Abstract: Test apparatus for testing porous material such as used in roadway base or building foundations may be deployed in the field at various test sites. The test apparatus includes electrodes that contact the porous material under test and a sensor unit that supplies electromagnetic signals to the porous material. Response signals reveal electrical parameters such as complex impedance which can be equated to material properties such as density and moisture content. Reference may be made to empirical correlations made in laboratory tests using the same test apparatus to enable the effects of the test apparatus on the measurement to be accounted for. The electrodes may include flexible coplanar electrodes that reduce air gaps when in contact with the porous material.

Abstract: Systems and methods for evaluating permeability at unsteady-state pressure conditions and areal distribution of microproppants are provided.

Abstract: In the present invention, a method for determining at least one pore-related parameter of a porous structure is provided. In a preferred embodiment, an enhanced evapoporometry (EP) technique is provided to determine pore size distribution of continuous pores of a porous structure. In this enhanced EP technique, a volatile liquid, such as isopropoyl alcohol or water, is supplied to one side of a porous structure in order to enable the volatile liquid to penetrate and saturate the porous structure through capillary force. Thereafter, an immiscible non-volatile liquid, such as glycerol, mineral oils, silicon oils or hydrophilic ionic liquid, is supplied to the one side of the porous structure. As the volatile liquid evaporates progressively from the filled pores, the emptied pores may be immediately filled by the non-volatile liquid drawn upwards by capillary action. This prevents formation of a t-layer formed from the adsorption of vapour emanating from the volatile liquid that is used to saturate the pores.

Abstract: The present disclosure provides improved systems and methods for automated cell identification/classification. More particularly, the present disclosure provides advantageous systems and methods for automated cell identification/classification using shearing interferometry with a digital holographic microscope. The present disclosure provides for a compact, low-cost, and field-portable 3D printed system for automatic cell identification/classification using a common path shearing interferometry with digital holographic microscopy. This system has demonstrated good results for sickle cell disease identification with human blood cells. The present disclosure provides that a robust, low cost cell identification/classification system based on shearing interferometry can be used for accurate cell identification.

Abstract: A method of detecting bioaerosols, including detecting particles and estimating a particle size for each detected particle and determining a fluorescence strength for each detected particle. Comparing particle size and fluorescence strength for each detected particle to arrive at a normalized fluorescence strength per particle and comparing normalized fluorescence strengths over a time period to a maximum threshold, to detect highly fluorescent manmade substances.

Abstract: A particle detector that includes a housing defining a chamber, and an air stream injector, producing an airstream with entrained particles, in the chamber. A light source produces a light beam that intersects with and is wider than the air stream. A light detection assembly detects light generated by scattering of the light beam, by particles in the air stream. A digitizer produces a sequence of scattering digital values, each representing light detected per a first unit of time duration. Additionally, a summing assembly produces a sequence of summed scattering digital values, each equaling a sum of a sequential set of n of the digital values, and wherein successive summed digital values are offset by a the first unit of time duration and overlap by n?1 of the first units of time duration with a nearest neighbor. Finally, a detection assembly processes the summed scattering digital values to detect particles.

Abstract: Systems for differentially detecting light from a sample in a flow stream (e.g., in a flow cytometer) across one or more dimensions are described. Light detection systems according to embodiments include a flow cell configured to propagate a sample in a flow stream, a light source configured to irradiate the sample in the flow cell and a detector system having an optical adjustment component and a detector that is configured to differentially detect light from the flow cell without a scatter bar. Systems according to certain embodiments are configured to differentially detect light by modulating one or more components of the optical adjustment component or the detector. Methods for differentially detecting light from a sample in a flow stream with a detector unit without a scatter bar are also described. Kits having two or more components for use in the subject systems are also provided.

Abstract: A flow cytometer including a flow cell in which an imaging object flows; a laser beam irradiator configured to radiate laser beam; a camera including an image sensor of N×M pixels; and an optical system configured to introduce the laser beam from the laser beam irradiator to imaging range of flow cell and to introduce signal light, such as transmitted, reflected or scattered light, from imaging range of flow cell, to camera. Optical system includes a mirror device that is placed on a Fourier plane of imaging optical system, that has at least one mirror specularly reflecting the signal light, and that is driven and rotated in conjunction with a flow in flow cell, such that each part of an image formed by the signal light is introduced into an identical pixel of the image sensor for at least a predetermined time period from a predetermined timing.

