Methods, computer-readable media, software, and system may generally identify, determine, and understand the significance of commute location data using telematics data. The system and methods may identify significant commute location data and points by analyzing telematics data and capturing GPS locations associated with the mobility of a user. The commute location data may be classified as data points including origin, destination, and waypoints. This commute location data may be used with metadata to identify significant locations associated with the user. The commute location data may also be used with metadata to understand mobility behavior of the user. Lastly, the commute location data may be used with metadata to determine risk associated with the user, such as based on a risk map.

Methods, computer-readable media, software, and system may generally build and quantify mobility patterns based on user location data, both at an individual level and an aggregate level. The system may determine the origin and destination data for each trip taken by a user. The system may then define areas of mobility using a mobility graph built from the data. The graph may include nodes and edges. In some examples, the nodes are constructed from the origins and destinations of the trajectories using spatial clustering techniques. Further, the edges between nodes may be constructed based on the trips between them, such as two nodes are connected by an edge if there is at least one trip between them. The edges may be given different weights based on trip frequencies. The system may then determine a region of mobility using the generated mobility graph and data clustering techniques.

Reliable location data is found using messages with unreliable location data. A logistic-geohash is found for a plurality of messages. Records of are accessed data messages, each data message including a geographic locator and a sender-identifier. For each sender-identifier, one or more geogroups are determined. For each geogroup: determining, a representative point of the geogroup is found to represent the geogroup. Using the representative point of the geogroup, a geogroup-geohash is found. Pair of geogroup: logistic address are found based on a matching of at least some of the first plurality of digits and some of the second plurality of digits. For each pair of geogroup:logistic address, a distance is determined between the representative point of the geogroup and the representative point of the logistic address. Geogroup:logistic address pairs are selected. The selected geogroup:logistic address pairs are stored in memory as representing a logistic location of the sender-identifier.

The described technology is generally directed towards combining user identity information, corresponding to user profile data, with vehicle information, such as for use by a traffic zone management system that charges a fee for vehicle usage in a traffic zone. A user device, such as a mobile communications device, can be coupled to vehicle information such as via a transponder that is detected by roadside units, or by uploading the combined information to a wireless communications system. Based on the combination of information, different billing rates or the like can be applied to different users and vehicle types. The technology can work with various communication systems, including roadside units and wireless communication networks.

A wireless communication method includes receiving a reference signal and a data signal, based on a coverage enhancement level represented by a number of transmission repetitions; processing the reference signal and the data signal received by the receiving; setting a number of resource elements for transmitting the reference signal based at least on a channel type; and setting usage of resource elements indicated by a System Information Block (SIB). The reference signal is a Cell-specific Reference Signal (CRS) or a Demodulation Reference Signal (DMRS).

A method of presenting data on a mobile device is provided, comprising reading a compass and an accelerometer for sensing orientation and movement of the mobile device, initiating a local geographic search or query by pointing the mobile device in a desired direction, determining a boundary for search results, the boundary based on a current location of the mobile device, providing the boundary to a server, storing (a) search rules for a given location, (b) localized storage of POI data, and (c) logic for switching the search from a macro database to a micro database, and initiating a geographic query for points of interest (POIs) that have an associated geographic position within the boundary.

A system and method for the use of geo-fences to coordinate and track delivery of items. In some embodiments, the system comprising a mobile delivery device comprising a vector calculation module configured to determine a motion vector associated with the mobile delivery device, a geo-location module configured to determine a geo-location associated with a mobile delivery device, and a geo-fence database configured to determine a size of at least one geo-fence associated with at least one location and determine whether the mobile delivery device is within the geo-fence. In some embodiments, the size of the geo-fence is determined at least in part on the motion vector determined by the vector calculation module.

The embodiments of the present application provide a wakeup region update method and device for updating a wakeup region of a terminal. The method includes a terminal receiving a wakeup signal, the wakeup signal carrying a wakeup region indicator; and the terminal updating the wakeup region indicator of the terminal according to the wakeup region indicator carried by the wakeup signal received. The present application is adopted to achieve updating and maintenance of the wakeup region of the terminal.

A system for facilitating sending and receiving of security alerts may include a processor communicatively coupled to a memory and a network interface, the network interface communicatively coupled to a network. A fixed location manager and a roving location manager may be communicatively coupled to the network interface and the network and may be configured to: (i) receive security messages from a plurality of user mobile devices coupled with the network, (ii) create a fixed forum security message and a roving forum security message, each of which is associated with a geographic location of one of the security messages, and (iii) send the fixed forum security message and the roving forum security message to all of the plurality of user mobile devices that comprise a fixed alert area or a roving alert area associate with the geographic location.

Disclosed are systems, methods, and non-transitory media for sensing radio frequency signals. For instance, radio frequency data can be received by an apparatus and from at least one wireless device in an environment. Based on the radio frequency data received from the at least one wireless device, the apparatus can determine sensing coverage of the at least one wireless device. The apparatus can further provide the determined sensing coverage and a position of at least one device to a user device.