Abstract: Described herein are techniques to enable a mobile device to perform multi-source estimation of an altitude for a location. A baseline altitude may be determined at ground level for a location and used to calibrate a barometric pressure sensor on the mobile device. The calibrated barometric pressure sensor can then estimate changes in altitude relative to ground level based on detected pressure differentials, allowing a relative altitude to ground to be determined. Baseline calibration for the barometric sensor calibration can be performed to determine an ambient ground-level barometric pressure.

Abstract: A mobile wireless transmitter is detected from location data received for a plurality of wireless transmitters obtained through crowdsourcing or wardriving. Location data is held until sufficient time or enough location data is collected from which movement of a wireless transmitter can be detected. Sets of measurement data for each wireless transmitter are determined from the collected location data. The sets of measurement data may include, e.g., Service Set Identifier (SSID), a round trip time (RTT) variance, and/or a neighbor relationship graph for each wireless transmitter. The mobile wireless transmitter is identified from the sets of measurement data. An almanac database may then be published in which any mobile wireless transmitters are identified or excluded.

Abstract: A mobile wireless transmitter is detected from location data received for a plurality of wireless transmitters obtained through crowdsourcing or wardriving. Location data is held until sufficient time or enough location data is collected from which movement of a wireless transmitter can be detected. Sets of measurement data for each wireless transmitter are determined from the collected location data. The sets of measurement data may include, e.g., Service Set Identifier (SSID), a round trip time (RTT) variance, and/or a neighbor relationship graph for each wireless transmitter. The mobile wireless transmitter is identified from the sets of measurement data. An almanac database may then be published in which any mobile wireless transmitters are identified or excluded.

Abstract: Methods, systems, computer-readable media, and apparatuses for determining a flight route for a flight of an unmanned aerial vehicle (UAV) are presented. The flight-specific route for the UAV is determined dynamically during the flight or in advance before the flight, using navigation assistance data that includes flight-specific navigation assistance data for a plurality of geographic zones determined based on flight-specific information. The flight-specific navigation assistance data includes flight-specific ranking data for the plurality of geographic zones that can be used by the UAV or a server to determine the flight route.

Abstract: A method of auto-calibrating light sensor data of a mobile device includes, obtaining, by the mobile device, one or more reference parameters representative of light sensor data collected by a reference device. The method also includes collecting, by the mobile device, light sensor data from a light sensor included in the mobile device, itself. One or more sample parameters of the light sensor data obtained from the light sensor included in the mobile device are then calculated. A calibration model is then determined for auto-calibrating the light sensor data of the light sensor included in the mobile device based on the one or more reference parameters and the one or more sample parameters.

Abstract: According to various embodiments, there is provided a method for controlling a vehicle, the method including detecting a triggering event. The method further includes, in response to detecting the triggering event, determining updated dimensions of the vehicle. The method further includes adjusting operation of the vehicle based on the updated dimensions.

Abstract: Methods, systems, computer-readable media, and apparatuses for determining a flight route for a flight of an unmanned aerial vehicle (UAV) are presented. The flight-specific route for the UAV is determined dynamically during the flight or in advance before the flight, using navigation assistance data that includes flight-specific navigation assistance data for a plurality of geographic zones determined based on flight-specific information. The flight-specific navigation assistance data includes flight-specific ranking data for the plurality of geographic zones that can be used by the UAV or a server to determine the flight route.

Abstract: According to various embodiments, there is provided a method for controlling a vehicle, the method including detecting a triggering event. The method further includes, in response to detecting the triggering event, determining updated dimensions of the vehicle. The method further includes adjusting operation of the vehicle based on the updated dimensions.

Abstract: Methods and systems for utilizing priority based geofences are disclosed. A mobile device receives, from another device over a wireless network, at least one geofence, each of the at least one geofence having an assigned priority level indicating an importance of the at least one geofence, wherein the assigned priority level is one of a plurality of priority levels and is received from the other device over the wireless network, determines, based on the priority level of the at least one geofence, a geofence breach detection method and an evaluation rate, and monitors a position of the mobile device relative to the at least one geofence at the evaluation rate using the geofence breach detection method.