Abstract: An object is to provide a deterioration detection sensor of a printed wiring board in which the accuracy of detection is enhanced. A deterioration detection sensor of a printed wiring board is a circuit board which is vertically provided on a printed wiring board, and is soldered to the printed wiring board with a soldering portion at a lower end. The deterioration detection sensor includes a detection surface for detecting a foreign material. The detection surface forms an intersection surface which intersects the planar direction of the printed wiring board. In the deterioration detection sensor as described above, a wiring in the detection surface is broken, and thus the foreign material is detected.

Abstract: An apparatus for identifying metal corrosion includes a metal test piece, a push button timer, a liquid tank, a support, two fixed pulleys, a traction cable, a weight and a vibration motor. The support and the first pulley are in a lower portion of the tank. The second pulley is above the first pulley. The test piece is fixed on the support and connected to a first end of the traction cable which sequentially winds around the pulleys with a second end outside the tank. The weight, on which the motor is fixed, is suspended at the second end. The timer is under the motor. A corrosion solution is added into the tank, and the vibration motor provides alternating stress. When the metal test piece is broken, the weight and the motor are dropped and pressed on the electronic timer to record breaking time of the metal test piece.

Abstract: A method for determining a corrosion rate includes receiving an input signal including corrosion data from a sensor. A signal-to-noise ratio (SNR) and a type of noise is determined from the input signal. A corrosion rate computation method is selected based on the SNR and the type of noise. The corrosion rate is determined, using a processor, based on a selected corrosion rate computation method.

Abstract: An off-gas analyzer for analyzing H2O vapor, CO, O2, CO2 and/or H2 in a furnace gas stream is fluidically coupled to a gas extraction probe. The analyzer includes an optical measurement cell having multiple sampling chambers, optically coupled to a laser. The analyzer measuring cell is housed within a heated cabinet having a heater operable to heat the interior thereof so as to maintain the extracted gas sample therein at a temperature about the condensation point of water. The analyzer allows for the analysis of the gas water vapour of wet off-gas samples.

Abstract: A system includes a cuvette (200) including a cuvette body (202) forming a substantially planar exterior surface and having a sensor window (204) defined within the substantially planar exterior surface. The cuvette further includes a probe retention structure (236, 238, 204) extending from the cuvette body. The system includes a probe (402) with a probe body (404) and a protrusion (410) that is removably coupled to the probe retention structure.

Abstract: A flow-through measuring cell having one inlet opening for entry of the fluid, and one outlet opening for exit of the fluid. A single measurement space is located between the inlet opening and outlet opening. A radiation measurement region is provided for measuring the interaction of the fluid in the measuring cell with electromagnetic radiation from outside the measuring cell. The radiation measurement region is bordered by two opposite windows of which one is intended for inlet and the other for exit of the electromagnetic radiation. The measuring cell has a positioning range with several operating positions with a different distance A, A? between the windows into which the measuring cell can be set without rotation.

Abstract: A fluid analyzer includes an optical source and an optical detector defining an optical beam path through an interrogation region of a fluid flow cell. Flow-control devices conduct analyte and reference fluids through a channel and the interrogation region, and manipulate fluid flow in response to control signals to move a fluid boundary separating the analyte and reference fluids across the interrogation region. A controller generates control signals to (1) cause the fluid boundary to be moved across the interrogation region accordingly, (2) sample an output signal from the optical detector at a first interval during which the interrogation region contains more analyte fluid than reference fluid and at a second interval during which the interrogation region contains more reference fluid than analyte fluid, and (3) determine from samples of the output signal a measurement value indicative of an optically measured characteristic of the analyte fluid.

Abstract: A spectrum adjuster produces a pure analyte spectrum and includes: a dynamic opacity optic that receives input light, receives an adjustment signal, produces primary adjusted light, and produces secondary adjusted light from the input light based on the adjustment signal; a light source in optical communication with the dynamic opacity optic; a detector in optical communication with the dynamic opacity optic and that receives transmitted light from the sample and produces a transmitted light signal based on an amount of transmitted light received; and an adjustment controller that receives the transmitted light signal, produces the adjustment signal, and communicates the adjustment signal to the dynamic opacity optic.

