Abstract: The present disclosure provides systems and methods for storing, reading, and writing data using particle-based acoustic wave driven shift registers. The shift registers may physically shift particles along rows and/or columns of wells through the interactions of two parallel surfaces. A transducer may generate an acoustic wave to displace one or more of the two parallel surfaces. The particles may be transferred to and/or otherwise constrained by a buffer surface during at least a portion of the acoustic wave, such that the particles may be shifted during one or more cycles of the acoustic wave. In various embodiments, the amplitude of the acoustic wave may correspond to the spacing distance between each of the wells. The wells may be physical and/or potential wells.

Abstract: Techniques for ability enhancement are described. In some embodiments, devices and systems located in a transportation network share threat information with one another, in order to enhance a user's ability to operate or function in a transportation-related context. In one embodiment, a process in a vehicle receives threat information from a remote device, the threat information based on information about objects or conditions proximate to the remote device. The process then determines that the threat information is relevant to the safe operation of the vehicle. Then, the process modifies operation of the vehicle based on the threat information, such as by presenting a message to the operator of the vehicle and/or controlling the vehicle itself.

Abstract: Systems and methods are described relating to detecting an indication of a person within a specified proximity to at least one mobile device; and presenting an indication of location of the at least one mobile device at least partially based on the indication of the person within the specified proximity. Additionally, systems and methods are described relating to means for detecting an indication of a person within a specified proximity to at least one mobile device; and means for presenting an indication of location of the at least one mobile device at least partially based on the indication of the person within the specified proximity.

Abstract: The present disclosure provides systems and methods associated with determining velocity and/or acceleration information using ultrasound. A system may include one or more ultrasonic transmitters and/or receivers. An ultrasonic transmitter may be configured to transmit ultrasound into a region bounded by one or more surfaces. The ultrasonic receiver may detect a Doppler shift of reflected ultrasound to determine an acceleration and/or velocity associated with an object. The velocity and/or acceleration information may be utilized to modify the state of a gaming system, entertainment system, infotainment system, and/or other device. The velocity and/or acceleration date may be used in combination with a mapping or positioning system that generates positional data associated with the objects.

Abstract: A hands-free intercom may include a user-tracking sensor, a directional microphone, a directional sound emitter, and a communication interface. The user-tracking sensor may determine a location of a user so the directional microphone can measure vocal emissions by the user and the directional sound emitter can deliver audio to the user. The hands-free intercom may include a directional camera to capture video of the user and/or a directional video projector to deliver video to the user. The captured video may be provided to a remote entity and/or the delivered video may be received from the remote entity. The captured video may be used to identify vocal commands, gestures, facial expressions, and/or eye movements from the user. The projected video may be used to provide status information to the user.

Abstract: Systems and methods are described relating to accepting a query from a radio-frequency identification object associated with at least one mobile device; and presenting an indication of location of the at least one mobile device at least partially based on the query response from the radio-frequency identification object associated with the at least one mobile device. Additionally, systems and methods are described relating to means for accepting a query from a radio-frequency identification object associated with at least one mobile device; and means for presenting an indication of location of the at least one mobile device at least partially based on the query response from the radio-frequency identification object associated with the at least one mobile device.

Abstract: A hands-free intercom may include a user-tracking sensor, a directional microphone, a directional sound emitter, and a communication interface. The user-tracking sensor may determine a location of a user so the directional microphone can measure vocal emissions by the user and the directional sound emitter can deliver audio to the user. The hands-free intercom may determine whether the user is communicatively coupled via a mobile device to a remote entity. The hands-free intercom may be configured to receive a handoff of the communicative coupling, for example, by acting as a peripheral of the mobile device, by requesting the handoff, and/or the like. The hands-free intercom may be configured to deliver communications from the user to an appliance and vice versa. The hands-free intercom may manage access rights of the various entities to prevent unauthorized communications.

Abstract: Techniques for ability enhancement are described. In some embodiments, devices and systems located in a transportation network share threat information with one another, in order to enhance a user's ability to operate or function in a transportation-related context. In one embodiment, a process in a vehicle receives threat information from a remote device, the threat information based on information about objects or conditions proximate to the remote device. The process then determines that the threat information is relevant to the safe operation of the vehicle. Then, the process modifies operation of the vehicle based on the threat information, such as by presenting a message to the operator of the vehicle and/or controlling the vehicle itself.

Abstract: Systems and methods are described relating to accepting a query from a radio-frequency identification object associated with at least one mobile device; and presenting an indication of location of the at least one mobile device at least partially based on the query response from the radio-frequency identification object associated with the at least one mobile device. Additionally, systems and methods are described relating to means for accepting a query from a radio-frequency identification object associated with at least one mobile device; and means for presenting an indication of location of the at least one mobile device at least partially based on the query response from the radio-frequency identification object associated with the at least one mobile device.

Abstract: Systems and methods are described relating to determining a specified time period of non-movement in a mobile device and presenting an indication of location of the mobile device at least partially based on the specified time period of non-movement. Additionally, systems and methods are described relating to means for determining a specified time period of non-movement in a mobile device and means for presenting an indication of location of the mobile device at least partially based on the specified time period of non-movement.

