Abstract: An electronic device provides a capability of distinguishing between human tissue and a non-human object in proximity of a transmission source. In this manner, transmission power adjustments to the transmission source can be made selectively, depending on whether human tissue or a non-human object is detected in the proximity of the RF transmitter. Distinguishing between human tissue and other non-human-tissue objects in proximity of the transmission source provides for selective control of SAR adjustments. Accordingly, an electronic device can avoid certain communication performance reductions introduced by decreases in transmission power effected to comply with SAR standards by reducing transmission power when human tissue is detected in the proximity but not reducing transmission power when a non-human object (but no human tissue) is detected in the proximity.

Abstract: An electronic device disclosed herein includes mechanisms for modeling and dynamically controlling transmission power of an electronic device. The electronic device determines a back-off function defining at least one transmission power adjustment that is effective to adjust a predicted average energy emanating from an electronic device over the future time interval to satisfy a power condition. Power of the electronic device is adjusted according to the back-off function responsive to satisfaction of a proximity condition.

Abstract: Systems, methods, and computer media for determining the angle of a target object with respect to a device are provided herein. Target object information captured at approximately the same time by at least two cameras can be received. The target object information can comprise images or distances from the target object to the corresponding camera. An angle between the target object and the device can be determined based on the target object information. When the target object information includes images, the angle can be determined based on a correlation between two images. When the target object information includes distances from the target object to the corresponding camera, the angle can be calculated geometrically.

Abstract: Disclosed herein are representative embodiments of tools and techniques for using storyboards in controlling a camera for capturing images, photographs, or video. According to one exemplary technique, at least two storyboards are stored. In addition, at least one storyboard identifier from a camera application is received. Also, using the storyboard identifier, a storyboard of the stored at least two storyboards is retrieved. The retrieved storyboard includes a sequence of control frames for controlling a camera. Additionally, a sequence of image frames is captured at least by controlling a camera using the retrieved storyboard.

Abstract: A user interface for power management of a mobile communications device is described. In an implementation, power consumption used in performance of a plurality of tasks is monitored by a mobile communications device. A determination is made as to an amount of power that remains in a battery of the mobile communications device. A user interface is displayed on a display device of the mobile communications device that describes an amount of time each of the plurality of tasks may be performed based on the determined amount of power that remains in the battery.

Abstract: A cellular mobile station including a modem processor and memory. The memory includes instructions for the modem processor to perform layer 1 processor operations, layer 2 processor operations, and layer 3 processor operations. The modem processor executes the instructions to perform processor operations for the cellular mobile station to communication data as per a cellular communications protocol. In one example, the mobile station includes different levels of memory to provide different deterministic access times.

Abstract: Disclosed herein are representative embodiments of tools and techniques for using storyboards in controlling a camera for capturing images, photographs, or video. According to one exemplary technique, at least two storyboards are stored. In addition, at least one storyboard identifier from a camera application is received. Also, using the storyboard identifier, a storyboard of the stored at least two storyboards is retrieved. The retrieved storyboard includes a sequence of control frames for controlling a camera. Additionally, a sequence of image frames is captured at least by controlling a camera using the retrieved storyboard.

Abstract: Systems, methods, and computer media for separating audio sources in a multi-microphone system are provided. A plurality of audio sample groups can be received. Each audio sample group comprises at least two samples of audio information captured by different microphones during a sample group time interval. For each audio sample group, an estimated angle between an audio source and the multi-microphone system can be estimated based on a phase difference of the samples in the group. The estimated angle can be modeled as a combined statistical distribution that is a mixture of a target audio signal statistical distribution and a noise component statistical distribution. The combined statistical distribution can be analyzed to provide an accurate characterization of each sample group as either target audio signal or noise. The target audio signal can then be resynthesized from samples identified as part of the target audio signal.

Abstract: A wireless transmission system disclosed herein includes a transmitter-receiver pair. When a dielectric object approaches the transmitter-receiver pair, a signal strength of a transmitted carrier wave increases at the receiver. In response, transmission power of the transmitter can be dynamically reduced. When the dielectric object moves away from the transmitter-receiver pair, a signal strength of the carrier wave decreases at the receiver. In response, the transmission power of the transmitter can be dynamically increased.

Abstract: Radio Frequency (RF) attenuation function techniques are described for intelligently modifying the performance of radio devices to maintain specific absorption rate (SAR) compliance with regulatory requirements while minimally perturbing antennas/radio operations. A mobile computing device is configured to implement attenuation functions that reflect relationships established between transmission power and back-off amounts for different operational contexts. Rather than setting a fixed back-off for power reductions, an appropriate attenuation function that matches a current operational context of the device is used to make variable adjustments to RF power (e.g., “back-offs”). The mobile computing device may compute back-off values on demand using the functions or look-up pre-computed values from a table or other data structure.

Abstract: A wireless transmission system disclosed herein includes a radiating structure integrated into a computing device case that substantially encloses electronics of a computing device. The radiating structure includes an insulator that forms a boundary with the metal plate on the computing device case. A proximity sensor collects data from an exposure point located within the radiating structure.

