Abstract: A method, apparatus, and computer program product are provided to enable the provision of a mechanism by which a device participating in a collaborative application may synchronize with other participating devices. A method may include providing for operation of a collaboration application, providing for transmission of a multicast reference time request to a wireless access point, receiving a multicast reference time message, establishing a reference time in response to receiving the reference time message, and synchronizing the collaboration application using the reference time. The synchronization of the collaboration application may be performed in response to receiving an acknowledgement message from collaborating devices. The method may further include providing for transmission of a second multicast reference time request in response to not receiving an acknowledgement message from the collaborating devices. The multicast reference time message may be received from the wireless access point.

Abstract: Techniques are described for wireless communication. In one method, a positioning reference signal (PRS) may be generated. The PRS may be configured in at least one downlink subframe among a plurality of downlink subframes. The PRS may be transmitted in the at least one downlink subframe using an unlicensed radio frequency spectrum band.

Abstract: In one embodiment, a method for selecting a sub-set of satellites from a set of N satellites is provided. The method includes recursively evaluating each sub-set of N?P satellites of a set of N satellites. If only one sub-set satisfies one or more first criterion, then the one sub-set that satisfies the one or more first criterions is selected. If, however, more than one sub-set satisfies the one or more first criterion, then the sub-sets that satisfy the one or more first criterion are evaluated with respect to one or more second criterion and the one sub-set that optimizes the one or more second criterion is selected. Once the selected set of N satellites is equal to the number of satellites from which a receiver is configured to calculate a navigation solution, then that selected set of N satellites is used to calculate a navigation solution.

Abstract: A counterfeit detection system may include a memory storing a module comprising machine readable instructions to determine a X-identification (XID) associated with a product. The XID may include an unencrypted component and/or an encrypted component associated with a parameter associated with the product. The machine readable instructions may further include selecting one or more validation rules, from a plurality of validation rules, to select one or more validation techniques from a plurality of validation techniques used to determine an authenticity of the product. The machine readable instructions may further include using the one or more selected validation techniques to determine the authenticity of the product based on the XID associated with the product. The counterfeit detection system may include a processor to implement the module.

Abstract: Techniques for supporting location services for a home Node B (HNB) and its user equipments (UEs) are disclosed. In an aspect, location services may be supported for a UE by having an HNB inter-work between user plane and control plane location solutions. In one design, the HNB receives a request for a location service for the UE and communicates (i) with a location server via the user plane location solution and (ii) with the UE via the control plane location solution to support the location service for the UE. The HNB inter-works between the user plane and control plane location solutions. In another aspect, a location server may be used to support assisted GNSS (A-GNSS) for HNBs and UEs. In one design, an HNB exchanges PCAP messages with the location server via an HNB GW and exchanges RRC messages with a UE to support a location service for the UE.

Abstract: The effective use of weak GPS signals that are present in various environments enables an electronic device to pinpoint its location in such environments. The electronic device uses an antenna to perform sequential scanning in multiple directions for global positioning system (GPS) signals. The electronic device further analyzes GPS signals obtained from scanning the multiple directions to determine a number of acquired GPS satellites that provided the GPS signals. The GPS signals include code phases of the acquired GPS satellites. The electronic device then computes a location of the electronic device based on the code phases of the acquired GPS satellites when the number of acquired GPS satellites meets a threshold.

Abstract: Embodiments provide for a positioning device comprising a global navigation satellite system (GNSS) receiving unit, a communication antenna and a communication module. The GNSS receiving unit is adapted to receive satellite information. The communication antenna allows for reception and/or transmission of complementary data. The communication module is connectable to the GNSS receiving unit and the communication antenna. The communication module is configured to provide complementary data received at the communication antenna to the GNSS receiving unit and/or to provide complementary data generated at the GNSS receiving unit to the communication antenna. The communication module is detachable or switchable for adaptation to an available communication technology.

Abstract: A position information processing device according to an exemplary embodiment of the present invention can include a GPS receiver adapted and configured to receive a first satellite signal, an interdevice receiver adapted and configured to receive a second satellite signal from a mobile phone, a GPS information processor adapted and configured to compare the first satellite signal with the second satellite signal and generate a third satellite signal for calculating a current position, and a controller adapted and configured to use the third satellite signal to calculate coordinates of the current position. The proposed position information processing device uses the satellite signal that is received from the mobile phone, and therefore the accuracy of the position measurement can be improved.

