A mobile terminal, and a locating method and device are provided, wherein the mobile terminal includes a first antenna, configured to transmit a first signal to an anchor node, wherein the first signal is used by the anchor node to detect the signal strength of the first antenna; a second antenna, arranged with the first antenna according to a preset angle and configured to transmit a second signal to the anchor node, wherein the second signal is used by the anchor node to detect the signal strength of the second antenna. The preset angle enables the coverage of the first antenna and the second antenna to be overlapped to some extent. The signal strength of the first antenna and the signal strength of the second antenna are used for determining a location of the mobile terminal.

A mobile terminal, and a locating method and device are provided, wherein the mobile terminal includes a first antenna, configured to transmit a first signal to an anchor node, wherein the first signal is used by the anchor node to detect the signal strength of the first antenna; a second antenna, arranged with the first antenna according to a preset angle and configured to transmit a second signal to the anchor node, wherein the second signal is used by the anchor node to detect the signal strength of the second antenna. The preset angle enables the coverage of the first antenna and the second antenna to be overlapped to some extent. The signal strength of the first antenna and the signal strength of the second antenna are used for determining a location of the mobile terminal.

The present disclosure provides a method for operating a first electronic device. The method includes detecting a movement of the first electronic device, receiving direction information of a second electronic device, and determining an azimuth angle of a heading direction of the first electronic device based on the received direction information of the second electronic device.

The present disclosure provides a method for operating a first electronic device. The method includes detecting a movement of the first electronic device, receiving direction information of a second electronic device, and determining an azimuth angle of a heading direction of the first electronic device based on the received direction information of the second electronic device.

A method, a sensor system, and a non-transitory computer readable medium are provided. Embodiments comprise receiving a plurality of incident signals reflected from a target at a plurality of receiver antennas. A processor identifies a subset of receiver antennas from the plurality of receiver antennas and performs angle of arrival (AOA) processing on respective incident signals of the subset of receiver antennas. The processor determines an angle of arrival of the target based on the AOA processing.

A location system and applications therefor is disclosed for wireless telecommunication infrastructures. The system is an end-to-end solution having one or more location systems for outputting requested locations of handsets or mobile stations (MS) based on, e.g., CDMA, GSM, GPRS, TDMA or WIFI communication standards, for processing both local mobile station location requests and more global mobile station location requests via, e.g., Internet communication between a distributed network of location systems. The following applications may be enabled by the location system: 911 emergency calls, tracking, navigation, people and animal location including applications for confinement to and exclusion from certain areas, friend finder applications, and applications for allocating user desired resources based on the user's location.

A radio wave status output device has: a measurement circuitry that measure each reception power or a C/N value of a radio wave received; an angle measurement circuitry that measure each an azimuth angle and an elevation angle of the directional antenna; a calculation circuitry that calculate an approximate curved surface corresponding to each the reception power or C/N value at a position of each of the plurality of different points on an X-Y plane, respectively, and that the reception power or the C/N value measured is a value of a Z-axis; and an extraction circuitry that extract, from the approximate curved surface calculated, a range on the X-Y plane in which the value of the Z-axis is equal to or greater than a predetermined threshold.

A radio wave status output device has: a measurement circuitry that measure each reception power or a C/N value of a radio wave received; an angle measurement circuitry that measure each an azimuth angle and an elevation angle of the directional antenna; a calculation circuitry that calculate an approximate curved surface corresponding to each the reception power or C/N value at a position of each of the plurality of different points on an X-Y plane, respectively, and that the reception power or the C/N value measured is a value of a Z-axis; and an extraction circuitry that extract, from the approximate curved surface calculated, a range on the X-Y plane in which the value of the Z-axis is equal to or greater than a predetermined threshold.

This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for establishing directional communications between two communication nodes via a configurable reflective surface. In some aspects, an assisting node (AN) may control a reflection characteristic (which may dictate or influence how signals reflect off of the configurable reflective surface) in accordance with parameters or configurations for directional communication between the two communication nodes. For example, the AN may use a first beam for directional communication with the first node and a second beam for directional communication with the second node, and the AN may control the reflection characteristic in accordance with an inferred incident direction of signaling at the configurable reflective surface and a desired reflected direction of the signaling from the configurable reflective surface that are associated with the first beam and the second beam, respectively.

This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for establishing directional communications between two communication nodes via a configurable reflective surface. In some aspects, an assisting node (AN) may control a reflection characteristic (which may dictate or influence how signals reflect off of the configurable reflective surface) in accordance with parameters or configurations for directional communication between the two communication nodes. For example, the AN may use a first beam for directional communication with the first node and a second beam for directional communication with the second node, and the AN may control the reflection characteristic in accordance with an inferred incident direction of signaling at the configurable reflective surface and a desired reflected direction of the signaling from the configurable reflective surface that are associated with the first beam and the second beam, respectively.