Abstract: A wearable device may include a head-mounted display (HMD) for rendering a three-dimensional (3D) virtual object which appears to be located in an ambient environment of a user of the display. The relative positions of the HMD and one or more eyes of the user may not be in desired positions to receive, or register, image information outputted by the HMD. For example, the HMD-to-eye alignment vary for different users and may change over time (e.g., as a given user moves around or as the HMD slips or otherwise becomes displaced). The wearable device may determine a relative position or alignment between the HMD and the user's eyes by determining whether features of the eye are at certain vertical positions relative to the HMD. Based on the relative positions, the wearable device may determine if it is properly fitted to the user, and provides feedback on the quality of the fit to the user, and may take actions to reduce or minimize effects of any misalignment.

Abstract: A method includes detecting, via a first one of a plurality of input devices, a primary input directed to a first candidate virtual spatial location of a computer-generated reality (CGR) environment. The first candidate virtual spatial location is an output of an extremity tracking function based on the primary input. The method includes detecting, via a second one of the plurality of input devices, a secondary input directed to a second candidate virtual spatial location of the CGR environment. The second candidate virtual spatial location is an output of an eye tracking function based on the secondary input. The method includes positioning a user-controlled spatial selector to a virtual spatial location of the CGR environment as a function of the first and second candidate virtual spatial locations.

Abstract: A system for processing data within a Trusted Execution Environment (TEE) of a processor is provided. The system may include: a trust manager unit for verifying identity of a partner and issuing a communication key to the partner upon said verification of identity; at least one interface for receiving encrypted data from the partner encrypted using the communication key; a secure database within the TEE for storing the encrypted data with a storage key and for preventing unauthorized access of the encrypted data within the TEE; and a recommendation engine for decrypting and analyzing the encrypted data to generate recommendations based on the decrypted data.

Abstract: Cellular connections can be used to provision non-cellular devices such as internet-of-things (IoT) devices. For example, IoT devices can comprise Bluetooth, Wi-Fi, and cellular capabilities. However, the cellular capability can be used to provision the IoT devices using non-internet protocol data delivery to prevent security vulnerabilities. Data can be transmitted to the IoT device using core elements without using an IP stack. Thus, IoT device configurations and the keys can be provisioned over-the-air without the use of internet protocol data.

Abstract: An augmented reality (AR) device can be configured to generate a virtual representation of a user's physical environment. The AR device can capture images of the user's physical environment to generate or identify a user's location. The AR device can project graphics at designated locations within the user's environment to guide the user to capture images of the user's physical environment. The AR device can provide visual, audible, or haptic guidance to direct the user of the AR device to explore the user's environment.

Abstract: Internet-of-things (TOT) devices can be identified based on specific behavioral patterns when their identification data is unknown. Previously identified IOT devices with similar behavioral patterns can be used as a baseline from which to compare data that is available about unknow IOT devices. For example, an IOT device can be pooled with a group of IOT devices based on the frequency with which they connect to a wireless network. Additionally, a confidence level of the unknown device being associated with the group of IOT devices can be generated based on such comparison data.

Abstract: A wearable device may include a head-mounted display (HMD) for rendering a three-dimensional (3D) virtual object which appears to be located in an ambient environment of a user of the display. The relative positions of the HMD and one or more eyes of the user may not be in desired positions to receive, or register, image information outputted by the HMD. For example, the HMD-to-eye alignment vary for different users and may change over time (e.g., as a given user moves around or as the HMD slips or otherwise becomes displaced). The wearable device may determine a relative position or alignment between the HMD and the user's eyes. Based on the relative positions, the wearable device may determine if it is properly fitted to the user, may provide feedback on the quality of the fit to the user, and may take actions to reduce or minimize effects of any misalignment.

Abstract: A system for processing data within a Trusted Execution Environment (TEE) of a processor is provided. The system may include: a trust manager unit for verifying identity of a partner and issuing a communication key to the partner upon said verification of identity; at least one interface for receiving encrypted data from the partner encrypted using the communication key; a secure database within the TEE for storing the encrypted data with a storage key and for preventing unauthorized access of the encrypted data within the TEE; and a recommendation engine for decrypting and analyzing the encrypted data to generate recommendations based on the decrypted data.

Abstract: A wearable device may include a head-mounted display (HMD) for rendering a three-dimensional (3D) virtual object which appears to be located in an ambient environment of a user of the display. The relative positions of the HMD and one or more eyes of the user may not be in desired positions to receive, or register, image information outputted by the HMD. For example, the HMD-to-eye alignment vary for different users and may change over time (e.g., as a given user moves around or as the HMD slips or otherwise becomes displaced). The wearable device may determine a relative position or alignment between the HMD and the user's eyes. Based on the relative positions, the wearable device may determine if it is properly fitted to the user, may provide feedback on the quality of the fit to the user, and may take actions to reduce or minimize effects of any misalignment.