Abstract: Methods and apparatus for determining an assistance data transmission time to account for cell timing acquisition are disclosed. In an example method, a network node determines whether a target wireless communication node (110) will need to obtain timing information for at least one cell to be included in the assistance data. The network node then estimates an acquisition time ?T for the wireless communication node (110) to obtain timing information for at least a first cell. The network node then transmits the positioning assistance data to the wireless communication node (110) at least ?T before an expected time for the wireless communication node (110) to begin performing positioning measurements. In some embodiments, the network node is configured to wait for a time period at least equal to an expected reporting delay that accounts for the acquisition time ?T, before deciding that the positioning has failed.

Abstract: Particular embodiments described herein provide for an apparatus, such as a wireless electronic device, that includes a memory element configured to store electronic code, a processor operable to execute instructions associated with the electronic code, and at least one module. The at least one module is configured to receive first location information identifying a first location associated with an electronic device. The at least one module is further configured to receive first connection location information indicative of a second location of the electronic device at a time of connection with a first wireless device. The at least one module is further configured to evaluate for a presence of the first wireless device when the first location is within a predetermined distance of the second location.

Abstract: Various methods, apparatuses and/or articles of manufacture are provided which may be implemented in one or more electronic devices supporting mobile device positioning within an indoor environment. Tiered positioning assistance data (tiered-PAD) corresponding to an indoor environment may be generated and/or distributed. Mobile device positioning and/or navigation capabilities may be based, at least in part, on tiered-PAD corresponding to the indoor environment. Tiered-PAD may be provided to a plurality of mobile devices. A given mobile device may, for example, select applicable portion(s) of tiered-PAD to affect one or more positioning functions and/or the like which may be performed, at least in part, by the mobile device.

Abstract: Embodiments of the present invention provide a method for obtaining configuration data and a method for providing configuration data, a base station device, and a network management system, where the method for obtaining configuration data includes: obtaining, by the base station device, site identifier information of a site where the base station device is located; sending, by the base station device, the site identifier information to a network management system; and receiving, by the base station device, configuration data corresponding to the site identifier information and sent by the network management system, where the configuration data is obtained by the network management system according to a correspondence between the site identifier information and the configuration data.

Abstract: A method, apparatus, and computer program product are provided to enable the provision of a mechanism by which a device participating in a collaborative application may synchronize with other participating devices. A method may include providing for operation of a collaboration application, receiving a signal from a sensor, establishing a reference time in response to receiving the signal from the sensor, and synchronizing the collaboration application using the reference time. The sensor may include an accelerometer and the signal may include a sampling of information from the sensor. The sampling may be conducted during a pre-defined time interval or possibly until a bump is detected. Establishing the reference time may include detecting a maximum value of the signal and/or detecting the signal exceeding a pre-defined threshold. Establishing the reference time may not require wireless communication.

Abstract: A method and an apparatus for providing a Local BreakOut (LBO) service in a wireless communication system are provided. In the method for providing an LBO service in a wireless communication system, after an access authentication procedure between an authentication server and a terminal, a femto gateway receives a subscriber profile including LBO service flow information from the authentication server to provide the LBO service flow information to a femto base station through initial service flow setting between the terminal and the femto gateway. The femto base station sets an LBO service flow through a Dynamic Service Addition (DSA) procedure. The terminal performs a Dynamic Host Configuration Protocol (DHCP) procedure through the LBO service flow setting, and obtains an IP address for LBO based on the DHCP procedure.

Abstract: Methods and apparatus for supporting reference signals for positioning measurements are disclosed. Methods include subframe configuration, subframe structures, measurement opportunities using a set of downlink subframes which are not all consecutive, handling of subframes containing reference signals and system signals such as synchronization signals, paging occasions and Multicast Broadcast Multimedia Service (MBMS), and related control signaling between a long term evolution (LTE) network and a wireless transmit/receive unit (WTRU). Moreover, methods to resolve allocation conflicts arising between positioning reference signals and other reference signals are disclosed.

Abstract: Methods, systems, and products determine electromagnetic reflective characteristics of ambient environments. A wireless communications device sends a cellular impulse and receives reflections of the cellular impulse. The cellular impulse and the reflections of the cellular impulse may be compared to determine the electromagnetic reflective characteristics of an ambient environment.

