Abstract: Systems and methods, as described herein, may comprise and/or utilize data governance systems to enable end-to-end encrypted communications between an organization and third parties as well as between systems internal to the organization. The data governance systems may enforce compliance with an organization's data governance policies, as well as various laws, rules, and/or policies, for encrypted communications and/or other encrypted data payloads.

Abstract: Systems and methods, as described herein, may comprise and/or utilize data governance systems to enable end-to-end encrypted communications between an organization and third parties as well as between systems internal to the organization. The data governance systems may enforce compliance with an organization's data governance policies, as well as various laws, rules, and/or policies, for encrypted communications and/or other encrypted data payloads.

Abstract: Systems and methods, as described herein, may comprise and/or utilize data governance systems to enable end-to-end encrypted communications between an organization and third parties as well as between systems internal to the organization. The data governance systems may enforce compliance with an organization's data governance policies, as well as various laws, rules, and/or policies, for encrypted communications and/or other encrypted data payloads.

Abstract: A mixing assembly for use in a semi-continuous process for producing liquid personal care compositions, such as shampoos, includes a main feed tube carrying a base of the composition to be produced, a plurality of injection tubes in selective fluid communication with the main feed tube, and an orifice provided in a wall at an end of the main feed tube downstream of the plurality of injection tubes. The wall in which the orifice is provided includes a curved (e.g., semispherical) entry surface on an upstream or inlet side of an orifice, and a curved (e.g., semi-elliptical) exit surface on a downstream or outlet side of the orifice. The orifice may have a rectangular or elliptical shape. By maintaining symmetry of the injection tubes with respect to the orifice, and leveraging delay between introduction of dosed modules and increased viscosity, effective mixing may be achieved with minimal energy.

Abstract: An apparatus for determining the location of a radio-opaque marker embedded in an excised specimen includes a radio-opaque marker including an energy beacon that can be embedded in the specimen, an energy beacon controller, at least three detectors, a signal processing component, and a display device. An associated method is disclosed. A method for evaluating a radiographically labeled excised specimen involves determining the location of a radio-opaque marker embedded in the excised specimen, anatomically sectioning the excised specimen, macro-optically segmenting the sectioned specimen into an adipose tissue component, a fibrous tissue component, and an epithelial tissue component, and microscopically examining at least one of the tissue components. An associated apparatus is disclosed.

Abstract: An embodiment of the present invention may include an apparatus that captures 3D images having a lens barrel. The lens barrel may include a lens disposed at the first end of the lens barrel, an image capture element at the second end of the lens barrel, and a pair of refracting lenses positioned along the optical axis of the lens barrel. The first and second refracting lenses may be mounted to a first set and second set of positioning elements. The image capture element may capture images continuously at a predetermined frame rate, and the first and second set of positioning elements may continuously change the position of the first and second refracting lenses among a series of predetermined correlated positions based on the predetermined frame rate.

Abstract: An apparatus for determining the location of a radio-opaque marker embedded in an excised specimen includes a radio-opaque marker including an energy beacon that can be embedded in the specimen, an energy beacon controller, at least three detectors, a signal processing component, and a display device. An associated method is disclosed. A method for evaluating a radiographically labeled excised specimen involves determining the location of a radio-opaque marker embedded in the excised specimen, anatomically sectioning the excised specimen, macro-optically segmenting the sectioned specimen into an adipose tissue component, a fibrous tissue component, and an epithelial tissue component, and microscopically examining at least one of the tissue components. An associated apparatus is disclosed.

Abstract: A method for capturing a three-dimensional image. The method comprises capturing a combined beam of light having first polarized beam of light and a second polarized beam of light, sampling the combined beam of light using an imager, and providing the first polarized image to a first output and the second polarized image to a second output. The first polarized beam of light and the second polarized beam of light are orthogonally polarized. The imager includes a set of first polarized pixels for sampling the first polarized beam of light to produce a first polarized image, and a set of second polarized pixels for sampling the second polarized beam of light to produce a second polarized image.

