Abstract: The present disclosure relates to computer-implemented systems and methods for device provisioning. The method may include receiving, by a computer, a selection instructions to detect wireless devices. The computer may include one or more processors, a radio transceiver, and a microphone. The method may also include identifying, by the radio transceiver, a plurality of wireless devices. Additionally, the method may include transmitting, by the radio transceiver to the wireless devices, respective requests for inaudible audio signal transmission. The method may also include receiving, by the microphone, a first inaudible audio signal from a first wireless device of the plurality of wireless devices. Further still, the method may include determining, based at least in part on the first inaudible audio signal, that the first wireless device is located in the same room as the user device.

Abstract: A mechanism is described for facilitating dynamic client-side triangulation to determine global position of computing devices according to one embodiment of the invention. A method of embodiments of the invention includes detecting, at a computing device, first location information associated with static wireless access points. The method may further include detecting, at the computing device, second location information associated with roaming computing devices broadcasting the second location information relating to their current locations, and dynamically determining a current location of the computing device based on the first and second location information.

Abstract: A mechanism is described for facilitating location-based zone management for computing systems according to one embodiment. A method of embodiments, as described herein, includes receiving, at a server computing device, a request to locate a destination relating to an entity, retrieving a first data relating to an outdoor navigation portion of an address relating to the destination, and retrieving a second data relating to an indoor navigation portion of the address relating to the destination. The first and second data are retrieved from a first database coupled with the first server computing device. The method may further include communicating the first data and the second data to a client computing device.

Abstract: A method for discovery of devices is described herein. The method includes connecting, via a processor, to a discovery node service. The method also includes sending, via the processor, a node name to the discovery node service. The method further includes sending, via the processor, data and content to be sent to a discovery node associated with the node name. The method also further includes receiving data and content from the discovery node, the data to include a list of devices subscribed to the discovery node.

Abstract: Disclosed herein are directionality detection techniques for smart door locks. According to various such techniques, a smart door lock may be configured to transmit an inside chirp on a private side of a door and an outside chirp on a public side of the door. The inside and outside chirps may comprise wireless signals of a type that typically does not penetrate walls, doors, and/or other barriers. In some embodiments, such directionality detection techniques may be utilized in combination with device discovery procedures performed according to a low-power wireless discovery protocol such as Bluetooth® Low Energy (BLE) or Neighbor Awareness Networking (NAN).

Abstract: A device stores an indication of a current floor of a multiple floor building on which a device is located. The device measures signal strengths of signals received at the device from transmitters having known locations on the floors of the building. The device selects one of the multiple floors as a candidate floor based in part on the measured signal strengths. The device increases a confidence level associated with the indication of the current floor if the candidate floor corresponds to the current floor, and decreases the confidence level if the candidate floor does not correspond to the current floor. The device replaces the indication of the current floor with the candidate floor if the confidence level is below a threshold.

Abstract: Embodiments of techniques and systems for dead-zone-location detection in wireless systems are described. In embodiments, a wireless device may be configured to receive radio signals and provide indicators that convey signal strength of received radio signals. The received radio signals are considered degraded when signal strength of the received radio signals is below a threshold level. The wireless device may also be configured to determine which dead zone the wireless device is currently located, in response to a determination that receipt of radio signals is degraded. Other embodiments may be described and claimed.

Abstract: A mechanism is described for facilitating proximity and context-based deduction of global positioning of computing devices according to one embodiment of the invention. A method of embodiments of the invention includes detecting wireless proximity of a plurality of computing devices with respect to a computing device, and selecting one or more of the plurality of computing devices based on their detected proximity to the computing device. The method may further include receiving contextual information from the one or more computing devices, and semantically deducing location of the computing device based on the received contextual information.

Abstract: Embodiments of the invention address how trilateration processes are affected by physical placement and sub-optimal selection of peer devices (PDs) used to obtain a location of a mobile computing device. Embodiments of the invention describe processes for selecting nearest PDs over further PDs, as received signal strength indicator (RSSI) measurements are more reliable—i.e., said “nearest PDs” provide more accurate distance measurements while improving the probability of finding more intersection points. Embodiments of the invention further describe selecting a physical spread of PDs to help increase the number of intersection points while helping distinction/resolution of the location of the mobile device in both the ‘x’ (longitude) and the ‘y’ (latitude) directions. Embodiments of the invention further enhance trilateration processes by utilizing dampening values for calculated location poll data.

