Abstract: Implementations generally relate to setting up and updating media devices in a media system. In some implementations, a method includes receiving a signal at a television, wherein the signal is associated with at least one other media device. The method further includes determining a make and model of the at least one other media device based on the signal. The method further includes determining one or more settings of the at least one other media device based on the make and model of the at least one other media device. The method further includes configuring the one or more settings of the at least one other media device.

Abstract: A head mounted display (HMD) device that includes a plurality of sensors, an actuator, a plurality of protective mechanisms, and a processor configured to identify a situational state of a user of the HMD device within a proximity of the user, based on sensor input received from the plurality of sensors. A risk-level of a potential injury to the user from a component of the HMD device is determined based on the identified situational state and the sensor input. A protective mechanism is selected from the plurality of protective mechanisms based on the identified situational state and the determined risk-level. The actuator is controlled to deploy the selected protective mechanism to mitigate injury to the user from the component of the HMD device, based on the identified situational state and the determined risk-level.

Abstract: A camera based depth mapping system. Depth information is coded with colors to make a laser-generated 3D depth map easier to interpret. In the event that the laser illumination is not sufficient, the depth information can have a low signal to noise ratio, i.e., the depth map can be noisy. Color noise reduction techniques are used to alleviate this problem.

Abstract: A micro mirror assembly widens the field of view (FOV) of a 3D depth map sensor, alleviating the limitation of limited laser illumination power and limitations on the resolution of the available imaging device.

Abstract: Multiple camera systems which use laser illumination for ranging benefit from a heartbeat to synchronize the timing of the individual lasers to eliminate collisions of multiple simultaneous laser emissions. An optical micromesh system provides for the dynamic entry and egress of mobile and stationary nodes. The optical communication between nodes may be controlled using time domain multiplexing (TDM) to avoid cross talk and communication collision due to overlapping laser illumination. By using an optical, laser based micromesh network, laser ranging can be used to dynamically map node location.

Abstract: A head-mounted device (HMD) that includes at least one speaker, at least one audio capturing device and circuitry is provided. The circuitry receives, via the at least one audio capturing device, a user input that corresponds to an audio input. The circuitry further determines a first location of a source of the received audio input, based on the received audio input. The circuitry further determines that the received audio input is enunciated from a wearer of the HMD in a worn state of the HMD, based on the determined first location of the source of the received audio input. The circuitry further controls at least a function of the HMD, based on the determination that the received audio input is enunciated from the wearer.

Abstract: A code is generated by a primary cloud server and sent to a device to be controlled (controlee). The code is displayed and a user speaks the code to a controller device, such as a voice assistant (VA). The controller sends the spoken code via a third party server to the primary server and if the primary server identifies the code as being correct, a first step is complete. The controlee then generates a second code, sends it to the primary server and also displays it for a user to speak it to the controller, which sends the spoken second code to the primary server via the third party server. If the primary server identifies the second code as being correct, pairing is authorized between the controller and controlee. The first and second steps should be completed within a timeout period to be valid.

Abstract: To reduce the random noise in a depth map that is rendered using colors to convey the various depths, pattern recognition may be used to selectively apply noise reduction or to modulate the strength of the noise reduction. In this way, the potential adverse effect on the detail/sharpness of the image can be ameliorated. For example, in an image of a person, the skin does not have any sharp edges so noise reduction can be applied to such an image with little adverse consequence, whereas noise reduction applied to the image of a person's eye can cause loss of the detail of the iris, eyelashes, etc. Using pattern recognition on objects in the image, the appropriate level of noise reduction can be applied across an image while minimizing blurring/loss of detail.

Abstract: Each of plural devices includes a laser emitter and a camera for detecting reflections of laser light emitted by the device, so that plural of the devices can generate their own depth maps showing images within the field of view of their cameras. The resulting 3D depth maps from multiple cameras at potentially arbitrary locations can be aggregated to create a more accurate 3D depth map of the area covered by all the individual cameras. Each device/camera may be assigned a unique identification such as a unique number and a mechanism to identify, either electronically or visually, devices in its field of view. Using this information, the relative locations of the cameras can be calculated for purposes of aggregating the multiple depth maps.