Abstract: A mixing assembly for use in a semi-continuous process for producing liquid personal care compositions, such as shampoos, includes a main feed tube carrying a base of the composition to be produced, a plurality of injection tubes in selective fluid communication with the main feed tube, and an orifice provided in a wall at an end of the main feed tube downstream of the plurality of injection tubes. The wall in which the orifice is provided includes a curved (e.g., semispherical) entry surface on an upstream or inlet side of an orifice, and a curved (e.g., semi-elliptical) exit surface on a downstream or outlet side of the orifice. The orifice may have a rectangular or elliptical shape. By maintaining symmetry of the injection tubes with respect to the orifice, and leveraging delay between introduction of dosed modules and increased viscosity, effective mixing may be achieved with minimal energy.

Abstract: A system having a number of land units [100, 4000, 5000] is disclosed which operates to efficiently find and create boreholes [5] to one or more underground targets [1]. Each of the land units [100, 4000, 5000] may be remotely controlled from a central command unit [6000]. The land unit also may be self-controlled, or partially controlled by the central command unit [6000]. The system [10] is reconfigurable to reallocate tasks to functional land units [100, 4000, 5000] which were originally allocated to land units which have been destroyed and are now non-functional.

Abstract: A simulation system [200] models and optimizes parameters for a pulsed liquid slug boring system employing an energetic fluid [7]. The simulation system [200] employs a fluid flow energy unit [251], an exhaust and retention energy unit [253] and a comminuting energy unit [255] to calculate energies of the system. Total energy unit [257] combines these energies. Fluid flow energy unit 251 receives fluid volume and calculates the fluid flow energy. Exhaust and retention energy unit 253 receives input from the exhaust energy volume unit [243] and mission duration unit [211] to determine the exhaust and retention energy. Comminuting energy unit 255 receives hole depth and hole diameter and specific energy of rock to determine the require comminuting energy. The simulation system [200] operates to determine optimum values of design parameters by searching for the minimum energy solution.

Abstract: A camera for obtaining a three-dimensional image. The camera includes a lens module for capturing a beam of light, a filter module for polarizing the beam of light into a first polarized beam of light and a second polarized beam of light, a polarization array for generating a combined beam of light, one or more imagers for capturing the first polarized beam of light and the second polarized beam of light and an output module for processing and separating the mixed polarization image to produce the three-dimensional image. The imager further comprises one or more first polarized pixels for capturing the first polarized beam of light and one or more second polarized pixels for capturing the second polarized beam of light.

Abstract: A method for capturing a three-dimensional image is disclosed. The method comprises capturing a combined beam of light having a first polarized beam of light and a second polarized beam of light, sampling the combined beam of light using one or more imagers, and providing an electrical signal representing a mixed polarization image having a first polarized image and a second polarized image as a single output. The first polarized beam of light and the second polarized beam of light are orthogonally polarized. The one or more imagers include a set of first polarized pixels for sampling the first polarized beam of light to produce the first polarized image, and a set of second polarized pixels for sampling the second polarized light to produce the second polarized image.

Abstract: A method for optimizing stereoscopic effect in a three-dimensional image is provided. The method for optimizing stereoscopic effect comprises capturing a first unpolarized beam of light representing a first image and a second unpolarized beam of light representing a second image using a lens module, converting the first and second unpolarized beam of light into the first polarized beam of light and the second polarized beam of light using a filter module and adjusting separation and convergence of the lens module using a lens control module for generating an output stream.

Abstract: A method for capturing a three-dimensional image. The method comprises capturing a combined beam of light having first polarized beam of light and a second polarized beam of light, sampling the combined beam of light using an imager, and providing the first polarized image to a first output and the second polarized image to a second output. The first polarized beam of light and the second polarized beam of light are orthogonally polarized. The imager includes a set of first polarized pixels for sampling the first polarized beam of light to produce a first polarized image, and a set of second polarized pixels for sampling the second polarized beam of light to produce a second polarized image.

