A server includes a network interface to interface with mobile computing devices operating within a geographical area, with at least one of the mobile computing devices providing a request for navigation instructions between two geo-locations based on prompting the user to select an optimized connectivity route prompt. A processor is coupled to the network interface and is configured to generate a network connectivity map based on varying cellular network connectivity metrics for the geographical area, and generate, based on the user-selected optimized connectivity route prompt, the navigation instructions between the two geo-locations to be provided to the at least one mobile communications device via said network interface. The navigation instructions are generated based on the network connectivity map to provide a single route that is optimized to include areas with strong cellular network connectivity metric values.

A server includes a network interface to interface with mobile computing devices operating within a geographical area, with at least one of the mobile computing devices providing a request for navigation instructions between two geo-locations based on prompting the user to select an optimized connectivity route prompt. A processor is coupled to the network interface and is configured to generate a network connectivity map based on varying cellular network connectivity metrics for the geographical area, and generate, based on the user-selected optimized connectivity route prompt, the navigation instructions between the two geo-locations to be provided to the at least one mobile communications device via said network interface. The navigation instructions are generated based on the network connectivity map to provide a single route that is optimized to include areas with strong cellular network connectivity metric values.

A method for monitoring spectral efficiency in a wireless network includes determining total number of resource blocks or resource elements allocated for each of one or more calls in the wireless network during a given time period and determining a corresponding total number of bits transmitted for each of the one or more calls during the given time period. A spectral efficiency metric is calculated for each of the one or more calls based at least in part on the total number of bits transmitted during the given time period and the total number of resource blocks or resource elements allocated for transmission during the given time period. A heat map for each of the one or more calls is generated based on geographic locations of the one or more calls.

The present disclosure provides methods operable in a balloon network. The method can include determining that a balloon is at a location associated with a legally-defined geographic area. An area profile of the legally-defined geographic area may identify geographically-restricted data that must not be removed from the legally-defined geographic area. The method can also include determining that the balloon contains at least some of the geographically-restricted data. The method can also include determining that the balloon is likely to move out of the legally-defined geographic area. The method can also include removing the geographically-restricted data from the memory of the balloon.

The present disclosure provides methods operable in a balloon network. The method can include determining that a balloon is at a location associated with a legally-defined geographic area. An area profile of the legally-defined geographic area may identify geographically-restricted data that must not be removed from the legally-defined geographic area. The method can also include determining that the balloon contains at least some of the geographically-restricted data. The method can also include determining that the balloon is likely to move out of the legally-defined geographic area. The method can also include removing the geographically-restricted data from the memory of the balloon.

The embodiments of the present application provide a wireless communication method and a wireless communication device. The method includes: determining, by a terminal device, information to be transmitted in a first time unit according to a transmission parameter of at least one downlink physical channel and a transmission parameter a first uplink channel, wherein an uplink channel for transmission of ACK/NACK information corresponding to the at least one downlink physical channel and the first uplink channel are overlapped in the first time unit.

The embodiments of the present application provide a wireless communication method and a wireless communication device. The method includes: determining, by a terminal device, information to be transmitted in a first time unit according to a transmission parameter of at least one downlink physical channel and a transmission parameter a first uplink channel, wherein an uplink channel for transmission of ACK/NACK information corresponding to the at least one downlink physical channel and the first uplink channel are overlapped in the first time unit.

The present disclosure relates to apparatus, systems, and methods for analyzing characteristics of entities of interest. In particular, the present disclosure provides a mechanism for analyzing information about entities of interest and for rating or scoring the entities of interest based on the analyzed information. The rating or the score of an entity of interest can sometimes be referred to as a placerank value of an entity of interest.

Methods and apparatus are provided for integrated communication and sensing. For example, an electronic device may transmit a radio frequency (RF) pulse signal in the active phase of a periodic sensing cycle, and sense in the passive phase of the sensing cycle, a reflection of the RF pulse signal reflected from an object. The RF pulse signal is defined by a waveform for carrying communication data between electronic devices. The sensed RF pulse signal is at least a portion of the transmitted or reflected RF pulse signal, wherein the portion is equal to or greater than a threshold value for the object being within a sensing range of the first electronic device. The electronic device may also receive a communication signal from another electronic device during the passive phase.

Systems, methods, and apparatuses for providing dynamic, prioritized spectrum utilization management. The system includes at least one monitoring sensor, at least one data analysis engine, at least one application, a semantic engine, a programmable rules and policy editor, a tip and cue server, and/or a control panel. The tip and cue server is operable utilize the environmental awareness from the data processed by the at least one data analysis engine in combination with additional information to create actionable data.