Abstract: In implementations of automated bounce flash, a camera device includes a camera to capture an image of a subject in an environment, and includes a flash device to illuminate the subject for image capture. A memory and processor of the camera device implements an image exposure application to select a surface in the environment from which to bounce light emitted from the flash device toward the subject during the image capture. The image exposure application is also implemented to control a direction of the light emitted from the flash device onto the selected surface during the image capture.

Abstract: An electronic device includes a first device housing and a second device housing. A hinge, which can be a multi-link hinge, couples the first device housing to the second device housing. The first device housing is pivotable about the hinge relative to the second device housing. A flexible display is coupled to the first device housing and the second device housing and spans the hinge. The flexible display is to deform when the first device housing pivots about the hinge relative to the second device housing.

Abstract: A method, a system, and computer program product for calculating an effective heat transfer coefficient of a device. The method includes measuring: an internal temperature of the device, a first temperature at a first location along a first resistive path of a parallel resistive network and a second temperature at a second location along a second resistive path of the parallel resistive network. An ambient temperature of the environment and an effective heat transfer coefficient of the device is then calculated based on the internal temperature, the first temperature, the second temperature, and resistive properties of the parallel resistive network. The ambient temperature and the effective heat transfer coefficient are provided to a thermal management component.

Abstract: The present invention provides a mobile wireless communication system, network, and method for managing the use of one or more peripherals with a mobile wireless communication device in connection with an upcoming event. The method includes associating one or more peripherals with one or more users, where the one or more peripherals have an extended capability for use with a mobile wireless communication device, and maintaining a list of the peripheral associations and the respective extended capabilities. Upcoming events and any need for corresponding event supporting capabilities are monitored. Any unmet need for event supporting capabilities is compared with the extended capability of peripherals associated with at least some of the one or more users that will be attending the upcoming event.

Abstract: An alert peripheral device that provides sensory notification to a user of the device includes: a power subsystem; a communication mechanism by which notification signals is received from a first user equipment (UE) that generates and transmits the notification signals in response to detection of specific events at the first UE; and a response notification mechanism that provides a sensory response of the peripheral device following receipt of a notification of a detected event (NDE) signal. The device further includes an embedded controller coupled to each of the other components and which includes firmware that when executed on the embedded controller configures the embedded controller to: establish a communication link between the communication mechanism and the first UE; and in response to detecting a receipt of the NDE signal from the first UE, trigger the response notification mechanism to exhibit the sensory response.

Abstract: A system and method of operation involves collecting acceleration and gyroscope data from a first sensor positioned in a wearable device on a user's wrist and a second sensor located in a mobile device. The mobile device determines a trajectory for the wearable device by filtering the first sensor data using the second sensor data, and determines a probability of the user holding an automobile steering wheel using the trajectory. The method may also include determining a probability of the user holding an automobile steering wheel of a specific automobile selected from an automobile list. The disclosed system includes the wearable device and the mobile device.

Abstract: The present application provides an electronic device having at least a three part housing foldable between multiple use positions. The three part housing includes a first housing part, a second housing part, and a third housing part, where each of the three housing parts has a front facing, a back facing, and two spaced apart sides respectively coupled between the front facing and back facing at opposite edges of the front and back facings. The second housing part is respectively movably coupled to a side of each the first housing part and the third housing part at a different one of the two spaced apart sides of the second housing part. The electronic device further includes a flexible display which extends along at least portions of the first housing part and the second housing part, and across the movably coupled sides, at which the first housing part is coupled to the second housing part.

Abstract: A wearable charging apparatus configured for charging of a wearable device while the wearable device is in an operative position, such as on the wrist of the user the wearable charging apparatus includes a front housing portion, a rear charging portion, a coupling member and a charge system. The wearable device is positionable between the front housing portion and the rear charging portion. The front portion has a battery and the rear charging portion has a wearable charge coil that is placed in operable position relative to the wearable device and configured to electrically communicate with a coil within the body of the wearable device and coupled to a wearable battery therewith, to, in turn, transfer power from the battery within the cavity to the wearable battery.

Abstract: The present application provides an electronic device having at least a three part housing foldable between multiple use positions. The three part housing includes a first housing part, a second housing part, and a third housing part, where each of the three housing parts has a front facing, a back facing, and two spaced apart sides respectively coupled between the front facing and back facing at opposite edges of the front and back facings. The second housing part is respectively movably coupled to a side of each the first housing part and the third housing part at a different one of the two spaced apart sides of the second housing part. The electronic device further includes a flexible display which extends along at least portions of the first housing part and the second housing part, and across the movably coupled sides, at which the first housing part is coupled to the second housing part.

Abstract: A display stack-up for an electronic device has: multiple layers that include a display layer and a second layer; and an outer seal. Each layer has first and second base surfaces and a thickness therebetween defining a height of a lateral surface at a periphery of the layer. The multiple layers are stacked along an axis perpendicular to their base surfaces and parallel to their lateral surfaces, and the outer seal is positioned along the lateral surface of at least some of the multiple layers. The outer seal is composed of a flexible material and is arranged to bind the second layer and at least one other layer of the multiple layers. The outer seal also contains a non-adhesive liquid between the second layer and the at least one other layer to allow relative sliding between at least two layers of the multiple layers.

