Abstract: A pivot-arm assembly is provided for attaching an ear cup to a mounting feature on an exterior of a helmet. The pivot-arm assembly comprises a mount configured to releasably couple to the mounting feature. An arm has a first end configured to couple to the ear cup and a second end. A hinge is rotatable about a first axis and about a second axis. The hinge is coupled to the second end of the arm and disposed between the second end of the arm and the mount such that the first end of the arm is rotatable relative to the mount about the first axis and the first end of the arm is rotatable relative to the mount about the second axis. A biasing member is coupled to the arm and is configured to spring bias the first end of the arm relative to the mount in a rotatable direction about the second axis of the hinge.

Abstract: The present disclosure relates to a ball check-valve assembly comprising a ball; a casing comprising an outer surface and defining an internal cavity extending within the casing, the internal cavity comprising a cylindrical inner wall; a bottom threaded connection at a downhole end of the casing, the bottom threaded connection comprising an opening therethrough to allow fluid passage into the internal cavity; a top threaded connection at an uphole end of the casing, at least three longitudinally extending guides defined within internal cylindrical cavity; and (f) a sealing surface formed in the casing and interposed between the top threaded connection and the internal cavity, the sealing surface further defining at least three quartic-shaped flow-passages extending from the sealing surface and providing for fluid passage through the sealing surface from the internal cavity to the uphole end of the casing.

Abstract: A vehicle is electrically connected to one or more removable accessories. The vehicle includes a user interface, an electrical power supply, a chargeable storage, and a controller. The controller may be configured to detect the one or more removable accessories that are connected to the at least one power outlet, determine an identifier associated with each of the one or more detected removable accessories, and cause the user interface to display one or more identifiers associated with the one or more detected removeable accessories.

Abstract: A clock device including: an LC network comprising: a first inductive portion; a second inductive portion connected to the first inductive portion; a third inductive portion connected to the second inductive portion; a first capacitive portion connected to the first, the second, and the third inductive portions; and a second capacitive portion connected to the first inductive portion and the third inductive portion, wherein the LC network is configured to simultaneously resonate at a first frequency and a second frequency that is substantially three times the first frequency, and wherein the clock signal is provided between the first and the third inductive portions by combining a first signal component and a second signal component that is a third harmonic of the first signal component and each inflection point of the first signal component is phase aligned with a corresponding inflection point of the second signal component.

Abstract: A mixed-signal integrated circuit (IC), including: a voltage booster that includes one or more charge pump devices configured to receive an input voltage, an oscillator signal, and a control signal, wherein the one or more charge pump devices comprise a network of capacitors switchable to provide a charged pumped in response to the control signal, and wherein the one or more charge pump devices, using the pumped, generate a boosted voltage based on the input voltage and at least a portion of an amplitude of the oscillator signal, a voltage regulator coupled to the one or more charge pump devices and configured to receive the boosted voltage and generate a regulated boosted voltage based on the boosted voltage, and a control and monitoring engine configured to provide the control signal based on, at least in part, the input voltage, the oscillator signal, and the regulated boosted voltage.

Abstract: Valve assemblies and related pumps, plungers, lift assemblies, and methods may include an insert disposed in an internal flow path of a plunger. The insert includes protrusions, each individually extending into the internal flow path of the plunger and converging at an apex of the insert to define a cage in which the restriction element is configured to move axially through the internal flow path.

Abstract: In general, the subject matter described herein relates to wettable materials that can be used to expose a liquid phase to a gas phase. An example method includes: providing a material including a polymeric substrate and at least one of: a silicate coating disposed over the polymeric substrate; or a polar mineral additive dispersed within the polymeric substrate at a loading from about 1% to about 25%, by weight; and using the material in a chemical process in which the material is at least partially covered by a liquid phase and the liquid phase is exposed to a gas phase.

Abstract: A mixed signal receiver includes a first sample and hold (S/H) circuit having a first S/H input terminal to receive an analog input signal and a first S/H output terminal directly coupled to a first common node; a first data slicer having a first slicer input terminal coupled to the first common node; and a first data-driven charge coupling digital-to-analog converter (DAC) including: (i) a DAC input terminal to receive a first digital signal from a first digital output of the first data slicer, (ii) a DAC output terminal directly coupled to the first common node, (iii) a plurality of capacitor modules configured to be pre-charged during a sample phase, and (iv) logic components, wherein when the logic components toggle a voltage on the plurality of capacitor modules, charge is capacitively coupled to or from the first common node during an immediately subsequent hold phase.

Abstract: An apparatus and method for a multipoint, flexible fishing rod holder that may be quickly and efficiently engaged and disengaged is disclosed. Both the rod handle and rod blank may be supported by separate flexible devices that accommodate all sizes and styles of fishing rod such that the rod may be maintained in a generally horizontal orientation. In one embodiment, the supporting apparatus can be retrofitted to existing fishing apparel. In another, the supporting apparatus is integral to the apparel at the time of manufacture. In certain aspects, the rod holder can be quickly engaged and disengaged to allow an angler use of both hands to facilitate various activities such as changing lures, adding bait, positioning bobbers, or wading with a staff.

Abstract: In general, the subject matter described herein relates to wettable materials that can be used to expose a liquid phase to a gas phase. An example method includes: providing a material including a polymeric substrate and at least one of: a silicate coating disposed over the polymeric substrate; or a polar mineral additive dispersed within the polymeric substrate at a loading from about 1% to about 25%, by weight; and using the material in a chemical process in which the material is at least partially covered by a liquid phase and the liquid phase is exposed to a gas phase.

