

Abstract: The display system for remote control of a working machine includes a plurality of camera units and an image processing device, both provided on or in a working machine, and a display device and a remote control device, both provided in the remote control side. The display device detects movement of the head of an operator and transmits the detected movement of the head of the operator to the remote control device. The remote control device transmits, to the image processing device over wireless communications, the movement of the head of the operator transmitted from the display device. The image processing device adjusts, for transmission to the display device, parts of left-eye and right-eye panoramic images according to the movement of the head of the operator transmitted from the remote control device.

Abstract: The display system for remote control of a working machine includes a plurality of camera units and an image processing device, both provided on or in a working machine, and a display device and a remote control device, both provided in the remote control side. The display device detects movement of the head of an operator and transmits the detected movement of the head of the operator to the remote control device. The remote control device transmits, to the image processing device over wireless communications, the movement of the head of the operator transmitted from the display device. The image processing device adjusts, for transmission to the display device, parts of left-eye and right-eye panoramic images according to the movement of the head of the operator transmitted from the remote control device.

Abstract: A communication method between one or more users (20 and 40) associated to respective workstations and one or more remote services (26) located in different geographic places connected by a communication network (21), capable of establishing a direct connection between a remote service agent (31) and an interface agent (28 and 43) in real time, creating a common immersive virtual environment to the users where said services are available and where said users (20 and 40) can cooperate in real time—According to this method, an user (20) comes into contact with a physic interface device (21), for example a haptic interface capable of transmitting to the user feedback signals making a virtual environment in which the user has the sensation to be immersed, connected to an interface agent (28) adapted to connect said physic interface device (21) with a connection network (27).