Abstract: A display stack-up for an electronic device has: multiple layers that include a display layer and a second layer; and an outer seal. Each layer has first and second base surfaces and a thickness therebetween defining a height of a lateral surface at a periphery of the layer. The multiple layers are stacked along an axis perpendicular to their base surfaces and parallel to their lateral surfaces, and the outer seal is positioned along the lateral surface of at least some of the multiple layers. The outer seal is composed of a flexible material and is arranged to bind the second layer and at least one other layer of the multiple layers. The outer seal also contains a non-adhesive liquid between the second layer and the at least one other layer to allow relative sliding between at least two layers of the multiple layers.

Abstract: An electronic device includes a first device housing and a second device housing. A hinge, which can be a multi-link hinge, couples the first device housing to the second device housing. The first device housing is pivotable about the hinge relative to the second device housing. A flexible display is coupled to the first device housing and the second device housing and spans the hinge. The flexible display is to deform when the first device housing pivots about the hinge relative to the second device housing.

Abstract: A method, a system, and computer program product for calculating an effective heat transfer coefficient of a device. The method includes measuring: an internal temperature of the device, a first temperature at a first location along a first resistive path of a parallel resistive network and a second temperature at a second location along a second resistive path of the parallel resistive network. An ambient temperature of the environment and an effective heat transfer coefficient of the device is then calculated based on the internal temperature, the first temperature, the second temperature, and resistive properties of the parallel resistive network. The ambient temperature and the effective heat transfer coefficient are provided to a thermal management component.

Abstract: An electronic device has a housing, at least one actuator attached to the housing, and a deformable skin having air pores. The actuators are attached to both the housing and the deformable skin to impart a motion that causes a varying amount of separation. A thermal exchange cavity is defined by the housing and the deformable skin. A skin oscillation controller is contained with the housing and is electrically connected to the at least one actuators that vary a volume of the thermal exchange cavity by deforming the deformable skin, causing an exchange of ambient air through the air pores to convectively cool the housing.

Abstract: A heat management apparatus for an electronic device that includes a heat spreader. The heat spreader has a top surface and a bottom surface. A first portion is coupled to the electronic device. A second portion extends away from the electronic device. The heat spreader has a heat conductivity of at least approximately 100 Watts per meter Kelvin (W/mK). In some configurations the heat spreader may comprise a woven graphite material or a graphene material with a heat conductivity of at least approximately 1000 W/mK.

Abstract: A wearable charging apparatus configured for charging of a wearable device while the wearable device is in an operative position, such as on the wrist of the user the wearable charging apparatus includes a front housing portion, a rear charging portion, a coupling member and a charge system. The wearable device is positionable between the front housing portion and the rear charging portion. The front portion has a battery and the rear charging portion has a wearable charge coil that is placed in operable position relative to the wearable device and configured to electrically communicate with a coil within the body of the wearable device and coupled to a wearable battery therewith, to, in turn, transfer power from the battery within the cavity to the wearable battery.

Abstract: A battery can include an anode-electrolyte-cathode stack and a phase-change material. The anode-electrolyte-cathode stack can include at least one anode, at least one cathode, and an electrolyte which more directly interacts with each of the at least one anode and the at least one cathode, wherein the at least one anode electrically interacts with the at least one cathode via the electrolyte. The phase-change material can change phase to actuate an interference with an electrochemistry of the anode-electrolyte-cathode stack proximate an area where a localized temperature exceeds a predefined phase change threshold, the interference with the electrochemistry, which decreases current generation within the anode-electrolyte-cathode stack, can be adapted to occur prior to reaching a temperature that can create a failure within the anode-electrolyte-cathode stack.

Abstract: An alert peripheral device that provides sensory notification to a user of the device includes: a power subsystem; a communication mechanism by which notification signals is received from a first user equipment (UE) that generates and transmits the notification signals in response to detection of specific events at the first UE; and a response notification mechanism that provides a sensory response of the peripheral device following receipt of a notification of a detected event (NDE) signal. The device further includes an embedded controller coupled to each of the other components and which includes firmware that when executed on the embedded controller configures the embedded controller to: establish a communication link between the communication mechanism and the first UE; and in response to detecting a receipt of the NDE signal from the first UE, trigger the response notification mechanism to exhibit the sensory response.

Abstract: A system and method of operation involves collecting acceleration and gyroscope data from a first sensor positioned in a wearable device on a user's wrist and a second sensor located in a mobile device. The mobile device determines a trajectory for the wearable device by filtering the first sensor data using the second sensor data, and determines a probability of the user holding an automobile steering wheel using the trajectory. The method may also include determining a probability of the user holding an automobile steering wheel of a specific automobile selected from an automobile list. The disclosed system includes the wearable device and the mobile device.

Abstract: A heat management structure for a wearable electronic device includes a first thermally conductive layer, a second thermally conductive layer, and insulating layer. The first and second thermally conductive layers and the insulating layer are arranged in a stacked configuration along their surface areas with the insulating layer disposed between and in physical contact with the first and second thermally conductive layers. At least one edge of the second thermally conductive layer extends beyond an edge of at least one of the first thermally conductive layer or the insulating layer.