Abstract: An analytical test device (i) includes two or more sets of emitters (2, 3, 98, 101), each set of emitters (2, 3, 98, 101) comprising one or more light emitters (2, 3, 98, 101) configured to emit light within a range around a corresponding wavelength. Each set of light emitters (2, 3, 98, 101) is configured to be independently illuminable. The test device (1) also includes one or more photodetectors (4) arranged such that light from each set of emitters (2, 3, 98, 101) reaches the photodetectors (4) via an optical path (7) comprising a sample receiving portion (8). The emitters (2, 3, 98, 101) and photodetectors (4) are configured such that, at the sample receiving portion (8) of the optical path (7), a normalised spatial intensity profile generated by each set of emitters (2, 3, 98, 101) is substantially equal to a normalised spatial intensity profile generated by each other set of emitters (2, 3, 98, 101).

Abstract: A device for calibrating an in-line sensor is disclosed, including a housing having a first aperture and a second aperture arranged along an optical path extending through the housing, a first filter and a second filter disposed within the housing such that the filters are moveable from an operating position to a calibration position. In the calibration position the filters are arranged in the optical path and the housing includes a connection adjacent each of the first aperture and the second aperture, the connection structured to enable the housing to be reversibly attached to a flow cell, a detector and a light source of an in-line sensor.

Abstract: The present invention makes use of a modular Folded Tubular Photometer to measure the concentrations of gas-phase species and/or particles, including especially air pollutants such as ozone (O3), nitrogen dioxide (NO2), sulfur dioxide (SO2) and black carbon particulate matter, by means of absorbance of ultraviolet (UV), visible or infrared (IR) light. The optical bench makes use of modular components (tubes and mirror assemblies) that allow construction of path lengths of up to 2 meters or more while maintaining low detection cell volumes. The long path lengths, low cell volumes, and the innovation of pressure equalization during the absorbance measurements enable sensitive detection of ambient air pollutants down to low part-per-billion levels or less for gas species, and extinctions down to 1 Mm?1 or less for particulate matter, corresponding to ˜0.13 ?g/m3 or less for black carbon particulates.

Abstract: This analyte concentration measuring method including: preparing a mixed solution by mixing a sample solution containing an analyte, with a solution containing aggregation-induced emission fluorescent material-containing particles that have a binding partner which binds with the analyte and that agglutinate and fluoresce when the analyte binds to the binding partner; measuring the fluorescence intensity generated from the aggregation-induced emission fluorescent material-containing particles in the mixed solution; and comparing a fluorescence intensity calibration curve for analyte concentration with the fluorescence intensity, and associating the fluorescence intensity with the analyte concentration in the mixed solution. Employing agglutinating-luminescent-material-containing particles enables measurements to be carried out with a satisfactory detection sensitivity while suppressing background fluorescence.

Abstract: An apparatus and methods for high-speed non-linear spectrally encoded multi-photon imaging that are particularly suited for use in two photon fluorescence and fluorescence lifetime imaging. The system is capable of optical image compression and scale invariant digital zoom. A wavelength agile laser with digitally synthesized electro-optic modulation in a master oscillator-power amplifier configuration is combined with spectral encoding to eliminate the speed limitations of inertial scanning. The technique for fast two photon fluorescent imaging with simultaneous lifetime imaging independently detects the location, amplitude and lifetime of fluorescent emission by synthesizing a sequential excitation beam via digital electro-optic modulation of a quasi-CW swept source followed by time encoded detection. For fluorescent imaging, spectral and temporal mappings are employed separately, with quasi-CW spectral encoding used for pumping and time encoding for constructing the image at fluorescence wavelength.

Abstract: A security feature has a plurality of luminescent surface elements, wherein luminescence lifetime varies between the surface elements. In order to verify the security feature, a lock-in imager is used. The security feature is illuminated with excitation light, which is intensity-modulated with a modulation frequency. The luminescent light emitted by the security feature is detected synchronously with the modulation frequency in a plurality of pixels. This is used to determine a measure of a phase shift between the excitation light and the luminescent light in different pixels. The security feature is verified taking account of the measure of the phase shift in different pixels.

Abstract: High-throughput hyperspectral imaging systems are provided. According to an aspect of the invention, a system includes an excitation light source; an objective that is configured to image excitation light onto the sample, such that the excitation light causes the sample to emit fluorescence light; a channel separator that is configured to separate the fluorescence light into a plurality of spatially dispersed spectral channels; and a sensor. The excitation light source includes a light source and a plurality of lenslet arrays. Each of the lenslet arrays is configured to receive light from the light source and to generate a pattern of light, and the patterns of light generated by the lenslet arrays are combined to form the excitation light. The objective is configured to simultaneously image each of the patterns of light to form a plurality of parallel lines or an array of circular spots at different depths of the sample.

