Abstract: An innovative papermaking belt is disclosed. The papermaking belt has a framework and a reinforcing structure. The framework has a first surface defining a paper-contacting side of the papermaking belt, a second surface opposite the first surface, and conduits extending between the first and second surfaces. A reinforcing structure is positioned between the first surface and at least a portion of the second surface. A material having at least one discrete measuring device disposed therein is disposed upon the reinforcing structure and extends from the first surface to the second surface. The material is distributed so that the reinforcing structure and the discrete measuring device are positioned between the first and second surfaces.

Abstract: A system and method for delivering a flow of gas to an airway of a patient (54). The system includes a gas flow generator (52) and a patient circuit (56) comprising a conduit (100) that communicates the flow of gas to a patient. A sensor (62) is configured to measure a rate of the flow gas and generate flow signals based on the measured rate of flow. A controller (64) is operatively connected with the gas flow generator (52) and the sensor (62) and is configured to control a pressure of the flow of gas provided to the patient. The controller (64) receives the flow signals from the sensor (62), determines a rate of change in the flow of the gas, and modifies or compensates the pressure of the flow of gas provided to the patient if the rate of change in the flow of gas provided to the patient exceeds a threshold amount.

Abstract: An innovative papermaking belt is disclosed. The papermaking belt has a framework and a reinforcing structure. The framework has a first surface defining a paper-contacting side of the papermaking belt, a second surface opposite the first surface, and conduits extending between the first and second surfaces. The reinforcing structure is positioned between the first surface and at least a portion of the second surface. The reinforcing structure comprises a plurality of machine direction warp yarns interwoven with a plurality of cross-machine direction weft yarns. At least one of the machine direction warp yarns further comprises a measuring device.

Abstract: A method for adjusting a papermaking process for producing rolls of convolutely wound web material having a machine direction (MD) and a cross-machine direction (CD) coplanar and orthogonal thereto is disclosed. The process improves the operating life of a papermaking belt used therefor.

Abstract: A method of making a papermaking belt is disclosed. The papermaking belt has a reinforcing structure and a framework. The method comprises the steps of: (a) providing a reinforcing structure having a paper-facing side, a machine-facing side opposite the paper-facing side, interstices and a reinforcing component comprised of a plurality of structural components; (b) providing a first portion of the reinforcing component with a measuring device, the measuring device being disposed upon the first portion of the reinforcing component; and, (c) coating the at least one side of the reinforcing structure with a material so that the material forms a first surface and a second surface, the material being distributed so that the paper-facing side of the reinforcing structure and the measuring device is positioned between the first and second surfaces of the material.

Abstract: A method comprises receiving, by a computing device, a video stream comprising a first presentation interface, separating the received video stream from the first presentation interface, processing the separated video stream, and presenting the processed video stream on a display device in the absence of the first presentation interface.

Abstract: Examples of a wave simulator for board sports and other uses are disclosed. An example wave simulator includes means for forming a wave, the means having at least one inclined side wall and a bottom corresponding to a desired wave shape. The wave simulator includes means for flowing water along at least partially along the inclined side wall and bottom of the flume to form a simulated wave. The wave simulator includes means for restraining a board rider in the means for forming a wave. Streamlines of the simulated wave are substantially parallel to a crest line of the simulated wave, and an inclined water flow ends in a downward arc.

Abstract: An automated system and method for assisting in decision making for the treatment of stroke patients is provided, and specifically for assisting a physician whether the patient should be administered a drug or transferred to another hospital to undergo an endovascular thrombectomy procedure. A variety of factors are input into the system with limited human intervention and a tool automatically determines the probability of whether the patient will have a better outcome if transferred or not. The factors include clinical factors, imaging factors and time to transfer factors. The tool includes processes for automatically determining several imaging factors, including the determination of clot length, collateral blood flow, the presence of forward blood flow within and around the clot, and the clot permeability. The tool has capability to continuously update the treatment protocol and other output results using current clinical, health system or other relevant information or feedback.

Abstract: A system for controlling machine-induced expiratory airflow of a subject, the subject having an airway, the system comprising: a pressure generator (140) configured to generate a pressurized flow of breathable gas for delivery to the airway of the subject; and one or more processors (110) configured to execute computer program modules, the computer program modules comprising: a control module (170) configured to control the pressure generator a metric determination module (154) configured to determine a value of a flow metric during expiration by the subject, a flow analysis module (156) configured to compare the determined value of the flow metric with a target level of the flow metric; and an adjustment module (160) configured to adjust one or more of exsufflation pressure.