Abstract: The present invention is a self-contained, high-energy liquid rock-boring system that will bore a small-diameter access hole [5] several hundred meters through hard granite and other obstacles within minutes of deployment. It employs a land unit [100] platform subsystem [1000] with an energetic fluid fuel reservoir [1300] and a boring subsystem [3000] having a plurality of pulsejets [3100]. Each pulsejet [3100] repeatedly ignites the energetic fluid [7] causing a plurality of rapidly-expanding gas bubbles [3250] which create and force a plurality liquid slugs [10] ahead of them rapidly out through a nozzle [3260] causing the slugs [10] to impact against materials ahead of the nozzles [3260], boring an access hole [5]. The system also employs an umbilical subsystem [2000] connecting the boring [3000] and the platform subsystems [1000]. The system can be used to rapidly bore an access hole [5] to provide air and resources to trapped miners.

Abstract: A method and device for boring a hole [5] through a material along a desired path includes an umbilical subsystem [2000] connected to a boring subsystem [3000] having a plurality of pulsejets [3100]. These pulsejets [3100] repeatedly receive and ignite a combustible fluid [7] in a combustion chamber [3230] causing a portion of the fluid [7] to be forced out of a nozzle [3260] at high speeds as a fluid slug [10] that impacts materials ahead of the pulsejet [3100]. A controller [3310] controls the amount of fluid provided to each pulsejet [3100], and the firing timing, thereby controlling the intensity in which each slug [10] impacts the material. By modulating the intensity and firing sequence of each of the pulsejets [3100], material ahead of the boring subsystem [3000] is differentially bored thereby allowing steering of the boring subsystem [3000].

Abstract: A system having a number of land units [100, 4000, 5000] is disclosed which operates to efficiently find and create boreholes [5] to one or more underground targets [1]. Each of the land units [100, 4000, 5000] may be remotely controlled from a central command unit [6000]. The land unit also may be self-controlled, or partially controlled by the central command unit [6000]. The system [10] is reconfigurable to reallocate tasks to functional land units [100, 4000, 5000] which were originally allocated to land units which have been destroyed and are now non-functional.

Abstract: The present invention is a self-contained, high-energy liquid rock-boring system that will bore a small-diameter access hole [5] several hundred meters through hard granite and other obstacles within minutes of deployment. It employs a land unit [100] platform subsystem [1000] with an energetic fluid fuel reservoir [1300] and a boring subsystem [3000] having a plurality of pulsejets [3100]. Each pulsejet [3100] repeatedly ignites the energetic fluid [7] causing a plurality of rapidly-expanding gas bubbles [3250] which create and force a plurality liquid slugs [10] ahead of them rapidly out through a nozzle [3260] causing the slugs [10] to impact against materials ahead of the nozzles [3260], boring an access hole [5]. The system also employs an umbilical subsystem [2000] connecting the boring [3000] and the platform subsystems [1000]. The system can be used to rapidly bore an access hole [5] to provide air and resources to trapped miners.

Abstract: A method and device for boring a hole [5] through a material along a desired path includes an umbilical subsystem [2000] connected to a boring subsystem [3000] having a plurality of pulsejets [3100]. These pulsejets [3100] repeatedly receive and ignite a combustible fluid [7] in a combustion chamber [3230] causing a portion of the fluid [7] to be forced out of a nozzle [3260] at high speeds as a fluid slug [10] that impacts materials ahead of the pulsejet [3100]. A controller [3310] controls the amount of fluid provided to each pulsejet [3100], and the firing timing, thereby controlling the intensity in which each slug [10] impacts the material. By modulating the intensity and firing sequence of each of the pulsejets [3100], material ahead of the boring subsystem [3000] is differentially bored thereby allowing steering of the boring subsystem [3000].