Abstract: A multifunctional therapeutic workout enhancement brace has a joint-receiving sling, a pair of adjustable cuffs, and a tension-diverting band. The joint-receiving sling is a flexible piece of material that is molded to conform to the shape of the user's joint. The pair of adjustable cuffs are mounted along opposite edges of the joint-receiving sling. Thus, enabling the user to attach the adjustable cuffs to opposite sides of the user's joint. The tension-diverting band is a strip of material that is mounted in between the adjustable cuffs and the joint-receiving sling. Thus positioned, the tension-diverting band transfers forces that are directed toward the user's joint out of the joint-receiving sling and into the adjustable cuffs. Further, the joint-receiving sling, the pair of adjustable cuffs, and the tension-diverting band work in concert to reduce the torque applied to the user's joint during exercise.

Abstract: A more efficient internet-of-things (IoT) manufacturing process can be achieved using hash functions to authenticate and identify IoT devices. Device data comprising manufacturer name data, device name data, software version data, and/or hardware version data can be feed through a hash function to generate hashed data. Additionally, same and/or similar data can be hashed via a manufacturing process. The two outputs from both sets of data can then be matched to determine the authentication of a device. Based on the authenticity of the device being verified, the IoT device can undergo a certification process as a part of the manufacturing process. This manufacturing process comprising hashed data can eliminate current manufacturing processes and allow for a unique identifier to be associated with the IoT device.

Abstract: Techniques for generating a geological model include identifying a plurality of well data for each of a plurality of wells drilled into a reservoir basin from a terranean surface. The reservoir basin includes a plurality of landing zones formed under the terranean surface, each of the landing zone including a discrete geological layer. The techniques further include comparing the plurality of well data for each well with a reservoir basin database that associates the well data with one of the plurality of landing zones; correlating each of the plurality of wells with a particular landing zone of the plurality of landing zones based on the comparison; and generating a geological model of the reservoir basin based on the correlated wells.

Abstract: A computer implemented system for controlling access to data associated with an entity includes a data storage device having a protected memory region, and one or more processors, at least one of which is operable in the protected memory region. The one or more processors are configured for: storing a secret key associated with the entity in a portion of the protected memory region associated with the entity; upon receiving entity data, storing the entity data in the portion of the protected memory region associated with the entity; and upon receiving an access grant signal, generating a smart contract, the smart contract defining the entity data to be accessed and a recipient of the entity data to be accessed.

Abstract: A system for processing data within a Trusted Execution Environment (TEE) of a processor is provided. The system may include: a trust manager unit for verifying identity of a partner and issuing a communication key to the partner upon said verification of identity; at least one interface for receiving encrypted data from the partner encrypted using the communication key; a secure database within the TEE for storing the encrypted data with a storage key and for preventing unauthorized access of the encrypted data within the TEE; and a recommendation engine for decrypting and analyzing the encrypted data to generate recommendations based on the decrypted data.

Abstract: A wearable device may include a head-mounted display (HMD) for rendering a three-dimensional (3D) virtual object which appears to be located in an ambient environment of a user of the display. The relative positions of the HMD and one or more eyes of the user may not be in desired positions to receive, or register, image information outputted by the HMD. For example, the HMD-to-eye alignment vary for different users and may change over time (e.g., as a given user moves around or as the HMD slips or otherwise becomes displaced). The wearable device may determine a relative position or alignment between the HMD and the user's eyes. Based on the relative positions, the wearable device may determine if it is properly fitted to the user, may provide feedback on the quality of the fit to the user, and may take actions to reduce or minimize effects of any misalignment.

Abstract: A multifunctional therapeutic workout enhancement brace has a joint-receiving sling, a pair of adjustable cuffs, and a tension-diverting band. The joint-receiving sling is a flexible piece of material that is molded to conform to the shape of the user's joint. The pair of adjustable cuffs are mounted along opposite edges of the joint-receiving sling. Thus, enabling the user to attach the adjustable cuffs to opposite sides of the user's joint. The tension-diverting band is a strip of material that is mounted in between the adjustable cuffs and the joint-receiving sling. Thus positioned, the tension-diverting band transfers forces that are directed toward the user's joint out of the joint-receiving sling and into the adjustable cuffs. Further, the joint-receiving sling, the pair of adjustable cuffs, and the tension-diverting band work in concert to reduce the torque applied to the user's joint during exercise.