Abstract: An apparatus and method for a multipoint, flexible fishing rod holder that may be quickly and efficiently engaged and disengaged is disclosed. Both the rod handle and rod blank may be supported by separate flexible devices that accommodate all sizes and styles of fishing rod such that the rod may be maintained in a generally horizontal orientation. In one embodiment, the supporting apparatus can be retrofitted to existing fishing apparel. In another, the supporting apparatus is integral to the apparel at the time of manufacture. In certain aspects, the rod holder can be quickly engaged and disengaged to allow an angler use of both hands to facilitate various activities such as changing lures, adding bait, positioning bobbers, or wading with a staff.

Abstract: An apparatus and method for a multipoint, flexible fishing rod holder that may be quickly and efficiently engaged and disengaged is disclosed. Both the rod handle and rod blank may be supported by separate flexible devices that accommodate all sizes and styles of fishing rod such that the rod may be maintained in a generally horizontal orientation. In one embodiment, the supporting apparatus can be retrofitted to existing fishing apparel. In another, the supporting apparatus is integral to the apparel at the time of manufacture. In certain aspects, the rod holder can be quickly engaged and disengaged to allow an angler use of both hands to facilitate various activities such as changing lures, adding bait, positioning bobbers, or wading with a staff.

Abstract: A clock device including: an LC network comprising: a first inductive portion; a second inductive portion connected to the first inductive portion; a third inductive portion connected to the second inductive portion; a first capacitive portion connected to the first, the second, and the third inductive portions; and a second capacitive portion connected to the first inductive portion and the third inductive portion, wherein the LC network is configured to simultaneously resonate at a first frequency and a second frequency that is substantially three times the first frequency, and wherein the clock signal is provided between the first and the third inductive portions by combining a first signal component and a second signal component that is a third harmonic of the first signal component and each inflection point of the first signal component is phase aligned with a corresponding inflection point of the second signal component.

Abstract: A mixed signal receiver includes a first sample and hold (S/H) circuit having a first S/H input terminal to receive an analog input signal and a first S/H output terminal directly coupled to a first common node; a first data slicer having a first slicer input terminal coupled to the first common node; and a first data-driven charge coupling digital-to-analog converter (DAC) including: (i) a DAC input terminal to receive a first digital signal from a first digital output of the first data slicer, (ii) a DAC output terminal directly coupled to the first common node, (iii) a plurality of capacitor modules configured to be pre-charged during a sample phase, and (iv) logic components, wherein when the logic components toggle a voltage on the plurality of capacitor modules, charge is capacitively coupled to or from the first common node during an immediately subsequent hold phase.

Abstract: A mixed-signal integrated circuit (IC), including: a voltage booster that includes one or more charge pump devices configured to receive an input voltage, an oscillator signal, and a control signal, wherein the one or more charge pump devices comprise a network of capacitors switchable to provide a charged pumped in response to the control signal, and wherein the one or more charge pump devices, using the pumped, generate a boosted voltage based on the input voltage and at least a portion of an amplitude of the oscillator signal, a voltage regulator coupled to the one or more charge pump devices and configured to receive the boosted voltage and generate a regulated boosted voltage based on the boosted voltage, and a control and monitoring engine configured to provide the control signal based on, at least in part, the input voltage, the oscillator signal, and the regulated boosted voltage.

Abstract: In general, the subject matter described herein relates to wettable materials that can be used to expose a liquid phase to a gas phase. An example method includes: providing a material including a polymeric substrate and at least one of: a silicate coating disposed over the polymeric substrate; or a polar mineral additive dispersed within the polymeric substrate at a loading from about 1% to about 25%, by weight; and using the material in a chemical process in which the material is at least partially covered by a liquid phase and the liquid phase is exposed to a gas phase.

Abstract: A temperature measuring circuit uses a diode to drain a switched capacitor at two different lengths of time. The capacitor's voltage is amplified, measured, and compared for each length of time to calculate a temperature. The circuitry may cancel out errors due to manufacturing tolerances and variations, as well as offset voltages, supply noise, substrate noise, and other issues. The process may charge a capacitor, then drain the capacitor with a diode for a first period of time, at which point, the diode is switched out of the circuit. The remaining charge in the diode may be amplified, then analyzed using an analog to digital converter. A second measurement may be taken with a different period of time, and the two measurements may be subtracted to yield an absolute temperature.

Abstract: A clock device includes an LC network that has a first inductive portion; a second inductive portion connected to the first inductive portion; a third inductive portion connected to the second inductive portion; a first capacitive portion connected to the first, the second, and the third inductive portions; and a second capacitive portion connected to the first inductive portion and the third inductive portion, wherein the LC network is configured to simultaneously resonate at a first frequency and a second frequency that is substantially three times the first frequency, and wherein the clock signal is provided between the first and the third inductive portions by combining a first signal component and a second signal component that is a third harmonic of the first signal component and each inflection point of the first signal component is phase aligned with a corresponding inflection point of the second signal component.

Abstract: In general, the subject matter described herein relates to wettable materials that can be used to expose a liquid phase to a gas phase. An example method includes: providing a material including a polymeric substrate and at least one of: a silicate coating disposed over the polymeric substrate; or a polar mineral additive dispersed within the polymeric substrate at a loading from about 1% to about 25%, by weight; and using the material in a chemical process in which the material is at least partially covered by a liquid phase and the liquid phase is exposed to a gas phase.

Abstract: In general, the subject matter described herein relates to wettable materials that can be used to expose a liquid phase to a gas phase. An example method includes: providing a material including a polymeric substrate and at least one of: a silicate coating disposed over the polymeric substrate; or a polar mineral additive dispersed within the polymeric substrate at a loading from about 1% to about 25%, by weight; and using the material in a chemical process in which the material is at least partially covered by a liquid phase and the liquid phase is exposed to a gas phase.