Abstract: A method of generating wireless signal information includes receiving relative movement data generated by sensors and wireless signal data generated by a wireless signal module at a computing system, the sensors and module for detecting wireless signals located in a portable electronic device (PED). The method further includes generating landmark information at a landmark detection module based on the relative movement data, the sensor data and the wireless signal data. The method further includes generating a plurality of Simultaneous Localization and Mapping (SLAM) estimate locations based on the landmark information and the relative movement data at a SLAM optimization engine. The method further includes assembling a first database of locations and corresponding wireless signal strength and access points. The method further includes generating additional information concerning locations and wireless signal information based on the first database.

Abstract: A method of generating wireless signal information includes receiving relative movement data generated by sensors and wireless signal data generated by a wireless signal module at a computing system, the sensors and module for detecting wireless signals located in a portable electronic device (PED). The method further includes generating landmark information at a landmark detection module based on the relative movement data, the sensor data and the wireless signal data. The method further includes generating a plurality of Simultaneous Localization and Mapping (SLAM) estimate locations based on the landmark information and the relative movement data at a SLAM optimization engine. The method further includes assembling a first database of locations and corresponding wireless signal strength and access points. The method further includes generating additional information concerning locations and wireless signal information based on the first database.

Abstract: A mechanism is described for facilitating detection and communication of geo-locations for devices according to one embodiment. A method of embodiments, as described herein, includes tracking, at a first smart device, one or more devices including a second smart device, and first and second smart devices including a computing device, and establishing a first connection with the second smart device, establishing further comprising exchanging first location data between the first smart device and the second smart device, establishing further including communicating a first current location associated with the first smart device to the second smart device. The method may further include identifying a second current location associated with the second smart device. The second current location may be initially recorded and iteratively rewritten at a first local memory of the first smart device.

Abstract: Methods and mechanisms for exchanging map information in a wireless communication. In an embodiment, map information to represent at least a portion of a map is advertised by a first communication device communication independent of any request for the map information being received in a data session or a voice session. In another embodiment, a second communication device receives the wireless communication and generates a representation of the map based on the advertised map information.

Abstract: Embodiments of the invention address how trilateration processes, used to obtain a location of a mobile computing device, are affected by physical placement and sub-optimal selection of peer devices (PDs). Embodiments of the invention describe processes for selecting nearest PDs over further PDs, as received signal strength indicator (RSSI) measurements are more reliable—i.e., said “nearest PDs” provide more accurate distance measurements while improving the probability of finding more intersection points. Embodiments of the invention selectively utilize abnormal location poll data when executing location determination processes. Embodiments of the invention further enhance trilateration processes by utilizing dampening values for calculated location poll data.

Abstract: Embodiments of the invention address how trilateration processes are affected by physical placement and sub-optimal selection of peer devices (PDs) used to obtain a location of a mobile computing device. Embodiments of the invention describe processes for selecting nearest PDs over further PDs, as received signal strength indicator (RSSI) measurements are more reliable—i.e., said “nearest PDs” provide more accurate distance measurements while improving the probability of finding more intersection points. Embodiments of the invention further describe selecting a physical spread of PDs to help increase the number of intersection points while helping distinction/resolution of the location of the mobile device in both the ‘x’ (longitude) and the ‘y’ (latitude) directions. Embodiments of the invention further enhance trilateration processes by utilizing dampening values for calculated location poll data.

Abstract: A mechanism is described for facilitating dynamic client-side triangulation to determine global position of computing devices according to one embodiment of the invention. A method of embodiments of the invention includes detecting, at a computing device, first location information associated with static wireless access points. The method may further include detecting, at the computing device, second location information associated with roaming computing devices broadcasting the second location information relating to their current locations, and dynamically determining a current location of the computing device based on the first and second location information.

Abstract: A mechanism is described for facilitating proximity and context-based deduction of global positioning of computing devices according to one embodiment of the invention. A method of embodiments of the invention includes detecting wireless proximity of a plurality of computing devices with respect to a computing device, and selecting one or more of the plurality of computing devices based on their detected proximity to the computing device. The method may further include receiving contextual information from the one or more computing devices, and semantically deducing location of the computing device based on the received contextual information.

Abstract: A method of improving the yield of plants such as legumes by the application thereto of plant growth regulants comprising nitro-oximino alkanoic acids and derivatives thereof having the general formula: ##STR1## wherein n is an integer from 1 to 12 and wherein Y is selected from the group consisting of OR, SR, NRR' in which R and R' are independently selected from the group consisting of hydrogen, alkyl, cycloalkyl, alkaryl, aralkyl, aryl, heterocyclic, alkenyl and alkynyl, and OR" in which R" is an alkali metal.