Abstract: Techniques are described for reducing the number of angles needed in structured illumination imaging of biological samples through the use of patterned flowcells, where nanowells of the patterned flowcells are arranged in, e.g., a square array, or an asymmetrical array. Accordingly, the number of images needed to resolve details of the biological samples is reduced. Techniques are also described for combining structured illumination imaging with line scanning using the patterned flowcells.

Abstract: The present disclosure provides devices and methods enabling the analysis of biomolecules. In some embodiments, the biomolecules may be DNA, RNA, protein, peptide, small molecule, catalyst, precursor, nucleotide, antibodies, or other biomolecules of interest.

Abstract: The present invention relates to an in vitro method for determining the transfection of a cell or group of cells, wherein said determination is performed spectroscopically. The determination comprises recording at least one Raman spectrum by means of Raman spectroscopy of the cell or group of cells. Furthermore, the present invention relates to a device for determining the transfection of a cell or group of cells, wherein the device comprises as a first unit (i) a microscope system in order to visualize the cells, as a second unit (ii) a Raman spectroscopy system in order to record a Raman spectrum of a cell or group of cells, and as a third unit (iii) an evaluation module which is coupled to the Raman spectroscopy system and which is configured to determine by means of the recorded Raman spectrum whether a cell or group of cells has been transfected.

Abstract: This invention concerns spectroscopy apparatus comprising a light source arranged to generate a light profile on a sample, a photodetector having at least one photodetector element for detecting characteristic light generated from interaction of the sample with light from the light source, a support for supporting the sample, the support movable relative to the light profile, and a processing unit. The processing unit is arranged to associate a spectral value recorded by the photodetector element at a particular time with a point on the sample predicted to have generated the characteristic light recorded by the photodetector element at the particular time based on. relative motion anticipated to have occurred between the support and the light profile.

Abstract: An electronic device and a method for predicting water ingress employ a water damage indicator including a water-dispersible coating layer which includes a water-dispersible, radiation-cured polymer. Electronic components of the device, which may be susceptible to water damage, are disposed within a casing. The water damage indicator may contact the casing of the electronic device and/or the electronic components. When water enters the casing, the water dispersible coating layer is at least partially removed, revealing the surface beneath, thereby providing an indication of potential water damage to the electronic components. The water damage indicator is not readily replaceable after manufacture, making it more difficult for a customer to disguise potential water damage to the device.

Abstract: The invention provides an apparatus for inspecting a light transmissible optical component. The apparatus comprises an image capturing module arranged on a first side of a support configured to hold a light transmissible optical component whilst it is being inspected. The apparatus includes an illumination device configured to shape light from a light source and to illuminate a selected portion of a surface of said light transmissible optical component with said shaped light to enable the image capturing module to capture any of a bright field image, a dark field image, or a combined bright field and dark field image of the light transmissible optical component being held by the support.

Abstract: Disclosed is a method for maintaining a mechanical apparatus, with the surface of a component thereof being damaged. In an embodiment, the method includes: taking at least one photograph for at least one component; processing the photograph to obtain geometric data of the component; comparing the data with a predetermined standard; and indicating the component meeting the predetermined standard.

Abstract: A system is described for inspecting a container having a top surface using light reflections and positional data. The system comprises a radiation source arranged such that the light beam projects radiation onto the top surface, wherein the radiation radiates along the outer edge of the container; a sensor, wherein the radiation is collected by the sensor reflected from the container using positional data, wherein the positional data is used to create a reference plane of the top of the top surface; and a processor operatively connected to the sensor, the processor integrates the positional data to detect defects in the container and creates a reference plane of a top surface of the container, wherein sensor captures the positional data of the container as the container moves on the conveyor; and the positional data is integrated using software to produce a 3D topographical map of the container.

Abstract: A method of analyzing a sample located on a hydrophilic portion of a surface is disclosed. The method includes directing a first incident non-destructive electromagnetic beam through the sample at a non-zero incidence angle relative to the surface. The method also includes analyzing a first reflected non-destructive electromagnetic beam reflected from the hydrophilic portion to obtain a first measurement associated with at least one property of the sample.

Abstract: Disclosed are a method, an apparatus, and a system for inspecting a ball grid array-type semiconductor chip package. A first embodiment of the present invention provides an apparatus for inspecting a semiconductor chip package, the apparatus comprising: a first image acquisition unit for acquiring a reference image using a three-dimensional image of a semiconductor chip serving as a reference, the reference image being obtained by removing a region of interest from the three-dimensional image; a second image acquisition unit for acquiring a two-dimensional image of a semiconductor chip to be inspected; and an image processing unit for deriving an image of a region of interest of the semiconductor chip to be inspected, from the difference between the reference image and the two-dimensional image.

