Abstract: A method and a system for migrating a computing environment from a first platform to a second platform are disclosed. The method includes identifying a first set of components associated with the first platform and a second set of components associated with the second platform. The method further includes comparing the first set of components with the second set of components. Further, the method includes mapping the first set of components with the second set of components based on the comparison. The method further includes introducing the first set of components in the second platform based on the mapping. Further, the method includes updating at least one interface associated with the second platform for interaction with at least one entity. Thereafter, the method includes enriching, using a trained model, the second set of components associated with the second platform.

Abstract: An apparatus, having a server and processor, is configured to receive a first set of security rules applicable to a set of users or a set of files for a first period of time. The first set of security rules are executable in an order of priority. The processor receives an interim security policy that is different from the first set of security rules. The interim security policy is applicable to a subset of the set of users for a second period of time that is less than the first period, or a subset of the set of files for a second period of time that is less than the first period. The processor determines, in the first set of security rules, an insertion point among the order of priority. The processor executes, at the insertion point and in the first set of security rules, the interim security policy.

Abstract: Techniques for providing centralized identity redistribution for a security service are disclosed. In some embodiments, a system/process/computer program product for providing centralized identity redistribution for a security service includes receiving user context information (e.g., an IP-user mapping, a user-tag mapping, an IP-tag mapping, an IP-port-user mapping, an IP-device ID mapping, 5G user context information, and/or other user context information/data) at a security platform from a cloud security service; and applying a security policy at the security platform using the user context information.

Abstract: A cryogenic dewar may include an inner tank and an outer tank. The cryogenic dewar may further include a plurality of trunnion mounts. A first four of the trunnion mounts may be coupled between a front half of the inner tank and a front half of the outer tank. A second four of the trunnion mounts may be coupled between a rear half of the inner tank and a rear half of the outer tank. The trunnion mount may be further strengthen with a plurality of pie-shaped reinforcing pads welded to each other and to an outer surface of the inner tank.

Abstract: A cryogenic dewar may include an inner tank and an outer tank. The cryogenic dewar may further include one or more longitudinal stiffeners coupled to the inner tank at locations of stress that provide resistance to such stress. The inner vessel may include a combination of longitudinal stiffeners to allow the dewar to meet governmental imposed regulations on strength and safety of the dewar without increasing the weight of the dewar or to increase the amount by weight of cryogenic liquid that can be transported under governmental imposed regulations, or both, by, with the addition of longitudinal stiffeners, simultaneously increasing the grade of the material of the inner tank.

Abstract: A cryogenic dewar may include an inner tank and an outer tank. The cryogenic dewar may further include one or more longitudinal stiffeners coupled to the inner tank at locations of stress that provide resistance to such stress. The inner vessel may include a combination of longitudinal stiffeners to allow the dewar to meet governmental imposed regulations on strength and safety of the dewar without increasing the weight of the dewar or to increase the amount by weight of cryogenic liquid that can be transported under governmental imposed regulations, or both, by, with the addition of longitudinal stiffeners, simultaneously increasing the grade of the material of the inner tank.

Abstract: A cryogenic dewar may include an inner tank and an outer tank. The cryogenic dewar may further include one or more longitudinal stiffeners coupled to the inner tank at locations of stress that provide resistance to such stress. The inner vessel may include a combination of longitudinal stiffeners to allow the dewar to meet governmental imposed regulations on strength and safety of the dewar without increasing the weight of the dewar or to increase the amount by weight of cryogenic liquid that can be transported under governmental imposed regulations, or both, by, with the addition of longitudinal stiffeners, simultaneously increasing the grade of the material of the inner tank.

Abstract: A cryogenic dewar may include an inner tank and an outer tank. The cryogenic dewar may further include a plurality of trunnion mounts. A first four of the trunnion mounts may be coupled between a front half of the inner tank and a front half of the outer tank. A second four of the trunnion mounts may be coupled between a rear half of the inner tank and a rear half of the outer tank. The trunnion mount may be further strengthen with a plurality of pie-shaped reinforcing pads welded to each other and to an outer surface of the inner tank.

Abstract: A cryogenic dewar may include an inner tank and an outer tank. The cryogenic dewar may further include a plurality of trunnion mounts. A first four of the trunnion mounts may be coupled between a front half of the inner tank and a front half of the outer tank. A second four of the trunnion mounts may be coupled between a rear half of the inner tank and a rear half of the outer tank. The trunnion mount may be further strengthen with a plurality of pie-shaped reinforcing pads welded to each other and to an outer surface of the inner tank.

