The invention relates to the field of logistics, and discloses a logistics apparatus and a method for identifying empty/full state of the logistics apparatus, which efficiently and accurately realizes automatic recognition of empty and full state. The invention includes: a base and side plates at four sides; a foldable mechanism being provided between the base and each side plate so that the side plates can be folded toward the base; and a short-range wireless transmitter module and a short-range wireless receiver module being respectively disposed on the base and at least one side plate; the short-range wireless transmitter module is configured to transmit a wireless signal indicating the identification of the logistics apparatus; and an arbiter, configured to determine whether the short-range wireless receiver module can currently receive the identifier transmitted by the short-range wireless transmitting module, and if yes, outputting an electrical signal indicating an empty state, otherwise, outputting an electrical signal indicating a full state.

An electronic device according to the disclosure includes an infrared signal receiver, an infrared signal transmitter, a memory that stores computer instruction code, which, when executed by a processor, causes the processor to: receive a first infrared signal output from a remote control device according to a user input for controlling an external device connected with the electronic device through the infrared signal receiver, identify a second infrared signal corresponding to one of control commands for controlling the operation of the external device based on control information included in the received first infrared signal, identify the output timing of the second infrared signal based on the type of the first infrared signal, and control the infrared signal transmitter to output the determined second infrared signal based on the identified output timing.

An electronic device according to the disclosure includes an infrared signal receiver, an infrared signal transmitter, a memory that stores computer instruction code, which, when executed by a processor, causes the processor to: receive a first infrared signal output from a remote control device according to a user input for controlling an external device connected with the electronic device through the infrared signal receiver, identify a second infrared signal corresponding to one of control commands for controlling the operation of the external device based on control information included in the received first infrared signal, identify the output timing of the second infrared signal based on the type of the first infrared signal, and control the infrared signal transmitter to output the determined second infrared signal based on the identified output timing.

A tactical communications apparatus is used to establish secure, reliable communications between a forward-deployed communications station and any designated second communicator during a building siege or hostage situation. At least one communications device, at least one processing unit, a transceiver array, and a power supply are mounted to a casing. The casing allows the tactical communication apparatus to be tossed into an area. The transceiver array wirelessly connects to at least one remote terminal, enabling communication via the at least one communication device. The casing also contains a plurality of discrete surveillance devices mounted into the casing to enable an operator to remotely surveil the area around the casing. Further, the tactical communication apparatus also supports at least one offensive device operated via the at least one remote terminal. The at least one offensive device may be activated as cover for responders if communications fail to resolve a situation.

A tactical communications apparatus is used to establish secure, reliable communications between a forward-deployed communications station and any designated second communicator during a building siege or hostage situation. At least one communications device, at least one processing unit, a transceiver array, and a power supply are mounted to a casing. The casing allows the tactical communication apparatus to be tossed into an area. The transceiver array wirelessly connects to at least one remote terminal, enabling communication via the at least one communication device. The casing also contains a plurality of discrete surveillance devices mounted into the casing to enable an operator to remotely surveil the area around the casing. Further, the tactical communication apparatus also supports at least one offensive device operated via the at least one remote terminal. The at least one offensive device may be activated as cover for responders if communications fail to resolve a situation.

A probe is configured for introduction into a vicinity of a hazard. The probe comprises multiple sensors, communications circuitry, processor circuitry, and a casing. The multiple sensors include at least: a sensor configured to acquire disposition information of the probe; and a sensor configured to acquire environmental information in a vicinity of the probe. The communications circuitry is configured to transmit the disposition information and the environmental information externally to the probe. The processor circuitry is configured to coordinate operation of the multiple sensors and the communications circuitry. The casing is configured to internally house the multiple sensors, the transmitter, and the processor circuitry. The casing comprises an essentially cylindrical bullet shape, and wherein along a major cylindrical axis a first end of the casing comprises a flat butt surface and a second end of the casing comprises a rounded nose surface.

In one example, an electronic device may include a housing having an opening and an antenna assembly disposed in the housing. The antenna assembly may include an antenna mounted to the housing, an antenna module disposed corresponding to the opening, and a cable to connect the antenna to the antenna module via routing the cable through the opening.

In one example, an electronic device may include a housing having an opening and an antenna assembly disposed in the housing. The antenna assembly may include an antenna mounted to the housing, an antenna module disposed corresponding to the opening, and a cable to connect the antenna to the antenna module via routing the cable through the opening.

A first device such as a wristwatch may include a front face at which a display is disposed and a rear face at which a rear housing wall is mounted. Antenna structures may overlap the rear housing wall and may be operable to transmit and receive relatively high frequency signals through the rear housing wall to a communication with a second device such as a wireless power transmitting device for the wristwatch. The second device may also include antenna structures that overlap a top surface housing. Respective sets of magnetic structures may be provided in the first and second devices to align the two devices and to form a reliable wireless communication link between the two devices. The first and second devices may include respective antenna arrays that include pairs of antenna elements that are selectively used to form a reliable wireless communication link.

A guest engagement system and associated methods provide seamless engagement with guests of facilities through the use of wireless sensing technologies. The system makes use of individual guest devices which are carried by guests and used to automatically identify and authenticate the guests throughout the facility. Services can thereby be seamlessly provided to the guests throughout the facility. The services include contact tracing, automatic unlocking of doors, including hotel or state room doors, based on the guests' immediate proximity to their assigned room's door. The services also include automated payment services provided at checkout or vending terminals, and automated log-on to interactive displays and portals, among others, based on secure wireless authentication of the guest devices.