Abstract: Methods, apparatuses, and systems for digital image analysis for device navigation in tissue are disclosed. The disclosed system uses real-time angiography and artificial intelligence to navigate an end effector of a surgical robot through a patient's vasculature to provide a surgical intervention. Digital imaging is performed that enables three-dimensional mapping of the patient's vasculature. Locations and movement of the end effector of the surgical robot are determined. The end effector is used to perform an intervention such as the removal of a blood clot or delivery of a drug for dissolving a blood clot.

Abstract: Provided is a process including: acquiring signal strength information that includes a plurality of signal strength measurements detected by a mobile computing device and that are each associated with a respective wireless signal measurement time; generating a wireless signal-based localization by localizing the mobile computing device based on the plurality of signal strength measurements and known locations of beacon devices; acquiring a plurality of mobility sensor measurements that are each associated with a respective mobility sensor measurement time; generating a mobility-based localization by localizing the mobile computing device based on the plurality of mobility sensor measurements; fusing the wireless signal-based localization and the mobility-based localization based on correspondence between the respective wireless signal measurement time for the signal strength measurements and the respective mobility sensor measurement time for the mobility sensor measurement to generate a fused mobile computin

Abstract: Methods, apparatuses, and systems for digital image analysis for device navigation in tissue are disclosed. The disclosed system uses real-time angiography and artificial intelligence to navigate an end effector of a surgical robot through a patient's vasculature to provide a surgical intervention. Digital imaging is performed that enables three-dimensional mapping of the patient's vasculature. Locations and movement of the end effector of the surgical robot are determined. The end effector is used to perform an intervention such as the removal of a blood clot or delivery of a drug for dissolving a blood clot.

Abstract: Described herein are techniques for generating a radiological report. In some cases, some or all of the radiological report may be generated during a medical imaging to which the report relates, such that the report is generated contemporaneously with or in real time during the imaging. In some embodiments described herein, some or all of the radiological report may be generated automatically, without intervention from an imaging technician or from a radiologist. Such an automatic generation of radiological report content may be performed in some embodiments through comparison of information regarding a medical imaging of a patient to information regarding one or more prior medical imaging's of the patient or other patients. In response to detecting a match between information regarding a medical imaging of a patient and information regarding a prior medical imaging, information relating to the prior medical imaging may be used to generate the radiological report.

Abstract: Methods, apparatuses, and systems for digital image analysis for device navigation in tissue are disclosed. The disclosed system uses real-time angiography and artificial intelligence to navigate an end effector of a surgical robot through a patient's vasculature to provide a surgical intervention. Digital imaging is performed that enables three-dimensional mapping of the patient's vasculature. Locations and movement of the end effector of the surgical robot are determined. The end effector is used to perform an intervention such as the removal of a blood clot or delivery of a drug for dissolving a blood clot.

Abstract: Methods, apparatuses, and systems for digital image analysis for device navigation in tissue are disclosed. The disclosed system uses real-time angiography and artificial intelligence to navigate an end effector of a surgical robot through a patient's vasculature to provide a surgical intervention. Digital imaging is performed that enables three-dimensional mapping of the patient's vasculature. Locations and movement of the end effector of the surgical robot are determined. The end effector is used to perform an intervention such as the removal of a blood clot or delivery of a drug for dissolving a blood clot.

Abstract: Disclosed are systems and methods that provide a framework for performing advanced image stabilization. The disclosed framework can operate to capture imagery used and/or relied upon for the preoperative (pre-op), operative and/or postoperative (post-op) stages of a medical procedure. The framework can function by collecting and monitoring sensor data related to a device of a user (e.g., a patient). The sensor data can be analyzed, whereby the framework can determine the most opportune time to capture an image(s)—for example, a computed tomography (CT) scan or magnetic resonance imaging (MRI) scan, and the like. Accordingly, the framework can leverage the determined capture opportunity to perform the image capture and storage of the image data and metadata, as well as perform a confidence score computation that enables validation or verification of the image's authenticity and quality.

Abstract: Provided is a method including: recording, by a computer system, a video of a macro-area of a physical environment to a micro-area of the physical environment; mapping, by the computer system, a plurality of feature points in the micro-area of the environment; positioning, by the computer system and in response to a user input, an augmented reality model at a location in the physical environment in the mapped micro-area; and storing, by the computer system, the video, the mapped micro-area, and the location in association with the augmented reality model in a database.