Abstract: Methods and systems for utilizing priority based geofences are disclosed. A mobile device receives, from another device over a wireless network, at least one geofence, each of the at least one geofence having an assigned priority level indicating an importance of the at least one geofence, wherein the assigned priority level is one of a plurality of priority levels and is received from the other device over the wireless network, determines, based on the priority level of the at least one geofence, a geofence breach detection method and an evaluation rate, and monitors a position of the mobile device relative to the at least one geofence at the evaluation rate using the geofence breach detection method.

Abstract: Methods, systems, computer-readable media, and apparatuses for determining indoor/outdoor state of a mobile device are presented. In some embodiments, a sensor reading is obtained from a sensor accessible by the mobile device. Contemporaneous information related to a local condition associated with an area where the mobile device is located is obtained. At least the sensor reading and the information related to a local condition are provided as input to an indoor/outdoor detection model selected from a plurality of trained models. Based on the model, the mobile device is classified as indoors or outdoors.

Abstract: A method of auto-calibrating light sensor data of a mobile device includes, obtaining, by the mobile device, one or more reference parameters representative of light sensor data collected by a reference device. The method also includes collecting, by the mobile device, light sensor data from a light sensor included in the mobile device, itself. One or more sample parameters of the light sensor data obtained from the light sensor included in the mobile device are then calculated. A calibration model is then determined for auto-calibrating the light sensor data of the light sensor included in the mobile device based on the one or more reference parameters and the one or more sample parameters.

Abstract: Methods and systems enable selection of a theme for implementation on a computing device based on sensor data. The computing device can include a variety of sensors including sensors capable of sensing ambient temperature, light, and sound, as well as geographic position, for example. Data collected by a sensor is used to select a theme correlated to the sensed condition. Data from sensors can also be used to generate customized advertisements that can be displayed on the computing device.

Abstract: Methods and systems enable selection of a theme for implementation on a computing device based on sensor data. The computing device can include a variety of sensors including sensors capable of sensing ambient temperature, light, and sound, as well as geographic position, for example. Data collected by a sensor is used to select a theme correlated to the sensed condition. Data from sensors can also be used to generate customized advertisements that can be displayed on the computing device.

Abstract: Methods and apparatus for providing an intuitive user-interface on a mobile device keypad for controlling television and multimedia applications uses a keypad protocol as a standard interface between video application software and the mobile device keypad. The keypad protocol can provide a common set of interfaces and APIs to facilitate development of video applications that are compatible with a wide variety of keypads, including keypads that may be developed after applications are fielded. Video applications can inform the keypad protocol of keypad configurations to support video functions, including providing graphics for presenting intuitive function description graphics on display keypads. In an embodiment, the mobile device can be configured to control external multimedia players using a area wireless data link transceiver within the mobile device while presenting intuitive graphics on the keypad showing assigned multimedia player functions assigned to particular keys.

Abstract: A keypad protocol is provided as part of mobile device system software to serve as a standard interface between application software and keypads and other user-interfaces. The keypad protocol can provide a common set of interfaces and APIs to facilitate development of applications that are compatible with a wide variety of keypads, including keypads that may be developed after applications are fielded. Similarly the keypad protocol can provide a common set of data structures and interfaces for accepting key press event notifications from and providing configuration information to keypads made by a variety of manufacturers. The keypad protocol can inform applications of the keypads activated and connected to the mobile device and useable by the application. Applications can inform the keypad protocol of a keypad selected for use as well as configure how the selected keypad should interface with the application.

Abstract: Methods and computing devices provide the capability of revealing the value or function assigned to particular keys in a keypad or keyboard by an application running on a computing device. A touch or near touch of a key prompts the presentation or display of the value or function presently assigned to the touched or nearly touched key. The key function assignment may be presented in a portion of the display so as to not block other graphics and text in the display. The process for generating a display of the function or value assigned to a touched or nearly touched key may be performed by a keypad protocol receiving key configurations from the application.

Abstract: Methods and systems for configuring keypads are provided to enable configuring display keypads to display themes, vary display fonts or present other graphics. An application may provide instructions to a keypad protocol to change the theme of or the size of the letters and numbers on the keypad. Alternatively, a keypad protocol can enable users to configure keypad displays. In an application the keypad can be configured to display advertising. Keys configured for advertising can allow users to receive advertisement content on their computing devices.