Abstract:
A first Mobile Repeater System (MRS), configured to serve as an access point associated with a Basic Service Set (BSS), broadcasts a Basic Service Set Identifier (BSSID). Other Mobile Repeater Systems (MRSs) join the BSS to create a local ad hoc trunked site in which each of the MRSs are communicatively coupled via at least one WLAN communication link. These MRSs include the first MRS and a second MRS. The first MRS can be configured to provide a control channel for communication with a first subscriber unit, and the second MRSs can be configured to provide a first trunked traffic channel for communication with the first subscriber unit.
Abstract:
A method and apparatus are disclosed for setting an initial transmit power level of a deployable network that overlaps in coverage with a WAN. Multiple transmit power levels are determined. For each transmit power level, a geographical coverage area of the deployable network at an incident is determined based on a signal propagation model, a first set of mobile devices is determined that are within the geographical coverage area and that are involved in responding to the incident, and a second set of mobile devices is determined that are within the geographical coverage area, that are not involved in responding to the incident, and that may be interfered with by transmissions of the deployable network. A transmit power level of the multiple transmit power levels then is selected as the initial transmit power level based on the first and second sets of mobile devices determined for each transmit power level.
Abstract:
A method and services network element are provided that provide for queued admissions control in a wireless communication system by receiving a bearer establishment request associated with a user equipment, determining that a cell where the user equipment is located is congested, in response to determining that the cell is congested, creating a bearer establishment request record (BERR) associated with the user equipment and the bearer establishment request, wherein the BERR comprises priority information associated with the BERR, and adding the BERR to a queue, wherein the queue is associated with a cell serving the user equipment, wherein the BERR is positioned in the queue based on the priority information, and wherein bearer establishment requests associated with BERRs in the queue are submitted based on a position of the BERRs in the queue.
Abstract:
A method and apparatus are provided for positioning an unmanned robotic vehicle (URV). The URV captures a set of one or more of image and non-image information of an object while positioned at a first position, provides the set of image/non-image information to a server entity, in response to providing the set of image/non-image information, receives a three-dimensional (3D) model associated with the object, autonomously determines a second position based on the 3D model, and autonomously navigates to the second position. At the second position, the URV may capture further image and/or non-image information and, based on the further captured image/non-image information, autonomously determine, and navigate to, a third position. The steps of capturing further image and/or non-image information and, based on the captured image and/or non-image information, autonomously determining and navigating to further positions may be repeated indefinitely, or until otherwise instructed.
Abstract:
Traffic light control using destination information in calendar data of a user device includes storing calendar data including destination information in a plurality of user devices in a community. A next step includes obtaining the calendar data by a community authority coordinator operable to communicate with the user devices through a community network. A next step includes controlling at least one traffic light in the community in response to the destination information. Optionally, the traffic light can be controlled in response to time, date, location, route, and number of vehicles, to alleviate future road congestion.
Abstract:
A method and apparatus are provided for positioning an unmanned robotic vehicle (URV). The URV captures a set of one or more of image and non-image information of an object while positioned at a first position, provides the set of image/non-image information to a server entity, in response to providing the set of image/non-image information, receives a three-dimensional (3D) model associated with the object, autonomously determines a second position based on the 3D model, and autonomously navigates to the second position. At the second position, the URV may capture further image and/or non-image information and, based on the further captured image/non-image information, autonomously determine, and navigate to, a third position. The steps of capturing further image and/or non-image information and, based on the captured image and/or non-image information, autonomously determining and navigating to further positions may be repeated indefinitely, or until otherwise instructed.
Abstract:
A method and a system for operating a subscriber unit to seamlessly switch between a trunked mode operation (TMO) and a direct mode operation (DMO) in a communication system. The communication system includes one or more subscriber units communicating in trunked mode operation on a first communication channel via a base station and the subscriber units communicating in direct mode operation on a second communication channel via a direct mode gateway station. When the subscriber units communicate in the TMO and when the signal quality on the first communication channel is below the predetermined threshold, the subscriber units automatically switch to the direct mode operation. When the subscriber units communicate in DMO and when the signal quality on the second communication channel is below the predetermined threshold, the subscriber units automatically switch to the trunked mode operation.
Abstract:
Traffic light control using destination information in calendar data of a user device includes storing calendar data including destination information in a plurality of user devices in a community. A next step includes obtaining the calendar data by a community authority coordinator operable to communicate with the user devices through a community network. A next step includes controlling at least one traffic light in the community in response to the destination information. Optionally, the traffic light can be controlled in response to time, date, location, route, and number of vehicles, to alleviate future road congestion.