Abstract: Provided is a process including: obtaining signal strength information associated with a mobile computing device, where the signal strength information includes, for a time, a set of signal strength measurements and each signal strength measurement is associated with a wireless radio frequency signal between a respective access point and the mobile computing device; determining that the set of signal strength measurements satisfies a similarity condition with one or more sets of fingerprint signal strength measurements in an environment fingerprint model, where each set is associated with a fingerprint location and each respective access point is associated with a access point location; calculating, with the computer system, a path-loss exponent using the one or more sets of fingerprint signal strength measurements that satisfy the similarity condition; and determining, using the path-loss exponent in a path-loss localization algorithm, a location of the mobile computing device that satisfies a location condi

Abstract: Provided is a process including: obtaining a plurality of mobile computing device localizations for one or more mobile computing devices, wherein a mobile computing device localization of the plurality of mobile computing device localizations is determined based on at least a wireless signal-based localization that is generated by localizing, using a wireless signal-based localization algorithm, a mobile computing device of the one or more mobile computing devices based on a plurality of signal strength measurements, respective wireless signal measurement times, and known locations of beacon devices that transmit wireless radio frequency signals from which the plurality of signal strength measurements are obtained; determining, using a machine learning algorithm, an environment fingerprint model for a monitored environment based on the plurality of mobile computing device localizations associated with the one or more mobile computing devices and associated with the monitored environment.

Abstract: Provided is a process including: acquiring signal strength information that includes a plurality of signal strength measurements detected by a mobile computing device and that are each associated with a respective wireless signal measurement time; generating a wireless signal-based localization by localizing the mobile computing device based on the plurality of signal strength measurements and known locations of beacon devices; acquiring a plurality of mobility sensor measurements that are each associated with a respective mobility sensor measurement time; generating a mobility-based localization by localizing the mobile computing device based on the plurality of mobility sensor measurements; fusing the wireless signal-based localization and the mobility-based localization based on correspondence between the respective wireless signal measurement time for the signal strength measurements and the respective mobility sensor measurement time for the mobility sensor measurement to generate a fused mobile computin

Abstract: An acoustic biometric imaging system comprising: a transparent device member having a first face to be touched by a finger surface of a user, and a second face opposite the first face, the transparent device member having a first acoustic impedance; a first ultrasonic transducer acoustically coupled to the second face of the transparent device member in a first transducer region for receiving acoustic signals conducted by the transparent device member from a finger touch region laterally spaced apart from the first transducer region, the first ultrasonic transducer having a second acoustic impedance; and an opaque masking layer arranged between the transparent device member and the first ultrasonic transducer in the first transducer region, the opaque masking layer having a third acoustic impedance between the first acoustic impedance and the second acoustic impedance.

Abstract: A method for manufacturing a fingerprint sensor device. The method comprises providing a fingerprint sensor chip, arranging the fingerprint sensor chip on a carrier, depositing a cover layer on the fingerprint sensor chip, the cover layer comprising a polarizable material; moving a top electrode into contact with a top surface of the cover layer; and applying a voltage between the top electrode and a bottom electrode located below the cover layer and comprised in a material stack between the bottom of the carrier and the cover layer, creating an electric field in the cover layer, thereby poling the cover layer such that a dielectric constant of the cover layer in a direction perpendicular to the sensing array is higher than a dielectric constant in a direction parallel to the sensing array, thereby forming a cover layer having an anisotropic dielectric constant.

Abstract: A method for manufacturing a fingerprint sensor device. The method comprises providing a fingerprint sensor chip, arranging the fingerprint sensor chip on a carrier, depositing a cover layer on the fingerprint sensor chip, the cover layer comprising a polarizable material; moving a top electrode into contact with a top surface of the cover layer; and applying a voltage between the top electrode and a bottom electrode located below the cover layer and comprised in a material stack between the bottom of the carrier and the cover layer, creating an electric field in the cover layer, thereby poling the cover layer such that a dielectric constant of the cover layer in a direction perpendicular to the sensing array is higher than a dielectric constant in a direction parallel to the sensing array, thereby forming a cover layer having an anisotropic dielectric constant.

Abstract: The present invention provides a method and apparatus for managing the presentation and regulation of E-Commerce, content and service providers access in an interactive television environment comprising interactions between a server, a client, and a service provider. Components are provided for managing and completing a purchase or delivery of an item offered by a service provider. A purchase transaction uses client information comprising partial client information from the client and a list of purchased items. Upon receiving partial information from the client, the server retrieves corresponding additional related information within its database and transmits this retrieved data from the server, along with the list of purchased items to complete the transaction. Business Agents are provided for logging the transaction, creating an electronic receipt, logging patches, logging error events, and viewer logging.

Abstract: The present invention provides a method and apparatus for managing the presentation and regulation of E-Commerce, content and service providers access in an interactive television environment comprising interactions between a server, a client, and a service provider. Components are provided for managing and completing a purchase or delivery of an item offered by a service provider. A purchase transaction uses client information comprising partial client information from the client and a list of purchased items. Upon receiving partial information from the client, the server retrieves corresponding additional related information within its database and transmits this retrieved data from the server, along with the list of purchased items to complete the transaction. Business Agents are provided for logging the transaction, creating an electronic receipt, logging patches, logging error events, and viewer logging.

Abstract: A new Illuminated Fire Hose Rescue Nozzle for offering a portable, optional light for a fire hose nozzle that illuminates a target or a pathway. The inventive device includes a light, a mounting means, and a power means. In use, the device is attached to a nozzle 4 of a fire hose 2 and when the on-off switch 14 is used to energize light 12, a pathway is illuminated in the direction the fire hose 2 is pointed.