Abstract: Assisted-GPS for a portable biometric monitoring device is provided. The portable biometric monitoring device may obtain updated ephemeris data from an associated secondary device via a short-range, low-power communication protocol. The secondary device may be a computing device such as a smartphone, tablet, or laptop. Various rules may control when the ephemeris data is updated. The ephemeris data may be used in the calculation of the global position of the portable biometric monitoring device. Additionally, the portable biometric monitoring device may communicate downloaded position fixing data to the associated secondary device. The associated secondary device may then calculate the global position from the position fixing data.

Abstract: The disclosed subject matter relates to an architecture that can leverage Universal Mobile Telecommunication System (UMTS) Terrestrial Radio Access Network (UTRAN) features to facilitate more efficient or more robust communication with a femtocell network. In particular, features such as a UMTS localized common pilot channel along with various UTRAN features can enable communications to be directed to specific targets such as to a specific home nodeB (HNB) or to a specific mobile device served by the HNB, while also reducing macro network load.

Abstract: Particular embodiments described herein provide for an apparatus, such as a wireless electronic device, that includes a memory element configured to store electronic code, a processor operable to execute instructions associated with the electronic code, and at least one module. The at least one module is configured to receive first location information identifying a first location associated with an electronic device. The at least one module is further configured to receive first connection location information indicative of a second location of the electronic device at a time of connection with a first wireless device. The at least one module is further configured to evaluate for a presence of the first wireless device when the first location is within a predetermined distance of the second location.

Abstract: A method and system for assisting mobile stations to locate a satellite use an efficient messaging format. A server computes a correction between coarse orbit data of a satellite and precise orbit data of the satellite. A coordinate system is chosen such that variation of the correction is substantially smooth over time. The server further approximates the correction with mathematical functions to reduce the number of bits necessary for transmission to a mobile station. The mobile station, upon receiving the coefficients, evaluates the mathematical functions using the coefficients and a time of applicability (e.g., the current time), converts the evaluated result to a standard coordinate system, and applies the conversion result to the coarse orbit data to obtain the precise orbit data.

Abstract: Implementations relate to systems and methods for location assistance using devices (104) in a personal area network (PAN). In one scenario, a user may use two separate location-enabled devices, such as a wearable personal device (102) and a cellular telephone device (104). In cases, one of those devices may have reached a higher or farther-developed state in terms of generating or storing location information (108) for the user's current position, as compared to the opposite device. This can take place, for instance, when the first (e.g. wearable) device (102) is first turned on. The two devices use platforms and techniques to exchange location information and carry out GPS or other operations to furnish the device that is lagging in position processing progress with assistance which will speed up or otherwise enhance the position fix for that device.

Abstract: Method and apparatuses involving satellite position signals are disclosed. Based on data indicating a usage environment, parameters, for example acquisition parameters or calculation parameters, are adapted.

Abstract: Methods and apparatuses for a mobile station to obtain a position fix using synchronous hybrid positioning and asynchronous hybrid positioning techniques are described. In one embodiment, a wireless communication apparatus may transmit a request to a mobile station for fine time assistance (FTA) corresponding to a global navigation satellite system (GNSS). The apparatus may be configured to receive the FTA, first timing measurements from one or more base stations, and second timing measurements from the GNSS. The apparatus may identify whether the FTA was received from the mobile station. If it is determined that the FTA was received, then a system frame number (SFN) received within the FTA may be identified, wherein the SFN is associated with one of the base stations. The apparatus may then establish a position fix for the mobile station using a synchronous hybrid positioning technique that involves relating the timing measurements to a time scale associated with the SFN.

Abstract: The present invention is related to location positioning systems, and more particularly, to a method and apparatus for providing an update of ephemeris information. According to one aspect, GPS enabled devices in the signal unavailable area monitors the state of its ephemeris data and time information. When the ephemeris data and time information become out of date, the GPS enable device uses an ad hoc Bluetooth network to retrieve ephemeris data and time information from another GPS enabled device with more current data. According to further aspects, a map of a deep hole region in which GPS and other cellular signals are not available, is generated to enable power reduction and cost saving measures.