Abstract: A code is generated by a primary cloud server and sent to a device to be controlled (controlee). The code is displayed and a user speaks the code to a controller device, such as a voice assistant (VA). The controller sends the spoken code via a third party server to the primary server and if the primary server identifies the code as being correct, a first step is complete. The controlee then generates a second code, sends it to the primary server and also displays it for a user to speak it to the controller, which sends the spoken second code to the primary server via the third party server. If the primary server identifies the second code as being correct, pairing is authorized between the controller and controlee. The first and second steps should be completed within a timeout period to be valid.

Abstract: Each of plural devices includes a laser emitter and a camera for detecting reflections of laser light emitted by the device, so that plural of the devices can generate their own depth maps showing images within the field of view of their cameras. The resolution of each depth map may be improved by accessing a data store of prior images of objects and combining the prior images using super-resolution with current images of the depth maps.

Abstract: Machine learning is applied to both 2D images from an infrared imager imaging laser reflections from an object and to the 3D depth map of the object that is generated using the 2D images and time of flight (TOF) information. In this way, the 3D depth map accuracy can be improved without increasing laser power or using high resolution imagers.

Abstract: A micro mirror assembly widens the field of view (FOV) of a 3D depth map sensor, alleviating the limitation of limited laser illumination power and limitations on the resolution of the available imaging device.

Abstract: To reduce the random noise in a depth map that is rendered using colors to convey the various depths, pattern recognition may be used to selectively apply noise reduction or to modulate the strength of the noise reduction. In this way, the potential adverse effect on the detail/sharpness of the image can be ameliorated. For example, in an image of a person, the skin does not have any sharp edges so noise reduction can be applied to such an image with little adverse consequence, whereas noise reduction applied to the image of a person's eye can cause loss of the detail of the iris, eyelashes, etc. Using pattern recognition on objects in the image, the appropriate level of noise reduction can be applied across an image while minimizing blurring/loss of detail.

Abstract: Each of plural devices includes a laser emitter and a camera for detecting reflections of laser light emitted by the device, so that plural of the devices can generate their own depth maps showing images within the field of view of their cameras. The resulting 3D depth maps from multiple cameras at potentially arbitrary locations can be aggregated to create a more accurate 3D depth map of the area covered by all the individual cameras. Each device/camera may be assigned a unique identification such as a unique number and a mechanism to identify, either electronically or visually, devices in its field of view. Using this information, the relative locations of the cameras can be calculated for purposes of aggregating the multiple depth maps.

Abstract: Multiple camera systems which use laser illumination for ranging benefit from a heartbeat to synchronize the timing of the individual lasers to eliminate collisions of multiple simultaneous laser emissions. An optical micromesh system provides for the dynamic entry and egress of mobile and stationary nodes. The optical communication between nodes may be controlled using time domain multiplexing (TDM) to avoid cross talk and communication collision due to overlapping laser illumination. By using an optical, laser based micromesh network, laser ranging can be used to dynamically map node location.

Abstract: A camera based depth mapping system. Depth information is coded with colors to make a laser-generated 3D depth map easier to interpret. In the event that the laser illumination is not sufficient, the depth information can have a low signal to noise ratio, i.e., the depth map can be noisy. Color noise reduction techniques are used to alleviate this problem.

Abstract: A method for invoking a software application comprising: executing a first application on a user device; detecting a trigger event on the user device, the trigger event is non-specific and external to the first application and a second application; invoking the second application in response to the trigger event; sending metadata from the first application to the second application; and performing an action in the second application based at least partially on the metadata received from the first application, wherein, the first application and the second application are not operating system processes, and the second application is separate and independent from the first application.

Abstract: A method of automatically replying to incoming phone calls is provided. The method includes enabling automatic reply on a cellular phone of a user; generating a voice message for the automatic reply; associating the voice message with at least one phone number; detecting the at least one number when an incoming call from the at least one phone number is received at the cellular phone; and playing the voice message associated with the at least one number to a person making the incoming call from the at least one phone number without requiring manual input from the user of the cellular phone when the incoming call from the at least one phone number is being received. A method of automatically replying to incoming text messages is also provided.

Abstract: A remote control (RC) has a touch pad and user touches on the pad are correlated to pad positions. The positions are sent to a remote display device and mapped to corresponding locations on the display of the display device as though the user were touching the display of the display device, not the touch pad of the RC.