Abstract: Direct 3D-printed orthodontic aligners with torque, rotation, and full-control anchors divots are provided. An example process generates multiple virtual models of orthodontic treatment based on progressive moduli of elasticity (MOE) of different materials that will be used to 3D-print a progressive set of 3D-printed aligners. A progression of 3D-printed aligners applies modeled forces to the divot anchors positioned by the models and to the teeth, in treatment stages that are also computed by the models. One class of the example 3D-printed aligners may have flat occlusal biting surfaces, enabling simultaneous treatment of bite correction, temporomandibular joint disorder (TMD), lower jaw growth, and sleep apnea, along with orthodontic movement of teeth. An example 3D-printed aligner has a micro blower for creating air pressure to treat apnea. The aligner may have a microprocessor, sensors, data handling, and data transmission, for controlling actions of the 3D-printed aligner.

Abstract: A micro, single piece, tubeless, cordless, directly inserted oral, nasal or hybrid sleep apnea treatment/anti-snoring device having controlled positive air-flow using a vibrationally isolated micro-blower to maintain an individual's upper airway unobstructed (pharynx area) with or without lower jaw, mandibular advancement is disclosed.

Abstract: A cryogenic dewar may include an inner tank and an outer tank. The cryogenic dewar may further include one or more longitudinal stiffeners coupled to the inner tank at locations of stress that provide resistance to such stress. The inner vessel may include a combination of longitudinal stiffeners to allow the dewar to meet governmental imposed regulations on strength and safety of the dewar without increasing the weight of the dewar or to increase the amount by weight of cryogenic liquid that can be transported under governmental imposed regulations, or both, by, with the addition of longitudinal stiffeners, simultaneously increasing the grade of the material of the inner tank.

Abstract: A cryogenic dewar may include an inner tank and an outer tank. The cryogenic dewar may further include a plurality of trunnion mounts. A first four of the trunnion mounts may be coupled between a front half of the inner tank and a front half of the outer tank. A second four of the trunnion mounts may be coupled between a rear half of the inner tank and a rear half of the outer tank. The trunnion mount may be further strengthen with a plurality of pie-shaped reinforcing pads welded to each other and to an outer surface of the inner tank.

Abstract: Direct 3D-printed orthodontic aligners with torque, rotation, and full-control anchors divots are provided. An example process generates multiple virtual models of orthodontic treatment based on progressive moduli of elasticity (MOE) of different materials that will be used to 3D-print a progressive set of 3D-printed aligners. A progression of 3D-printed aligners applies modeled forces to the divot anchors positioned by the models and to the teeth, in treatment stages that are also computed by the models. One class of the example 3D-printed aligners may have flat occlusal biting surfaces, enabling simultaneous treatment of bite correction, temporomandibular joint disorder (TMD), lower jaw growth, and sleep apnea, along with orthodontic movement of teeth. An example 3D-printed aligner has a micro blower for creating air pressure to treat apnea. The aligner may have a microprocessor, sensors, data handling, and data transmission, for controlling actions of the 3D-printed aligner.

Abstract: A sleep apnea treatment/anti-snoring device optionally having controlled positive air-flow using a micro-blower to maintain an individual's upper airway unobstructed (pharynx area). Optionally the device includes a lower jaw mandibular advancement component. The device has built-in sensors, microprocessor and other items required for data acquisition and transfer.

Abstract: A sleep apnea treatment/anti-snoring device optionally having controlled positive air-flow using a micro-blower to maintain an individual's upper airway unobstructed (pharynx area). Optionally the device includes a lower jaw mandibular advancement component. The device has built-in sensors, microprocessor and other items required for data acquisition and transfer.

Abstract: Direct 3D-printed orthodontic aligners with torque, rotation, and full-control anchors are provided. In an implementation, an orthodontic system uses 3D-printed aligners to perform orthodontic treatment of teeth. Manufacturing the aligners by 3D-printing or additive manufacturing processes imparts novel geometries to the aligners for applying torque, rotation, and full 3D control forces to the teeth in novel ways. The 3D-printed aligners may contain multiple different plastic or metal materials with different orthodontic properties. In an implementation, divot anchors can be strategically applied to teeth to work in conjunction with a 3D-printed aligner fitted over the divot anchors and teeth. The divot anchors may include a depression, channel, groove, or notch providing an attachment point for the aligner to apply a force to the tooth through the divot anchor, such as a torque, rotational force, leverage, push, pull, or 3D control force.

Abstract: A sleep apnea treatment/anti-snoring device optionally having controlled positive air-flow using a micro-blower to maintain an individual's upper airway unobstructed (pharynx area). Optionally the device includes a lower jaw mandibular advancement component. The device has built-in sensors, microprocessor and other items required for data acquisition and transfer.

Abstract: A Home Sleep Testing (HST) device for the diagnosis of obstructive sleep apnea (OSA) and snoring. The Device has an orally mounted microprocessor and sensor set configured to measure a user's movement, sleep pattern and snoring.

Abstract: A sleep apnea treatment/anti-snoring device optionally having controlled positive air-flow using a micro-blower to maintain an individual's upper airway unobstructed (pharynx area). Optionally the device includes a lower jaw mandibular advancement component. The device has built-in sensors, microprocessor and other items required for data acquisition and transfer.