Disclosed are a parking location checking system and a parking location checking method using the same, which can quickly and easily find a parking location even if a user who has parked a car in a parking lot does not remember the location of the parking section in which the car is parked, and can guide the user to the parking location and, simultaneously, even transmit various types of information or advertisement content to the user by executing the various type of information or advertisements through a smartphone. The parking location checking system and the parking location checking method using the same can quickly and easily find the parking section in which a car is parked just by allowing a smartphone to approach or come in contact with an NFC tag even if a user does not remember the location of the parking lot in which the user's car is parked, thereby remarkably improving the user's convenience and even creating additional profits by posting an advertisement therein while using the parking location checking system.

The disclosure includes implementations for determining a position of a vehicle using millimeter wave narrow beamforming. A method may include receiving a set of training packets that each uniquely identify a position on a portion of a roadway where the vehicle is located. Each of the training packets included in the set may be associated with only one of the millimeter wave narrow beams. The method may include identifying a training packet included in the set of training packets that has a highest receive power level among the set of training packets. The method may include determining the position uniquely identified by the training packet having the highest receive power level. The method may include determining positional information for the vehicle based on the position uniquely identified by the training packet having the highest receive power level. The positional information may describe a location of the vehicle on the roadway.

A networked system for managing a physical intrusion detection/alarm includes a network of end nodes, e.g., sensor nodes including one or more constrained sensor nodes for sensing physical conditions, and a gateway to provide network connections for the constrained sensor nodes. The system also includes a range extender for connecting the one or more constrained sensor nodes to the gateway, with the range extender including first and second radios and corresponding processors to wirelessly communicate with the gateway and constrained nodes.

Aspects of the subject disclosure may include, for example, a method in which a processing system obtains geolocation information for an unmanned aerial vehicle (UAV) and for a cell of a terrestrial communication network. The system estimates a distance between the UAV and the cell, calculates an expected receive (RX) power for a signal transmitted from the UAV to the cell, and compares the expected RX power with a threshold power to determine whether the cell is a suitable target cell for a communications handover procedure for the UAV. Other embodiments are disclosed.

A method in a communication device for providing a location information of the communication device to a Minimization of Driving Tests, MDT, server is disclosed. The communication device operates in a wireless communication environment which comprises multiple networks comprising at least one cellular network and at least one satellite positioning system. The communication device starts an MDT measurement and determines a signal strength received from a satellite in the satellite positioning system by measuring the signal strength at a positioning antenna. When the signal strength received from the satellite is above a threshold, the communication device 110 determines a feasibility of an Assisted Global Position System, AGPS. When the AGPS is feasible, the communication device initiates an AGPS session for obtaining the location information using an acquisition assistance data and sends the location information together with other MDT data to the MDT server.

Methods, systems, and non-transitory computer readable media are provided for rendering at an electronic terminal a first set of graphical user interfaces to request a first set of data from a user, receiving, at a central server in communication with the electronic terminal, the first set of data from the user, communicating the first set of data via a stateless edge appliance to a third party verification server in a selected one of a plurality of third party computer networks to validate the first set of data, rendering a second set of graphical user interfaces to request a second set of data from the user, communicating the second set of data to the third party verification server to authenticate the second set of data, and authenticating the user in response to receipt of authentication of the second set of data.

This invention provides a location verification server and a geospatial database in which is stored identity and geospatial location data pertaining to network elements (for instance GSM towers and base station transceivers (BTS)) and transaction devices (such as POS terminals). When a transaction is initiated on a transaction device, a location verification request is transmitted to the location verification server which is programmed to: communicate with 106 the mobile network of the mobile device associated with the transaction to determine the identities of network elements located in the vicinity of the mobile device; to perform a lookup in the geospatial database to determine the stored geospatial locations of the identified network elements and the originating transaction device; and to compare the locations of the transaction device and network elements to confirm location of the mobile device.

A real time asset tracking system and method is described including a plurality of mobile units (e.g., fobs) which are capable of communication with a network. The plurality of mobile units being configured to determine the presence of a contact event, e.g., when a first mobile unit is within a predetermined distance from a second mobile unit for a predetermined amount of time. If the first mobile unit is in a contact event, then the first mobile unit may be configured to alert the user (visual, vibration, sound) and report the contact event data to the server.

A management system for objects under monitoring that is capable of managing the presence of moving objects under monitoring. The management system includes a plurality of beacon terminals, one or more management terminals, and a management server. The beacon terminals are respectively held by the moving objects under monitoring, and each have a unique identifier and broadcast a beacon signal. The one or more management terminals are respectively held by one or more moving bodies moving in one or more areas, receive beacon signals to acquire beacon identifiers and beacon presence information, and acquire location information via a positioning system. The management terminals output beacon information spontaneously or upon request. The management server determines the state of presence of the objects under monitoring in the one or more areas, based on the beacon information acquired from the one or more management terminals.

Methods and systems receive location identification tokens from transmitters using a portable computerized device. A first location identification token is received from a first location transmitting device, while the portable computerized device is within a predetermined distance from a designated location. A second location identification token is received from a second location transmitting device. A current location signature is calculated using the first and second location identification tokens. A previously stored location signature associated with the first and second location identification tokens is obtained from a computer readable storage medium. The current location signature is compared with the previously stored location signature to determine a similarity measure. The location identification tokens and the current location signature are stored in a memory and transmitted to a server. The presence of the portable computerized device at the designated location is verified based on the location identification tokens and the current location signature.