Abstract: Systems, methods, computer-readable storage mediums including computer-readable instructions and/or circuitry for control of transmission to a target device with a cloud-based architecture may implement operations including, but not limited to: receiving localized context information associated with the at least one target device; determining, at least in part via a cloud-based architecture, at least one prospective message transmission practicability index according to a comparison of localized context information and the at least one historical transmission length; and authorizing, at least in part via a cloud-based architecture, at least one transmission to a target device in response to a determination of a prospective message transmission practicability index.

Abstract: A method embodiment includes receiving data indicative of a person accessing at least one of a first network-available electronic content or a second network-available electronic content. Also, receiving data indicative of an involvement with respect to possible matters of interest between the person and a third-party. The involvement being independent of the person activating a link to a site owned by the third-party that is included in the first network-available electronic content or in the second network available electronic content. Further, assessing a behavioral influence by the first network-available electronic content and/or the second network-available electronic content on the indicated involvement with respect to the possible matters of interest between the person and a third-party.

Abstract: The present disclosure provides systems and methods associated with determining position and/or movement information using ultrasound. A system may include one or more ultrasonic transmitters and/or receivers. An ultrasonic transmitter may be configured to transmit ultrasound into a region bounded by one or more surfaces. The ultrasonic receiver may receive direct ultrasonic reflections and/or rebounded ultrasonic reflections from one or more objects within the region. A mapping or positioning system may generate positional data associated with one or more of the object(s) based on the direct ultrasonic reflection(s) and/or the rebounded ultrasonic reflection(s). The mapping or positioning system may generate enhanced positional data by combining the direct positional data and the rebounded positional data.

Abstract: A hands-free intercom may include a user-tracking sensor, a directional microphone, a directional sound emitter, and a communication interface. The user-tracking sensor may determine a location of a user so the directional microphone can measure vocal emissions by the user and the directional sound emitter can deliver audio to the user. The directional sound emitter may emit ultrasonic waves configured to frequency convert to produce the audio. The communication interface may be configured to identify an entity of interest with which the user wishes to interact based on gestures and/or vocal emissions by the user and may automatically communicatively couple the user to the entity of interest. The hands-free intercom may determine whether remote entities requesting to communicatively couple with the user should be allowed to couple. The hands-free intercom may detect eavesdroppers and warn the user of the detected eavesdroppers.

Abstract: Methods and systems for determining a physiological parameter of a subject through interrogation of an eye of the subject with an optical signal are described. Interrogation is performed unobtrusively. The physiological parameter is determined from a signal sensed from the eye of a subject according to a schedule, under the control of a scheduling controller.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to enhance a user's ability to operate or function in a transportation-related context as a pedestrian or a vehicle operator. In one embodiment, the AEFS is configured perform vehicular threat detection based at least in part on analyzing audio signals. An example AEFS receives data that represents an audio signal emitted by a vehicle. The AEFS analyzes the audio signal to determine vehicular threat information, such as that the vehicle may collide with the user. The AEFS then informs the user of the determined vehicular threat information, such as by transmitting a warning to a wearable device configured to present the warning to the user.

Abstract: A hands-free intercom may include a user-tracking sensor, a directional microphone, a directional sound emitter, and a communication interface. The user-tracking sensor may determine a location of a user so the directional microphone can measure vocal emissions by the user and the directional sound emitter can deliver audio to the user. The directional sound emitter may emit ultrasonic waves configured to frequency convert to produce the audio. The communication interface may be configured to identify an entity of interest with which the user wishes to interact based on gestures and/or vocal emissions by the user and may automatically communicatively couple the user to the entity of interest. The hands-free intercom may determine whether remote entities requesting to communicatively couple with the user should be allowed to couple. The hands-free intercom may detect eavesdroppers and warn the user of the detected eavesdroppers.

Abstract: Systems and methods are described relating to accepting an indication of an inertial impact associated with at least one mobile device; and presenting an indication of location of the at least one mobile device at least partially based on accepting the indication of the inertial impact associated with the at least one mobile device. Additionally, systems and methods are described relating to means for accepting an indication of an inertial impact associated with at least one mobile device; and means for presenting an indication of location of the at least one mobile device at least partially based on accepting the indication of the inertial impact associated with the at least one mobile device.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to enhance a user's ability to operate or function in a transportation-related context as a pedestrian or a vehicle operator. In one embodiment, the AEFS is configured perform vehicular threat detection based at least in part on analyzing image data. An example AEFS receives data that represents an image of a vehicle. The AEFS analyzes the received data to determine vehicular threat information, such as that the vehicle may collide with the user. The AEFS then informs the user of the determined vehicular threat information, such as by transmitting a warning to a wearable device configured to present the warning to the user.

Abstract: An electrical power generation system includes a first fuel cell having a first responsiveness, a second fuel cell having a second responsiveness different from the first responsiveness, and a controller coupled to the first fuel cell and the second fuel cell. The controller is configured to engage the first fuel cell to satisfy at least a portion of a base load and selectively engage the second fuel cell to satisfy at least a portion of a load increase.