Abstract: An inspection apparatus including a light source, a sample holding stage, an image capture device, positioned to receive light from the light source after the light has interacted with a sample on the sample holding stage, and a damage metric. The damage metric includes two or more damage levels, and is a function of light in a test image. Further, the damage metric may correlate to visual observation so that an inspection apparatus may mimic how users of devices will perceive damage to the devices. The damage metric may be adjusted to account for different damage types, for example, abrasion and scratch damage.

Abstract: Utilizing microwave reflections to compare a reference device with counterfeit and/or aging devices under test. The reflection from the device under test varies based on certain properties, which results in each device having a unique and intrinsic electromagnetic signature. Comparisons of the electromagnetic signature of the device under test to the electromagnetic signature of a reference device enable evaluating the acceptability of the device under test.

Abstract: An X-ray CT measuring apparatus configured to emit an X-ray from an X-ray source while rotating a subject arranged on a rotary table, and obtain a tomographic image of the subject by reconstructing projection images, includes an imaging unit for imaging the subject on the rotary table from above or sideways, an obtaining unit for obtaining an image of the subject while rotating the subject, a calculating unit for calculating a maximum outer diameter of the subject during rotation by using the obtained image of the subject, and a setting unit for setting a movement limit of the rotary table on the basis of the maximum outer diameter.

Abstract: In an X-ray inspection device according to the present invention, an X-ray irradiation unit 40 includes a first X-ray optical element 42 for focusing characteristic X-rays in a vertical direction, and a second X-ray optical element 43 for focusing the characteristic X-rays in a horizontal direction. The first X-ray optical element 42 is constituted by a crystal material having high crystallinity. The second X-ray optical element includes a multilayer mirror.

Abstract: A hybrid inspection system of the present invention is an inspection system including a first inspection device (1) for inspecting a sample (11) based on X-ray measurement data obtained by irradiating the sample (11) with X-rays, and a second inspection device (2) for inspecting the sample (11) by a measuring method using no X-rays. The X-ray measurement data obtained by the first inspection device or an analysis result of the X-ray measurement data is output to the second inspection device (2). In the second inspection device (2), the structure of the sample (11) is analyzed by using the X-ray measurement data input from the first inspection device (1) or the analysis result of the X-ray measurement data.

Abstract: A sensor for determining the overall content of a pre-determined chemical element in a liquid body uses X-ray fluorescence technology and includes an X-ray source, an X-ray detector, and a cell intended to contain a sample of lubricant to be analyzed, and is provided with a wall forming a window for passage of X-rays, the wall of the sensor cell being produced from polyethylene terephthalate, the cell also including a casing defining an internal volume for receiving the sample. A procedure for calibrating the sensor, and an automated method for online monitoring are also described and claimed.

Abstract: A wavelength dispersive X-ray fluorescence spectrometer includes a single one-dimensional detector (10) having detection elements (7) arranged linearly, and includes a detector position change mechanism (11) for setting a position of the one-dimensional detector (10) to either a parallel position at which an arrangement direction of the detection elements (7) is parallel to a spectral angle direction of a spectroscopic device (6) or an intersection position at which the arrangement direction intersects the spectral angle direction. At the parallel position, a receiving surface of the one-dimensional detector (10) is located at a focal point of focused secondary X-rays (42). At the intersection position, a receiving slit (9) is disposed at the focal point of the focused secondary X-rays (42), and the receiving surface is located at a traveling direction side of the focused secondary X-rays (42) farther from the spectroscopic device (6) than the receiving slit (9).

Abstract: A resin discriminating apparatus includes an X-ray tube which emits X-rays, an X-ray detector which detects X-rays emitted from a sample irradiated with X-rays, a data processing section which creates a spectrum on the basis of a detection signal obtained by the X-ray detector, a peak extraction section which extracts a spectral line due to Compton scattering and a spectral line due to Rayleigh scattering derived from a target element of the X-ray tube on the spectrum, and obtains a peak intensity, and a discrimination section which calculates a scattering intensity ratio which is a ratio of the Rayleigh scattering intensity to the Compton scattering intensity and discriminates the type of resin contained in the sample from the scattering intensity ratio.

