Systems and methods can support identifying pairings and channel parameters in short-range wireless communications such as bluetooth low energy interfaces. Radio frequency sensors may be positioned within an electromagnetic environment where a master wireless device and a slave wireless device share short-range wireless communications. Signals transmitted between the master wireless device and the slave wireless device can be received by the radio frequency sensors. Inter-arrival times for packets within the received signals may be identified. Statistics of the inter-arrival times can be analyzed to identify connection intervals between the master wireless device and the slave wireless device as well as back-to-back interval exchanged within the connection intervals. Packet header contents may be used to reconcile the estimated timing parameters and time slots. Pairings between the master wireless device and the slave wireless device may be identified and tracked along with communication channel parameters.

Embodiments of this disclosure provide a method and apparatus for wireless network deployment and a terminal device, wherein, the method includes: estimating whether a deployment position of a current node satisfies a requirement according to planned network information and deployed network information of the current node; and optimizing the deployment position of the current node when an estimation result of the estimating unit is no. With the embodiments of this disclosure, deployment quality of an actual deployment position of a wireless network node may be estimated, such that actual deployment satisfies a requirement on network planning.

Embodiments of this disclosure provide a method and apparatus for wireless network deployment and a terminal device, wherein, the method includes: estimating whether a deployment position of a current node satisfies a requirement according to planned network information and deployed network information of the current node; and optimizing the deployment position of the current node when an estimation result of the estimating unit is no. With the embodiments of this disclosure, deployment quality of an actual deployment position of a wireless network node may be estimated, such that actual deployment satisfies a requirement on network planning.

The presently disclosed subject matter includes: calculating link-budget of at least one antenna on-board a vehicle with respect to at least one target antenna; the link-budget comprises a respective link-budget value assigned to each pixel in a collection of pixels, where each pixel in the collection of pixels represents a respective radiation vector in a three-dimensional space around the at least one antenna; determining for each pixel in the collection of pixels, compliance of the respective link-budget value with a sensitivity threshold value of the transceiver, thereby obtaining a respective antenna envelope of the at least one on-board antenna; displaying on a computer display device graphical representation of a pixel map representing at least the respective antenna envelope; continuously monitoring dynamics of the input data for repeatedly updating the pixel map, and displaying an updated graphical representation of the pixel map.

The presently disclosed subject matter includes: calculating link-budget of at least one antenna on-board a vehicle with respect to at least one target antenna; the link-budget comprises a respective link-budget value assigned to each pixel in a collection of pixels, where each pixel in the collection of pixels represents a respective radiation vector in a three-dimensional space around the at least one antenna; determining for each pixel in the collection of pixels, compliance of the respective link-budget value with a sensitivity threshold value of the transceiver, thereby obtaining a respective antenna envelope of the at least one on-board antenna; displaying on a computer display device graphical representation of a pixel map representing at least the respective antenna envelope; continuously monitoring dynamics of the input data for repeatedly updating the pixel map, and displaying an updated graphical representation of the pixel map.

A method and apparatus for provisioning subscriber information to a deployable network in a wirelress communication system. One exemplary embodiment provides a method providing subscriber information to a deployable network including a deployable user subscription database. The method includes determining, by a controller, a location for the deployable network. The method further includes determining, by the controller, a geofence around the location. The method further includes identifying, by the controller, at least one mobile device that may be involved in responding to the incident. The method further includes determining, by the controller, authentication information required for the at least one mobile device to connect to the deployable network. The method further includes conveying, by the controller via a wireless data network, the authentication information to a deployable user subscription database.

Systems, methods, and apparatus for facilitating automated wireless access point resource allocation and optimization are presented herein. An external data store (EDS) component can automatically select, based on spatial data of at least one polygon including at least one wireless access point, one or more parameters associated with wireless communications of the at least one wireless access point. Further, an access point provisioning gateway (APPG) can remotely initiate the at least one wireless access point to automatically configure equipment of the at least one wireless access point to service the wireless communications using at least one of the one or more parameters. Furthermore, a boundary generation component can automatically generate the spatial data by at least one of: combining spatial data of two or more polygons; splitting a polygon into at least two polygons; or expanding a boundary of the polygon.

Systems, devices and processes are provided to improve the design and implementation of radio frequency (RF) communication networks. Specifically, these various embodiments improve the likelihood of a successful RF network design by identifying and preferentially utilizing RF transmission sites having a relatively high probability of being successfully incorporated into the RF network. These various embodiments provide a site qualification database that includes site data for a plurality of RF transmission sites. When so implemented, the site qualification database is utilized to analyze the site data and generate a plurality of site scores, with each of the plurality of site scores providing a viability metric for the corresponding RF transmission site. The plurality of site scores is then utilized in rating each of the plurality of RF transmission sites. These ratings of the RF transmission sites are then utilized in an RF analysis.

Systems, devices and processes are provided to improve the design and implementation of radio frequency (RF) communication networks. Specifically, these various embodiments improve the likelihood of a successful RF network design by identifying and preferentially utilizing RF transmission sites having a relatively high probability of being successfully incorporated into the RF network. These various embodiments provide a site qualification database that includes site data for a plurality of RF transmission sites. When so implemented, the site qualification database is utilized to analyze the site data and generate a plurality of site scores, with each of the plurality of site scores providing a viability metric for the corresponding RF transmission site. The plurality of site scores is then utilized in rating each of the plurality of RF transmission sites. These ratings of the RF transmission sites are then utilized in an RF analysis.

Unified optical fiber-based distributed antenna systems (DASs) for supporting small cell communications deployment from multiple small cell service providers are disclosed. The unified optical fiber-based DASs disclosed herein are configured to receive multiple small cell communications from different small cell service providers to be deployed over optical fiber to small cells in the DAS. In this manner, the same DAS architecture can be employed to distribute different small cell communications from different small cell service providers to small cells. Use of optical fiber for delivering small cell communications can reduce the risk of having to deploy new cabling if bandwidth needs for future small cell communication services exceeds conductive wiring capabilities. Optical fiber cabling can also allow for higher distance cable runs to the small cells due to the lower loss of optical fiber, which can provide for enhanced centralization services.