Abstract: A pressurized flow of breathable gas is delivered to the airway of a subject in accordance with a therapy regime. Responsive to the subject resuming respiration after a respiratory event, delivery of the pressurized flow of breathable gas is resumed at an inhalation in the therapy regime. As such, the therapy regime is effectively re-synchronized with the respiration of the subject subsequent to a respiratory event.

Abstract: A method for adjusting a papermaking process for producing rolls of convolutely wound web material having a machine direction (MD) and a cross-machine direction (CD) coplanar and orthogonal thereto is disclosed. The process improves the operating life of a papermaking belt used therefor.

Abstract: A method of making a papermaking belt is disclosed. The papermaking belt has a reinforcing structure and a framework. The method comprises the steps of: (a) providing a reinforcing structure having a paper-facing side, a machine-facing side opposite the paper-facing side, interstices and a reinforcing component comprised of a plurality of structural components; (b) providing a first portion of the reinforcing component with a measuring device, the measuring device being disposed upon the first portion of the reinforcing component; and, (c) coating the at least one side of the reinforcing structure with a material so that the material forms a first surface and a second surface, the material being distributed so that the paper-facing side of the reinforcing structure and the measuring device is positioned between the first and second surfaces of the material.

Abstract: An innovative papermaking belt is disclosed. The papermaking belt has a framework and a reinforcing structure. The framework has a first surface defining a paper-contacting side of the papermaking belt, a second surface opposite the first surface, and conduits extending between the first and second surfaces. The reinforcing structure is positioned between the first surface and at least a portion of the second surface. The reinforcing structure comprises a plurality of machine direction warp yarns interwoven with a plurality of cross-machine direction weft yarns. At least one of the machine direction warp yarns further comprises a measuring device.

Abstract: The present disclosure pertains to a pillow system (40), in particular a pillow system that surrounds the subject's head. In some embodiments, the pillow system provides sound suppression. In some embodiments used with positive airways pressure (“PAP”) systems, the pillow system includes a tube that delivers breathable gas to a mask.

Abstract: Methods described herein manage wafer entry into an electrolyte so that air entrapment due to initial impact of the wafer and/or wafer holder with the electrolyte is reduced and the wafer is moved in such a way that an electrolyte wetting wave front is maintained throughout immersion of the wafer also minimizing air entrapment.

Abstract: The present disclosure pertains to a pillow system, in particular a pillow system that surrounds the subject's head, and moves with the subject. In some embodiments, the pillow system provides sound suppression. In some embodiments used with positive airways pressure (“PAP”) systems, the pillow system includes a tube that delivers breathable gas to a mask.

Abstract: Methods described herein manage wafer entry into an electrolyte so that air entrapment due to initial impact of the wafer and/or wafer holder with the electrolyte is reduced and the wafer is moved in such a way that an electrolyte wetting wave front is maintained throughout immersion of the wafer also minimizing air entrapment.

Abstract: The present disclosure pertains to a system and method for controlling insufflation pressure during inexsufflation of a subject. The system inexsufflates the subject such that tidal flow and/or tidal volume are monitored during insufflation, and insufflation pressure is adjusted to maintain the flow rate of the pressurized flow of breathable gas until a target tidal volume is reached for the insufflation. When the target tidal volume has substantially been reached, the system is causes gas to be evacuated from the airway of the subject. This may provide for more precise, customized therapy for the subject than is provided by conventional inexsufflation systems in which inspiratory flow may not be monitored and/or controlled. In one embodiment, the system comprises one or more of a pressure generator, a subject interface, one or more sensors, a processor, a user interface, electronic storage, and/or other components.

Abstract: A system for controlling machine-induced expiratory airflow of a subject, the subject having an airway, the system comprising: a pressure generator (140) configured to generate a pressurized flow of breathable gas for delivery to the airway of the subject; and one or more processors (110) configured to execute computer program modules, th computer program modules comprising: a control module (170) configured to control the pressure generator a metric determination module (154) configured to determine a value of a flow metric during expiration by the subject, a flow analysis module (156) configured to compare the determined value of the flow metric with a target level of the flow metric; and an adjustment module (160) configured to adjust one or more of exsufflation pressure.

Abstract: A pressurized flow of breathable gas is delivered to the airway of a subject in accordance with a therapy regime. Responsive to the subject resuming respiration after a respiratory event, delivery of the pressurized flow of breathable gas is resumed at an inhalation in the therapy regime. As such, the therapy regime is effectively re-synchronized with the respiration of the subject subsequent to a respiratory event.