Abstract: Methods, systems, and computer readable media described herein can be operable to facilitate location determination, communications with an AFC system, configuring operational parameters in response to an identification of active 6 GHz paths, and timing distribution and low-latency services. Methods, systems, and computer readable media are described herein for implementing and improving use of automated frequency coordination (AFC), operational deployment of the 6 GHz band for unlicensed devices, and use of the 6 GHz band for low-latency services, timing distribution, and QoS.

Abstract: Methods, systems, and computer readable media described herein can be operable to facilitate location determination, communications with an AFC system, configuring operational parameters in response to an identification of active 6 GHz paths, and timing distribution and low-latency services. Methods, systems, and computer readable media are described herein for implementing and improving use of automated frequency coordination (AFC), operational deployment of the 6 GHz band for unlicensed devices, and use of the 6 GHz band for low-latency services, timing distribution, and QoS.

Abstract: Methods, systems, and computer readable media described herein can be operable to facilitate location determination, communications with an AFC system, configuring operational parameters in response to an identification of active 6 GHz paths, and timing distribution and low-latency services. Methods, systems, and computer readable media are described herein for implementing and improving use of automated frequency coordination (AFC), operational deployment of the 6 GHz band for unlicensed devices, and use of the 6 GHz band for low-latency services, timing distribution, and QoS.

Abstract: Methods, systems, and computer readable media described herein can be operable to facilitate location determination, communications with an AFC system, configuring operational parameters in response to an identification of active 6 GHz paths, and timing distribution and low-latency services. Methods, systems, and computer readable media are described herein for implementing and improving use of automated frequency coordination (AFC), operational deployment of the 6 GHz band for unlicensed devices, and use of the 6 GHz band for low-latency services, timing distribution, and QoS.

Abstract: A method for calibrating an antenna and signal processing system enabling angle of arrival (AOA) determination for a frequency hopping signal, in which a calibration coefficient is determined in response to one or more calibration signals injected into the system at one or more of the frequencies in the hopping sequence and proximate in time to reception of the communication signal. The calibration coefficients are reflective of a frequency and time dependent parameter of a path between the antenna and wireless location sensor. The AOA is determined as a function of the calibration coefficient and the radio frequency energy of the received communication signal. Several embodiments of the method are illustrated.

Abstract: A method for generating geocoded data for a wireless communication system works over a plurality of network architectures and location processes. The method identifies the presence of mobile activity in the wireless communication network and in response collects wireless communication measurement data associated with the mobile activity. Geolocation is performed on the mobile associated with the activity and the geolocation and measurement data are combined forming geocoded data. The geocoded data is then supplied to a processing system to support implementation of optimization of the wireless network.

Abstract: A system for monitoring each channel of the communication link (307) for protocol messages and identifying a set of channels with valid protocol messages and, monitoring the set of channels to determine the transceivers (309) served by the set of channels and associating the transciver (309) with respective channels from the set of channels.

Abstract: A method and system for collecting test and measurement data for a wireless communication system utilizes a network overlay geo-location system to collect the data. The wireless communication system has plural base stations defining a signal coverage area for communication with a mobile appliance and collects test and measurement data simultaneous on the forward and reverse links during standard geo-location processes. The wireless communication system also collects test and measurement data when the network overlay geolocation system is in an idle state.

Abstract: A method for enabling a system to enhance the accuracy of a location estimate modifies weights in a weight matrix associated with receiver station measurements in parallel with successive refinements of the location estimate. In a typical location estimation scenario, several receiving stations simultaneously derive measurements of a signal from the emitter. Any one of these measurements is in general some function of the emitter location and the receiving station location. The aggregate of these measurements is often in excess of the minimum number of measurements required to provide an estimate of the emitter location. Where such an excess exists, the method proceeds by modifying the weights associated with the measurements in parallel with successive refinements of the location estimate. The method can be implemented over various cellular protocols with a consistent and significant enhancement in the accuracy of location estimates.

Abstract: Embodiments of a system and method are disclosed that enable geo-location of a mobile appliance (20) communicating over a frequency hopping air interface for a network overlay geolocation system having plural wireless location sensors (30). The wireless location sensors (30) include a radio receiver channel capable of receiving the forward channels of the air interface transmitted from the base station (10) to the mobile appliance (20). The network overlay geo-location system of the present disclosure monitors these forward channels and measures parameters that allow the geolocation system to synchronize with the hopping of the air interface on the reverse channel. The plurality of sensors measure an attribute of a signal on the reverse channel to thereby enable geo-location. Synchronization can also be reference to a stable system clock and the plurality of sensors may be tuned in reference to the system clock to enable measurement of the frequency hopping reverse channel.

Abstract: A novel system and method for tasking and reporting the geolocation of a mobile appliance for a wireless communications network overlay system is disclosed. Embodiments of the novel system and method allow for geolocating a mobile appliance regardless of the wireless air interface protocol standard utilized by the mobile appliance.

Abstract: A novel system and method for a network overlay geolocation system operating in a host wireless communication system with repeaters (350a, 350b) is disclosed. Embodiments of the novel system and method enable the geolocation system to determine if signals being received by the geolocation system arrive directly from a target mobile appliance or if the signals are passing through a repeater (350a, 350b) and therefore are subject to a known time delay. Embodiments of the novel system and method provide a more accurate geolocation of mobiles served by repeater stations than capable in the prior art.

Abstract: A system and method is disclosed for determining the location of a mobile appliance using the reverse pilot channel provided in CDMA 2000 communication systems to determine an attribute (e.g., time of arrival, angle of arrival, time difference of arrival, received power level) of a reverse pilot signal at one or more wireless location sensors. A network overlay of wireless location sensors monitors the reverse pilot channel for a target mobile's reverse pilot signal. The monitored signal may be compared to a reference signal to determine a correlation and thereby determine an attribute of the target mobile's reverse pilot signal. The method may be performed independently from the communication system and without requiring retrieval of information bits from the mobile appliance. The reference signal may be generated from the unique long spreading code mask of the target mobile appliance which is typically a function of the ESN of the target mobile appliance.

Abstract: A system and method for determining the positioning of mobile-appliance location determining sensors in a mobile-appliance communications network by estimating the positioning accuracy of the sensors.

Abstract: A method for calibrating an antenna and signal processing system enabling angle or arrival (AOA) determination for a frequency hopping signal, in which a calibration coefficient is determined in response to one or more calibration signals injected into the system at one or more of the frequencies in the hopping sequence and proximate in time to reception of the communication signal. The calibration coefficients are reflective of a frequency and time dependent parameter of a path between the antenna and wireless location sensor. The AOA is determined as a function of the calibration coefficient and the radio frequency energy of the received communication signal. Several embodiment of the method are illustrated.