A system for analyzing a state of a thermoset material is disclosed. In various embodiments, the system includes a source of electromagnetic energy configured to expose a sample of the thermoset material to an electric field; a detector configured to determine at least one of a dielectric permittivity or a complex admittance of the sample over a range of frequencies in response to a frequency sweep over the electric field; and an analyzer configured to assess the state of the thermoset material by comparing the at least one of the dielectric permittivity or the complex admittance of the sample against an acceptability map. In various embodiments, the acceptability map comprises a series of acceptability bands that represent a decrease in effective relaxation time from a baseline fresh batch of the thermoset material.

An airflow meter includes a housing including a base surface, a rear surface, a first side surface, a second side surface, a flow-rate inlet portion, a flow-rate outlet portion, a passage, and a physical quantity inlet portion, a flow rate detector, a board, and a physical quantity detector mounted on a board surface. The physical quantity inlet portion includes a first inner surface, a second inner surface, a third inner surface, and a fourth inner surface. The physical quantity detector is configured to output signals according to a physical quantity of air flowing through a board passage. The board, the first inner surface, the third inner surface, and the fourth inner surface are arranged to reduce a cross-sectional area of the board passage from the base surface toward the rear surface.

A biomolecule analysis method of the present disclosure includes: preparing a biomolecule analysis device including a thin film, a first liquid tank and a second liquid tank separated by the thin film, a first electrode disposed in the first liquid tank, and a second electrode disposed in the second liquid tank; and forming a nanopore in the thin film by applying a first voltage between the first electrode and the second electrode in a state where a nanopore forming solution is enclosed in the first liquid tank and the second liquid tank, wherein the nanopore forming solution contains ammonium ions and sulfate ions.

Provided is a method for generating a trained model for classifying blocking event data representing nanopore blocking events in a biomolecule measurement device. The method includes generating a first trained model by executing machine learning of a training model using first teacher data, the first teacher data includes teacher blocking event data and a teacher label, the teacher label indicates whether the teacher blocking event data is classified as Good data or bad data, and the first trained model is configured to classify the blocking event data into good data or bad data. In addition, a method for determining a base sequence a biomolecule and a biomolecule measurement device are provided.

Provided are a hole forming method and a hole forming apparatus capable of stably forming a single nanopore on a membrane. This hole forming method is a hole forming method for forming a hole in a film and includes: a first step of applying a first voltage between a first electrode and a second electrode, installed so as to sandwich the film provided in an electrolyte, and stopping the application of the first voltage when a current flowing between the first electrode and the second electrode reaches a first threshold current so as to form a thin film portion in a part of the film; and a second step of applying a second voltage between the first electrode and the second electrode after the first step so as to form a nanopore in the thin film portion.

A method and system for testing a cathodic protection system that protects a metallic structure with one or more DC power sources electrically connected to the metallic structure and an associated reference electrode. A Cathodic Protection Waveform Monitoring Unit (CPWMU) operates independently from power cycling by the cathodic protection system to measure cathodic protection voltage levels by measuring, over one or more measurement time periods, a voltage differential between the metallic structure and its associated reference electrode, a plurality of times when power provided to the metallic structure is cycled on and off. The CPWMU includes digital storage to store values indicative of the measured voltage differentials over the measurement time period. A reader that may be remotely located from any CPWMU communicates with a number of CPWMU's within communication range to obtain the values stored in the CPWMUs.

A method and system for testing a cathodic protection system that protects a metallic structure with one or more DC power sources electrically connected to the metallic structure and an associated reference electrode. A Cathodic Protection Waveform Monitoring Unit (CPWMU) operates independently from power cycling by the cathodic protection system to measure cathodic protection voltage levels by measuring, over one or more measurement time periods, a voltage differential between the metallic structure and its associated reference electrode, a plurality of times when power provided to the metallic structure is cycled on and off. The CPWMU includes digital storage to store values indicative of the measured voltage differentials over the measurement time period. A reader that may be remotely located from any CPWMU communicates with a number of CPWMU's within communication range to obtain the values stored in the CPWMUs.

A breathing-driven flexible respiratory sensor includes: a test cavity and a digital electrometer, wherein an upper internal wall of the test cavity is provided with an upper detecting component, and a lower internal wall of the test cavity is provided with a lower detecting component; the upper detecting component and the lower detecting component is arranged in a longitudinal symmetry form; wherein the upper detecting component comprises a substrate, an electrode and a gas sensitive film bonded in sequence from top to bottom, and the substrate is bonded to the upper internal wall of the test cavity; wherein a rubber airbag is disposed in the test cavity, and a friction film is bonded to the rubber airbag; an air inlet cylinder is connected to a left end of the rubber airbag, and an air outlet cylinder is connected to a right end of the rubber airbag.

An object trapping device enables efficiently trapping a plurality of objects in a specific combination. Each of a first electrode pair (13), a second electrode pair (14), and a third electrode pair (15) in an electrode pair group (3) is applied with an individual AC voltage and traps an object by dielectrophoresis generated in accordance with the AC voltage that is applied.

An exemplary smoking topography circuit of an electronic aerosol smoking article, includes at least one sensor configured to measure user interaction with the smoking article, a processor, and memory. The processor is configured to detect a smoking event based an output of the at least one sensor, collect data associated with the smoking event, and arrange the data in a pattern that associates the smoking event to shifts in battery voltage. The memory is configured to store the data pattern in a structured multi-byte format.