The present invention are a system and a method for controlling solar photovoltaic power generation on the basis of machine learning, the system comprising: solar photovoltaic modules; node control units for switching off a connected solar photovoltaic module when measured current, voltage and power data do not satisfy control data; a gateway unit for storing measured data; a real-time control module for classifying, comparing and analyzing data and storing same, and transmitting a control command to the gateway unit; and machine learning for monitoring a device and data, learning on the basis of machine learning, and extracting functional data required for controlling solar photovoltaic power generation so as to provide control service data according to the result of performed modeling.

A system and method for the centralized access and management of multiple IoT systems is provided via a networked media hub. The media hub functions as a nexus for multiple IoT systems, providing a familiar, single-point user interface enabling the aggregation of information from, and the transmission of user commands to various, disparate IoT systems. The hub also enables interaction between the connected IoT systems, providing a point of connection and management for previously isolated IoT systems.

An unmanned aerial vehicle control method includes: sending a random access request to a base station; sending connection success information to a remote control device according to identification information of the remote control device, after a communication connection with the base station is established; receiving a control signal sent by the remote control device through the base station; and performing an operation according to the control signal.

A robot control method, a device, and a remote control system. A mobile terminal establishes a connection to a robot by scanning a two-dimensional code and by a local area network. A remote monitoring and control center connects to the mobile terminal by a wide area network, and when the mobile terminal and the remote monitoring and control center send information to each other, the mobile terminal breaks off connection with the robot, thereby ensuring information transmission security. Operation instruction information from a user on an operation interface is acquired, the operation instruction information comprising a control parameter and an action execution parameter, and on based on the set control parameter and the set action execution parameter, first control instruction information is generated, and sent to the robot by a wireless communications network, in order to cause the robot to execute a corresponding action based on the first control instruction information.

A system for remote-controlling a spectrometer, which includes: at least one spectrometry device including a spectrometer and auxiliary modules, the spectrometry device being configured to measure spectrometry data on an object and/or a process; a control device configured to control the spectrometry device, the control device including an element for controlling the spectrometry device, an element for acquiring and processing the spectrometry data, and an element for remote communication; and at least one interface modules configured to communicate with the control device remotely. The remote-control device is configured to communicate with the interface module via Internet, and the spectrometry device is interchangeable. Also, a device for remote-controlling a spectrometry system that is configured to be used in a system for remote-controlling the spectrometer.

An operating system that can control any apparatus is provided. The operating system (1001) includes an input receiving device (1060), a first information processing device (1100), a second information processing device (1200), and an infrared output device (1070). The operating system (1001) operates a first-type apparatus (1010) operable by communication of an infrared pattern and a second-type apparatus (1020) operable via a network. The first information processing device (1100) is connected to the input receiving device (1060) and configured to analyze operation information corresponding to an input operation. The second information processing device (1200) is configured to control the second-type apparatus (1020) (controlled apparatus (B)) via the network based on a control instruction. The infrared output device (1070) is configured to output an infrared pattern corresponding to a control instruction to the first-type apparatus (1010) (controlled apparatus (A)).

The invention relates to a method for configuring the communication between at least one actuator and a remote control, in order to enable a control of the at least one actuator by the remote control, the at least one actuator being configured to communicate with the remote control, the communication between the at least one actuator and the remote control being established according to a first protocol or according to a second protocol, the communication according to the second protocol being implemented via a connection to a router connected to the mains, the method being implemented by a mobile terminal, the mobile terminal being configured to communicate according to the first protocol with the at least one actuator, and with the remote control, the mobile terminal being configured to communicate with the router according to the first protocol or according to a third protocol, the method comprising the following steps: —identifying an identifier of the at least one actuator, —identifying an identifier of the remote control, —analysing in order to detect a presence or absence of the router, —if the absence of the router is detected by the mobile terminal during the analysis step, transmitting, to the remote control, the identifier of the at least one actuator and/or transmitting, to the actuator, the identifier of the remote control, then transmitting, to the remote control and to the actuator, a request to deactivate the first protocol, if the presence of the router is detected by the mobile terminal during the analysis step, transmitting, to the router, the identifier of the at least one actuator and the identifier of the remote control.

An operating system that can control any apparatus is provided. The operating system includes an input receiving device, a first information processing device, a second information processing device, and an infrared output device. The operating system operates a first-type apparatus operable by communication of an infrared pattern and a second-type apparatus operable via a network. The first information processing device is connected to the input receiving device and configured to analyze operation information corresponding to an input operation. The second information processing device is configured to control the second-type apparatus (controlled apparatus (B)) via the network based on a control instruction. The infrared output device is configured to output an infrared pattern corresponding to a control instruction to the first-type apparatus (controlled apparatus (A)).

Embodiments are directed to controlling an electronically-controlled appliance using a software application and providing a user interface for controlling an electronically-controlled appliance. In one scenario, a computer system receives an indication from a remote computing system indicating that an electronically-controlled appliance is communicably connected to the remote computing system. The computer system provides a notification in the software application indicating that the electronically-controlled appliance is available to receive instructions, and receives a user input at the software application indicating that certain functions are to be performed by the electronically-controlled appliance. The computer system further generates instructions configured to control the electronically-controlled appliance based on the functions specified in the received user input, and sends the generated instructions to the electronically-controlled appliance to perform the specified functions. These functions are then interpreted and carried out on the electronically-controlled appliance via the hardware controller.

When a remote operation of a work machine 40 through one remote operation apparatus 20 as a first remote operation apparatus is stopped by one operator, operation of an engine 460 of the work machine 40 is continued without being stopped if another operator who may possibly continuously remotely operate the same work machine 40 through another remote operation apparatus 20 as a second remote operation apparatus exists. Therefore, the other operator can immediately remotely operate the work machine 40 through the second remote operation apparatus without causing the engine 460 of the work machine 40, which has been an operation target of the first remote operation apparatus so far, to restart and perform warm-up operation.