The technology provides a system and method for simulating and detecting bio signals such as brain bio-signals. Optical fibers provide modulated signals received from an optical signal modulator. The modulated signals are received by a set of emission elements disposed within the phantom body, which output corresponding electrical signals. The electrical signals are detected by a set of sensors and evaluated by a receiver device, such as for an electroencephalograph (EEG), electrocardiogram (ECG), electromyogram (EMG) or magnetoencephalography (MEG) diagnostic system. A controller manages the modulation of light signals so that specific electrical signals can be generated as desired. Because tens, hundreds or thousands of emission elements may be arranged in the phantom body, the controller can manage operation of the optical signal modulator so that the precise physical location of each emission element can be mapped quickly and efficiently. The controller may also detect defective components in a similar manner.

The technology provides a system and method for simulating and detecting bio signals such as brain bio-signals. Optical fibers provide modulated signals received from an optical signal modulator. The modulated signals are received by a set of emission elements disposed within the phantom body, which output corresponding electrical signals. The electrical signals are detected by a set of sensors and evaluated by a receiver device, such as for an electroencephalograph (EEG), electrocardiogram (ECG), electromyogram (EMG) or magnetoencephalography (MEG) diagnostic system. A controller manages the modulation of light signals so that specific electrical signals can be generated as desired. Because tens, hundreds or thousands of emission elements may be arranged in the phantom body, the controller can manage operation of the optical signal modulator so that the precise physical location of each emission element can be mapped quickly and efficiently. The controller may also detect defective components in a similar manner.

A method for controlling a vitrector of a vitrectomy system includes emitting an optical signal over an opening in a body of the vitrector, the opening providing access to a cutting member within the body, and using an optical sensor provided on the vitrector to capture optical feedback produced when the optical signal interacts with material proximate to the opening. The presence of the material in a vicinity of the cutting member of the vitrector is determined based on the optical feedback. A control signal to alter operation of the vitrector is issued responsive to determining the presence of the material in the vicinity of the cutting member of the vitrector.

A method for controlling a vitrector of a vitrectomy system includes emitting an optical signal over an opening in a body of the vitrector, the opening providing access to a cutting member within the body, and using an optical sensor provided on the vitrector to capture optical feedback produced when the optical signal interacts with material proximate to the opening. The presence of the material in a vicinity of the cutting member of the vitrector is determined based on the optical feedback. A control signal to alter operation of the vitrector is issued responsive to determining the presence of the material in the vicinity of the cutting member of the vitrector.

A control system controls a plurality of controllable units with a central control device and further has a plurality of control modules, each of which is assigned to one of the units to be controlled. The central control device is set up to exchange digital data with each control module. The control modules form a connection network, wherein each control module is connected to at least one other control module via a communication line so that data exchange between them is possible. One of the control modules is directly connected to the central control device as the master node of the connection network, and the control modules are set up to form a communication network within the connection network, so that the data exchange between the central control device and each control module can be respectively carried out via an assigned communication path within the communication network.

A control system controls a plurality of controllable units with a central control device and further has a plurality of control modules, each of which is assigned to one of the units to be controlled. The central control device is set up to exchange digital data with each control module. The control modules form a connection network, wherein each control module is connected to at least one other control module via a communication line so that data exchange between them is possible. One of the control modules is directly connected to the central control device as the master node of the connection network, and the control modules are set up to form a communication network within the connection network, so that the data exchange between the central control device and each control module can be respectively carried out via an assigned communication path within the communication network.

A light guide or beam guiding system with safety component and a method for its breakage monitoring. The present invention provides a fiber optic cable comprising a power fiber as well as first and second channels for break and plug monitoring of the power fiber, wherein the first and second channels may be separate.

A light guide or beam guiding system with safety component and a method for its breakage monitoring. The present invention provides a fiber optic cable comprising a power fiber as well as first and second channels for break and plug monitoring of the power fiber, wherein the first and second channels may be separate.

Embodiments of the present application provide a method based on an optical fiber communication network for controlling a robot, a storage medium and an electronic device. The method includes: converting an acquired electrical control signal of the robot to an optical control signal; broadcasting the optical control signal over a downlink of the optical fiber communication network; filtering the optical control signal based on a port identifier to obtain an optical control signal corresponding to the port identifier; converting the optical control signal corresponding to the port identifier to an electrical control signal; and sending the electrical control signal to an actuator of the robot. According to the embodiments of the present application, the number of wirings inside the robot is reduced, the wiring complexity is reduced, and the bandwidth for communication and anti-electromagnetic interference capabilities in the control system are improved.

Embodiments of the present application provide a method based on an optical fiber communication network for controlling a robot, a storage medium and an electronic device. The method includes: converting an acquired electrical control signal of the robot to an optical control signal; broadcasting the optical control signal over a downlink of the optical fiber communication network; filtering the optical control signal based on a port identifier to obtain an optical control signal corresponding to the port identifier; converting the optical control signal corresponding to the port identifier to an electrical control signal; and sending the electrical control signal to an actuator of the robot. According to the embodiments of the present application, the number of wirings inside the robot is reduced, the wiring complexity is reduced, and the bandwidth for communication and anti-electromagnetic interference capabilities in the control system are improved.