Abstract: For supporting a satellite based positioning of a mobile arrangement (30, 40) with assistance data, a communication network converts parameters of a dedicated orbit model describing a movement of a satellite (50, 60), which dedicated orbit model is defined for a particular satellite based positioning system, into parameters of a common orbit model describing a movement of a satellite (50, 60). Alternatively or in addition, the network replaces a reference value that is based on a satellite based positioning system time in available parameters of an orbit model by a reference value that is based on a communication system time. After the parameter conversion and/or the reference value replacement, the parameters are provided as a part of assistance data for the satellite based positioning.

Abstract: A vehicle-based radio frequency (RF) hardware component comprises first and second antennas, a digitizer, a serializer, and a serial output. The first antenna receives, over-the-air, a first analog Global Navigation Satellite System (GNSS) signal in a first frequency band. The second antenna receives, over-the-air, at least a second analog GNSS signal in a second frequency band, wherein the first frequency band and the second frequency band are separate and distinct. The digitizer digitizes the first analog GNSS signal into a first digitalized GNSS signal and digitizes the second analog GNSS signal into a second digitized GNSS signal. The serializer serializes the digitized GNSS signals into a serialized output signal. The serial output communicatively couples the digitized GNSS signals, as the serialized output signal, directly from a location in a vehicle of the radio frequency hardware component to a separate communication device that is also coupled with the vehicle.

Abstract: A stand-alone radio frequency (RF) hardware component comprises first and second antennas, a digitizer, a serializer, and a serial output. The first antenna receives, over-the-air, a first analog Global Navigation Satellite System (GNSS) signal in a first frequency band. The second antenna receives, over-the-air, at least a second analog GNSS signal in a second frequency band, wherein the first frequency band and the second frequency band are separate and distinct. The digitizer digitizes the first analog GNSS signal into a first digitalized GNSS signal and digitizes the second analog GNSS signal into a second digitized GNSS signal. The serializer serializes the digitized GNSS signals into a serialized output signal. The serial output communicatively couples the digitized GNSS signals, as the serialized output signal, directly from the RF hardware component to a communication device that is removably couplable with the stand-alone RF hardware component.

Abstract: A global positioning system (GPS) receiver that is configured to rapidly acquire GPS signals in space applications and a method for rapidly acquiring GPS signals in space applications is disclosed. In an embodiment, the GPS receiver includes, but is not limited to, a GPS signal acquisition component. The GPS signal acquisition component is adapted to acquire a GPS signal by receiving data from the GPS signal and processing the data to detect the GPS signal.

Abstract: A position fix identifying a geographic location of a receiver is received. The position fix was generated using signals received at the receiver from respective high-altitude signal sources (such as satellites). Imagery of a geographic area that includes the geographic location is also received. The imagery is automatically processed to determine whether one or more of the high-altitude signal sources were occluded from the geographic location when the position fix was generated. In response to determining that one or more of the high-altitude signal sources were occluded from the geographic location when the position fix was generated, the position fix is identified as being potentially erroneous.

Abstract: Described is a technology by which GPS-capable devices work with a cloud service to receive satellite visibility-related data. The satellite visibility-related data may be used to determine a location, and/or to abort a search for satellites. The cloud service may use crowd data from other GPS-capable devices. In one aspect, line-of-sight satellites are differentiated from other satellites, and used to determine which satellite signals are more trustworthy. Reflected signals also may be determined.

Abstract: The technology disclosed relates to implementing a novel-testing framework that combines playback of captured GNSS signals with real-time emulation of assisted global navigation satellite system telemetry (abbreviated A-GNSS) in a test session with a mobile device. In particular, it can be used for testing A-GNSS performance of communication devices, navigation systems, telematics and tracking applications.

Abstract: Disclosed in some examples are methods, systems and machine readable mediums to efficiently stream data across restricted networks. In some examples, this streamed data may be sent more efficiently using lower overhead protocols such as UDP. In order to bypass the aforementioned limitations on these lower overhead protocols, the client may send a periodic update message to the server. This update message maintains the openings in the network firewalls and updates the server on the client's status. This update message may be sent much less frequently than a typical TCP acknowledgement, and the lower overhead protocol may be a protocol that does not retransmit lost or corrupted packets—thereby eliminating unnecessary overhead. In some examples this streamed data may be GNSS correction data. In some examples, the client may be behind one or more network firewalls.