Abstract: A multi-beam metrology system includes an illumination source configured to generate a beam array, an illumination sub-system to direct the beam array to a sample at an array of measurement locations, an imaging sub-system to image the array of measurement locations as an array of imaged spots in a detection plane, and a detection assembly to generate detection signal channels associated with each of the imaged spots. The detection assembly includes an array of detection elements configured to receive the imaged spots with separate detection elements, and one or more position detectors to measure positions of the imaged spots in the detection plane. The detection assembly further generates feedback signals for the imaging sub-system based on the measured positions of the imaged spots to adjust the positions of one or more of the imaged spots in the detection plane to maintain alignment of the array of detection elements.

Abstract: A method for measuring the content of sterol and/or derivatives thereof by utilizing nuclear magnetic resonance technology. A nuclear magnetic resonance internal standard method is used, and a specific quantitative peak of sterol and/or derivatives thereof is selected, to accurately measure the (total) content of the sterol and/or derivatives thereof. The method can accurately measure the content of sterol and/or derivatives thereof in extracts of animals, plants and/or microorganisms, food, medicines or cosmetics.

Abstract: In an embodiment of the invention inductive coupling of an idler coil to a parent coil is used to provide a double resonance circuit without the disadvantages of capacitive coupling to the parent coil. In an embodiment of the invention, an inductive coupling coil can be used to achieve a double-tuned circuit. In an embodiment of the invention, a circuit uses inductive coupling to achieve a double resonance circuit for 1H, 19F, and 13C experiments where one of the three nuclei are observed and the other two are decoupled. In an embodiment of the invention a pivot or a shunt can be used to couple and decouple the idler coil and the parent coil.

Abstract: This disclosure relates to determining a material transition point such as a melt-point, and to determining an annealing parameter based on the determined material transition point. Changes in a parameter associated with an electromagnetic circuit coupled to an object subject to heating are monitored. A material transition point is determined upon detecting a predetermined change in the parameter. The annealing parameter is derived from the determined material transition point.

Abstract: A sensor for measuring electrochemical impedance includes a primary circuit that includes a primary electrically conducting coil and a secondary circuit that includes a secondary electrically conducting coil. The primary electrically conducting coil is inductively coupled to the secondary circuit. During operation, the secondary electrically conductive couple has contact electrodes that contact a medium for which the impedance is to be measured. An alternating current source energizes the primary electrically conducting coil during impedance measurements.

Abstract: Method and apparatus to test for volatile organic compounds (VOCs), including a cap configured to at least partially seal a container, and a plunger mechanism configured to form a passageway for air to flow from the container into a detection area. A sensor may be attached to the cap and positioned proximate the detection area. The sensor may be configured to detect data relating to a VOC and to generate a signal. A processor may be configured to receive the signal and to determine a result relating to the VOC.

Abstract: Disclosed are a gas sensor member, a gas sensor using the same, and manufacturing methods thereof, and specifically, a gas sensor member using a one-dimensional porous metal oxide nanotube composite material having a double average pore distribution in which mesopores (0.1 nm to 50 nm) and macropores (50 nm to 300 nm) are simultaneously formed on the surface of a nanotube through decomposition of a spherical polymer sacrificial template and continuous crystallization and diffusion of a metal oxide and a nanoparticle catalyst embedded in an apoferritin is uniformly loaded in the inside and on the outer wall and inner wall of a one-dimensional metal oxide nanotube through a high-temperature heat treatment, a gas sensor using the same, and manufacturing methods thereof are disclosed.

Abstract: A sensor comprises a plurality of sensor elements arranged in an array. Each sensor element is memristive and has an electrical resistance characteristic related to exposure to a species to be sensed. The sensor elements are arranged to be connectable such that at least one sensor element is connected in parallel with at least one other sensor element. By using appropriate connections, the array of sensor elements can be read.

Abstract: The invention provides a bio-detection device, including a carrier, a plurality of spacers, an electronic circuit, and a package layer, wherein an open platform is formed. The carrier includes a test region and a signal transmission wiring, wherein the test region is configured to carry a fluid under test. The spacers are located on the test region and electrically connected to two different voltage levels to form a capacitor for sensing a capacitance of the fluid. The spacers are connected to the signal transmission wiring. The electronic circuit receives and processes a sensing signal corresponding to the capacitance of the fluid. The package layer covers a portion of the carrier but does not cover the test region. The open platform is formed whereby a user can easily put in the fluid. The open platform has a bottom which includes the test region, and an area of the open platform is defined by the spacers and the package layer.