Abstract: A user interface for power management of a mobile communications device is described. In an implementation, power consumption used in performance of a plurality of tasks is monitored by a mobile communications device. A determination is made as to an amount of power that remains in a battery of the mobile communications device. A user interface is displayed on a display device of the mobile communications device that describes an amount of time each of the plurality of tasks may be performed based on the determined amount of power that remains in the battery.

Abstract: A method and apparatus is provided for adjusting the gain imparted to a signal by an audio transducer such as a microphone and/or a speaker, which is employed by an electronic device having a multi-touch screen user input. The method begins when pressure applied to the multi-touch screen by a user is detected. The pressure is detected while the user is providing or receiving audible signals to or from, respectively, the audio transducer. Next, the user is identified based on a pre-established user profile that identifies the user based on a pressure profile that is obtained by the multi-touch screen. The pressure profile represents at least a contour of a portion the user's head such as the user's ear, cheek or the like. Once the user has been identified, pre-established user-selectable settings associated with the identified user are retrieved from memory.

Abstract: Radio Frequency (RF) power back-off optimization techniques are described for specific absorption rate (SAR) compliance. A mobile device may be configured to intelligently modify antennas and radio device transmission levels to maintain compliance with SAR limits while minimally perturbing radio operations. The mobile device may implement a SAR optimization scheme that accounts for user presence and signal conditions to maintain compliance. Rather than setting a fixed back-off, user presence detectors may be employed along with information on current signal conditions to determine potential for excessive SAR exposure and selectively apply variable adjustments to RF transmission power (e.g., “back-offs”), accordingly. The mobile device may also be configured to report SAR conditions and/or mitigation actions to a base station to enable the base station to manage a connection to services based at least in part upon knowledge of SAR actions taken by the mobile computing device.

Abstract: Systems, methods, and computer media for determining the angle of a target object with respect to a device are provided herein. Target object information captured at approximately the same time by at least two cameras can be received. The target object information can comprise images or distances from the target object to the corresponding camera. An angle between the target object and the device can be determined based on the target object information. When the target object information includes images, the angle can be determined based on a correlation between two images. When the target object information includes distances from the target object to the corresponding camera, the angle can be calculated geometrically.

Abstract: Modified compression/decompression and metadata in burst mode images reduce the storage space consumed by burst mode images. Metadata is added to image files (e.g., EXIF files) to establish links between images in a burst mode image series. A series of linked burst mode images can include delta images representing a temporal difference between the image data (e.g., pixel data) for two burst images captured at different time instances. Difference information can be compressed. A root image for a linked burst mode series can be identified and used as a reference for other burst images. Metadata can be added to image files to link burst images prior to compression, after compression, or at an intermediate stage of compression of image data. Difference information for delta image files can be derived prior to compression, after compression, or at an intermediate stage of compression of image data.

Abstract: Systems, methods, and computer media for separating audio sources in a multi-microphone system are provided. A plurality of audio sample groups can be received. Each audio sample group comprises at least two samples of audio information captured by different microphones during a sample group time interval. For each audio sample group, an estimated angle between an audio source and the multi-microphone system can be estimated based on a phase difference of the samples in the group. The estimated angle can be modeled as a combined statistical distribution that is a mixture of a target audio signal statistical distribution and a noise component statistical distribution. The combined statistical distribution can be analyzed to provide an accurate characterization of each sample group as either target audio signal or noise. The target audio signal can then be resynthesized from samples identified as part of the target audio signal.

Abstract: Disclosed herein are representative embodiments of tools and techniques for using storyboards in controlling a camera for capturing images, photographs, or video. According to one exemplary technique, at least two storyboards are stored. In addition, at least one storyboard identifier from a camera application is received. Also, using the storyboard identifier, a storyboard of the stored at least two storyboards is retrieved. The retrieved storyboard includes a sequence of control frames for controlling a camera. Additionally, a sequence of image frames is captured at least by controlling a camera using the retrieved storyboard.

Abstract: Data from storage devices is stored in a read cache, having a read cache size, and a write cache, having a write cache size. The read cache and the write cache are separate caches. Cache configuration of the read cache and the write cache are automatically and dynamically adjusted based, at least in part, upon cache performance parameters. Cache performance parameters include one or more of preference scores, frequency of read and write operations, read and write performance of a storage device, localization information, and contiguous read and write performance. Dynamic cache configuration includes one or more of adjusting read cache size and/or write cache size and adjusting read cache block size and/or write cache block size.

Abstract: Disclosed herein are exemplary embodiments for automatically capturing images in a mobile electronic device. One embodiment comprises sensing device motion and automatically triggering image capture when the device is stationary. Use of this approach reduces image blur and avoids the need for subsequent image alteration or compensation for camera motion. Images can simply be captured in-between motions by leveraging high-resolution sensors and computational assets available to the mobile device to accurately assess when to trigger the shutter. Images can then be saved in a memory within the device. Enhancements to the disclosed method of automatic image capture include pre-selecting a set of threshold values for image acceptance.