Abstract: Examples disclosed herein relate to a method performed at a first mobile station that includes receiving a request for positioning assistance data from a second mobile station over a communication link; and transmitting one or more messages to the second mobile station in response to the request, wherein the one or more messages include the requested positioning assistance data, wherein the first mobile station is on a synchronous network.

Abstract: A combined GNSS and FM receiver receives FM signals comprising satellite navigation data from an AGNSS server. Associated navigation information such as a position fix is determined based on the received satellite navigation data. The received satellite navigation data are GNSS assistance data or LTO data. The AGNSS server generates the satellite navigation data by acquiring GNSS data from a satellite reference network. The acquired GNSS data comprise, for example, GPS data, GLONASS data and/or GALILEO data. The generated satellite navigation data are broadcasted as FM signals through RDS and/or RBDS to the combined GNSS and FM receiver. The combined GNSS and FM receiver receives updated satellite navigation data in subsequent FM signals, periodically or aperiodically, and updates associated navigation information, accordingly. The combined GNSS and FM receiver decodes the received FM radio signals for the updated satellite navigation data generated at the AGNSS server before being transmitted.

Abstract: A Global Navigation Satellite System (GNSS) chipset embedded within the cellular device is accessed. The GNSS chipset calculates raw observables that include raw pseudoranges and carrier phase information. The raw observables are extracted from the GNSS chipset for processing elsewhere in the cellular device outside of the GNSS chipset. Smoothed pseudoranges are provided by smoothing the raw pseudoranges based on the carrier phase information. The accessing, the extracting and the providing are performed by one or more hardware processors located in the cellular device and outside of the GNSS chipset.

Abstract: Methods and devices may request and provide assistance data from an assistance server to a receiver in a global navigation satellite system. A request for assistance data may include a preference list of navigation models suitable for the requesting receiver. Multiple preference lists for different navigation model types (e.g., orbit model, clock model, almanac model) may be included in a single list and/or data structure, or as multiple lists and/or data structures. An assistance server may receive and process the preference list, for example, by parsing and traversing the ordered list(s) for different navigation model types, in order to provide satellite navigation data to the receiver in accordance with suitable navigation models that are available at both the receiver and the assistance server.

Abstract: A method for supporting location services in a mobile radio communications system, in which method a mobile station receives from at least one network element involved in location services, for the implementation of a position measurement procedure, at least one information element indicating if the method type required for that position measurement procedure is a “Conventional GPS” method type where the mobile station behaves as a conventional satellite positioning system receiver.

Abstract: An implementation of a system, device and method for communicating location data of a mobile station, enhancing location data, optimally communicating Assistance Data, and/or reducing rebids of Measure Position Request messages in a wireless network.

Abstract: Methods and apparatuses are provided for use by devices within in wireless communication network to request and/or provide assistance data and/or other like data associated with various Satellite Positioning Systems (SPSs).

Abstract: A method of extracting pseudorange information using a cellular device. A Global Navigation Satellite System (GNSS) chipset which is physically remote from a cellular device is accessed which provides raw GNSS observables information based upon signals received from a circularly polarized GNSS antenna. The raw GNSS observables information is wirelessly transmitted from the GNSS chipset to the cellular device. The raw GNSS observables information is extracted by a processor of the cellular device. The raw GNSS observables information, in addition to GNSS corrections from at least one correction source, is used by the processor to determine a position of the circularly polarized GNSS antenna.

Abstract: A method for localizing a terminal includes transmitting the signal by the terminal; receiving the signal by a first and a second satellite; transmitting the signal from each satellite to a receiving station; demodulating the signal received by the first satellite to determine a signal content and the time of arrival of the signal transmitted by the terminal at the receiving station via the first satellite; determining the time of arrival of the signal transmitted by the terminal at the receiving station via the first and second satellite; determining a position for the terminal by triangulation.

Abstract: Each of a first and a second navigation satellite system (NSS) are adapted to operate according to a first and a second specification, respectively, and each includes a first and a second plurality of satellite vehicles (SVs), respectively. Each of the first and the second plurality of SVs are adapted to be identified by a first and a second plurality of unique corresponding identifications (IDs), respectively. A processor is adapted to receive and identify a first plurality of corresponding signals transmitted from the first plurality of SVs in response to the first plurality of unique corresponding IDs. The processor is adapted to receive and identify a second plurality of corresponding signals transmitted from the second plurality of SVs in response to the second plurality of unique corresponding IDs. The processor is adapted to determine position location information in response to receiving and identifying the first plurality of corresponding signals and the second plurality of corresponding signals.

