A control device is provided. The control device includes a first communication interface unit which transmits a control command in a first communication mode which uses a bi-directional wireless communication, a second communication interface unit which transmits a control command in a second communication mode which uses a unidirectional wireless communication, a state determination unit which determines a communication mode of the control device, a user interface unit which displays a user interface window which corresponds to a determined communication mode and receives the control command with respect to a broadcast receiver and a control unit which transmits the received control command according to the determined communication mode.

The invention relates to a spectacle-type device (1) in which a full image can be depicted in a reliable manner by overlapping the first partial image (α3) and the second partial image (α4), wherein a correct full image can be perceived by the operator (2), and an action can be carried out with reliability when at least two items of image information coincide. The invention also relates to a method for depicting a full image and/or for carrying out an action using a spectacle-type device.

A hand-held device with a sensor for providing a signal indicative of a position of the hand-held device relative to an object surface enables power to the sensor at a first time interval when the hand-held device is indicated to be in a position that is stationary and adjacent relative to the object surface, enables power to the sensor at a second time interval shorter than the first time interval when the hand-held device is indicated to be in a position that is moving and adjacent relative to the object surface, and enables power to the sensor at a third time interval when the hand-held device is determined to be in a position that is removed relative to the object surface.

A control device is provided. The control device includes a first communication interface unit which transmits a control command in a first communication mode which uses a bi-directional wireless communication, a second communication interface unit which transmits a control command in a second communication mode which uses a unidirectional wireless communication, a state determination unit which determines a communication mode of the control device, a user interface unit which displays a user interface window which corresponds to a determined communication mode and receives the control command with respect to a broadcast receiver and a control unit which transmits the received control command according to the determined communication mode.

A hand-held device with a sensor for providing a signal indicative of a position of the hand-held device relative to an object surface enables power to the sensor at a first time interval when the hand-held device is indicated to be in a position that is stationary and adjacent relative to the object surface, enables power to the sensor at a second time interval shorter than the first time interval when the hand-held device is indicated to be in a position that is moving and adjacent relative to the object surface, and enables power to the sensor at a third time interval when the hand-held device is determined to be in a position that is removed relative to the object surface.

[Problem] To enable imaging to be performed with appropriate timing. [Solution] In a camera manipulation device 1 according to the present invention, a trigger signal T12 is issued and imaging is begun when a prescribed command is transmitted from a control circuit side to an imaging unit side (see S12). Because the issuance of such trigger signal T12 is not accepted before a character reception start command is issued, it is possible to perform imaging with appropriate timing.

The present disclosure provides a server, a remote control device, and a remote control method for an automatic (or autonomous) driving vehicle. The method may include: after receiving a remote control request of an automatic driving vehicle, acquiring a target wireless channel of a target wireless network with the shortest communication delay from a plurality of candidate wireless channels of a plurality of candidate wireless networks in combination with the current geographic location of the automatic driving vehicle, and transmitting a corresponding control instruction to the automatic driving vehicle through the target wireless channel of the target wireless network.

The present disclosure provides a server, a remote control device and a remote control method for an automatic driving vehicle. The method includes: after receiving a remote control request of an automatic driving vehicle, determining a control instruction according to the remote control request, and transmitting the control instruction by using wireless channels corresponding to a plurality of wireless networks.

A multiply redundant safety system that protects humans and assets while transfer(s) and/or fueling of on road/off road, rail, marine, aircraft, spacecraft, rockets, and all other vehicles and/or vessels utilizing Compressed and or Liquefied Gas Fuels/compound(s). Utilizing Natural Gas Chemical Family of Hydrogen and/or Propane and/or ethane and/or ammonia and/or any mixtures along with or with out oxidizer(s), such as Liquefied Oxygen, Oxygen Triplet (O3) and/or ozone and/or hydrogen peroxide and/or peroxide and/or solid oxidizer(s) one or more processors, utilizing Artificial Intelligence techniques and/or machine learning in combination with one or more sensors; in combination with one or more micro switches and/or actuator(s) combine to detect any leaks and/or fire(s) and/or explosion hazards and/or vehicle motion and/or arcs, spark(s) and/or other hazards for quickly mitigating and/or locking out and/or stopping fueling and/or gas and/or transfers and/or vehicle releasing system(s).

The drone comprises M antennas, with in particular two offset antennas located symmetrically at the ends of two arms for the connection to the propulsion units (24), and a ventral antenna under the drone body. The radio transmission is operated simultaneously on N similar RF channels, with 2N<M. An antenna switching circuit couples selectively each of the N RF channels to N antennas out of the M antennas according to a plurality of different coupling schemes, dynamically through a piloting logic selecting one of the coupling schemes. The selection is operated as a function of a signal delivered by the drone-borne microprocessor, as a function of the flight and signal transmission conditions, determined at a given instant.