Abstract: Systems and methods of providing fine-time assistance (FTA) for a mobile device are described herein. A GNSS time is received from a GNSS satellite at a GNSS receiver. The GNSS time is then transferred to an access point (AP) over a wired network. The AP is coupled to the mobile device over a wireless local area network (WLAN). A round trip time (RTT) between the AP and the mobile device over the WLAN is determined, for example by exchanging one or more communications between the mobile device and the AP over the wireless local area network (WLAN). The GNSS time is then transferred from the AP to the mobile device over the WLAN. A FTA based GNSS time is calculated at the mobile device based on the GNSS time received from the AP and the RTT.

Abstract: A system and methods for location-based authentication using medium earth orbit (MEO) and low earth orbit (LEO) satellites are presented. Location of a client device is authenticated based on at least one client received MEO satellite signal received from at least one MEO satellite at the client device and at least one client received LEO satellite signal received from at least one LEO satellite at the client device.

Abstract: Systems and methods provide a network's synchronization status to a terminal when the terminal receives a transmission from the network. This network synchronization status can be indicated in accordance with various methods including, but not limited to the following: with a status flag in a network message; in a network capability indication; in a network's positioning capability indication; cell/network time relation information; in a time relation information of different Radio Access Technologies; and implicitly with another parameter and/or by a request for a certain measurement. When the network's synchronization status is determined, accurate time information/time assistance data can be maintained at the terminal.

Abstract: Locating satellites (e.g., GPS) are culled into a preferred group having a longest dwell time based on a time passing through an ellipsoid arc path through a cone of space, and communicated to mobile devices within a particular region (e.g., serviced by a particular base station). The culled locating satellites may select those visible, or more preferably those locating satellites currently within a cone of space above the relevant base station are selected for communication by a mobile device within the service area of the base station. The inverted cone of space may be defined for each antenna structure for any given base station, and each has 360 degrees of coverage, or less than 360 degrees of coverage, with relevant locating satellites. Thus, cell sites may be specifically used as reference points for culling the ephemeris information used to expedite Assisted GPS location determinations.

Abstract: A wireless communication device transmits a position assistance request. A system database receives and processes the position assistance request to determine a time of the request and a location of the wireless communication device and processes the time and the location to determine if the system database stores positioning satellite information for the time and the location. The system database transfers the positioning satellite information to the wireless communication device if the positioning satellite information is for the time and the location. The system database transfers the position assistance request to a position determining entity if the system database does not store the positioning satellite information for the time and the location.

Abstract: A method of communicating corrections for information related to satellite signals among global navigation satellite system (GNSS) receivers is described. The method includes at a first GNSS device determining a component of position of a satellite. The component is then divided by a first value to thereby obtain an integer value and a remainder value, and the only the remainder value is transmitted from the first GNSS device to the second GNSS device. Knowing the first value, the second GNSS device calculates the component of position.

Abstract: Methods, program products, and systems for adaptive location determination are described. A server computer can receive location information from location-aware mobile devices (e.g., GPS-enabled devices) located in a cell of a cellular communications network. The server computer can calculate an average geographic location using the received locations and distance between each location and the calculated average. The server computer can exclude locations that are sufficiently far away from the average. The server computer can repeat the calculation and exclusion until a level of precision is achieved for the average geographic location. The average geographic location and an error margin can be associated with the cell. The server computer can provide the average geographic location and the error margin to a mobile device (e.g., a non-GPS-enabled device) that is in the cell. The mobile device can display the information on a map display of the mobile device.

Abstract: A method and apparatus for determining a location of a remote receiver is described. The remote receiver receives satellite tracking data from a server, which it stores in memory. This satellite tracking data has a predetermined validity time period associated with it. When a connection cannot be established between the remote receiver and the server and the predetermine validity time period of the satellite tracking data has expired, the remote receiver calculates acquisition assistance data using the expired satellite tracking data for use with obtaining ephemeris data from a satellite. The remote receiver then calculates its position using the receiver ephemeris data.