Abstract: An analyzer (1) includes: an ionizer unit (10) that ionizes molecules to be analyzed; a filter unit (20) that selectively passes ions generated by the ionizer unit; and a detection unit (50) that detects ions that have passed the filter unit. The detection unit (50) includes a plurality of detection elements (51) disposed in a matrix, and the analyzer (1) further includes a first reconfiguration unit (83) that switches between detection patterns including detection elements to be enabled for detection out of the plurality of detection elements. The ionizer unit (10) includes a plurality of ion sources (11), and the analyzer (1) further includes a driving control unit (65) that switches the connections of the plurality of ion sources based on changes in characteristics of the ion sources.

Abstract: There is provided an analyzer including: an ionizer unit that ionizes molecules to be analyzed; a filter unit that selectively passes ions generated by the ionizer unit; and a detection unit that detects ions that have passed the filter unit. The detection unit includes a plurality of detection elements disposed in a matrix, and the analyzer further includes a first reconfiguration unit that switches between detection patterns including detection elements to be enabled for detection out of the plurality of detection elements. The ionizer unit includes a plurality of ion sources, and the analyzer further includes a driving control unit that switches the connections of the plurality of ion sources based on changes in characteristics of the ion sources.

Abstract: There is provided a monitoring apparatus including a gas sampling apparatus and a sensor that detects a chemical substance included in gas obtained by the gas sampling apparatus. The gas sampling apparatus includes: an air supplying unit that forms an air curtain to form a space that covers a region to which an object to be monitored is included and which is separated from the outside environment; a sampling unit that extracts the gas inside the separated space; and a diffusion gas supplying unit that supplies, into the separated space, an amount of diffusion gas that is at least equal to the sampled amount of the sampling unit, wherein the sampling unit includes a plurality of sampling nozzles disposed at three-dimensionally different positions inside the separated space.

Abstract: There is provided an analyzing apparatus including an irradiation unit irradiating a first point with a laser, a convergence unit causing an analysis target to converge at the first point, and a unit analyzing a sample gas including a substance that has been irradiated with the laser at the first point using an ion mobility sensor. One example of the convergence unit includes a unit causing the analysis target to be captured in a carrier substance in a liquid state; and a discharging unit discharging the carrier substance including the analysis target to the first point.

Abstract: There is provided a system that detects metal ions in a solution easily and with high precision. Such system includes: a unit that produces a mixed solution by mixing a first solution, which includes a first organic compound that has affinity with metal ions to be measured, and a second solution to be measured and supplies the mixed solution to a container; and a unit that detects the metal ions to be measured in the second solution based on a spectrum obtained by ionizing gas in a head space of the container. An example of the first organic compound is siderophores, such as catechol or AHA. The unit that detects the concentration is an ion mobility sensor and is capable of detecting the concentration of metal ions in a solution in real time.

Abstract: A netlist converter, which generates configuration information for reconfiguring a reconfigurable logic operation unit, includes: a mapping unit that enumerates k-feasible cuts where the number of nodes after cutting is an integer k or fewer, out of all cuts for each node included in a netlist generated based on a specification to be processed in the logic operation unit; and a generating unit that generates configuration information including element reconfiguration information that reconfigures elements by selecting cuts assigned to the elements out of the enumerated k-feasible cuts and channel reconfiguration information for reconfiguring the data transfer channels to realize the netlist by connecting the reconfigured elements.

Abstract: There is provided an analyzer including: an ionizer unit that ionizes molecules to be analyzed; a filter unit that selectively passes ions generated by the ionizer unit; and a detection unit that detects ions that have passed the filter unit. The detection unit includes a plurality of detection elements disposed in a matrix, and the analyzer further includes a first reconfiguration unit that switches between detection patterns including detection elements to be enabled for detection out of the plurality of detection elements. The ionizer unit includes a plurality of ion sources, and the analyzer further includes a driving control unit that switches the connections of the plurality of ion sources based on changes in characteristics of the ion sources.

Abstract: Provided is a monitor for monitoring the condition of the interior of a living organism from the surface of the living organism. The monitor is provided with: a probe which includes an observation window and is attached to the organism surface; a unit which irradiates, with a laser, at least a portion of an observation region; a unit which detects scattered light resulting from the laser irradiation; a Doppler analysis unit and a SORS analysis unit which narrow down the observation spots to a first observation spot; and a CARS analysis unit which obtains the optical spectrum for at least one component, and outputs first information indicating the condition of the organism interior on the basis of the intensity of the spectrum.

Abstract: An olfactory system (300) capable of detecting a threat includes: a detection unit (100) including an IMS sensor (110) that outputs IMS data (115) relating to chemical substances included in fluid at a sampling point; a local memory (41) storing a library (49) including a specifying pattern (48) generated when a specified chemical substance was detected by the IMS sensor (110); and a matching unit (42) that routinely compares and matches the IMS data (115) and the specifying pattern (48) for monitoring purposes included in the library (49).

Abstract: There is provided a monitoring apparatus that monitors abnormalities in a system including a plurality of components or products. The plurality of components or products respectively include a plurality of types of microcapsules that release, due to specific causes, a plurality of marker chemical substances respectively, the marker chemical substances having respectively different ion mobilities. The monitoring apparatus includes an ion mobility sensor that detects the plurality of marker chemical substances. By detecting the marker chemical substances, the monitoring apparatus is capable of identifying the occurrence of an abnormal state, the type of abnormal state, the occurrence location, the extent of the abnormal state, and the like.

Abstract: A data processing device includes a data processing unit including a plurality of elements and wiring groups that connect the plurality of elements, wherein respective elements in the plurality of elements include: a logic element; an acquisition unit that switches on and off an input side of the logic element for any wire out of the wiring groups on a cycle-by-cycle basis to latch input data; and a post unit that switches on and off an output side of the logic element for any wire out of the wiring groups on a cycle-by-cycle basis, and the data processing unit also includes a timing control unit that controls logic executed by the logic element and functions of the acquisition unit and the post unit on a cycle-by-cycle basis.

Abstract: An exchange membrane unit includes a first separation membrane, a first space that is connected to a second space via the first separation membrane, a first path that supplies a first fluid (carrier gas) to the first space and supplies chemical substances, which have passed through the first separation membrane from the second space into the first space and diffused, to an ion detector using the first fluid discharged from the first space, and a first ionizing unit provided in the first space. It is possible to provide a preprocessing system that produces little pollution and enables an ion detector to operate with high sensitivity. The present invention can be applied to FAIMS.

Abstract: A leak inspection system includes: an ionizing unit that ionizes components included in a gas; a detection unit that detects the ionized components; a container that houses an object subjected to a leak inspection; a first path that supplies a first gas having a first component that is not ionized by the ionizing unit to one out of the object and the container and supplies gas inside one out of the object and the container via the ionizing unit to the detection unit; and a determination unit that determines, from a detection result of the detection unit, leakage of a second gas, which has a second component that is ionized by the ionizing unit, from inside another out of the object and the container. A leak inspection system with high detection precision can be provided at low cost.

Abstract: There is provided a system that detects metal ions in a solution easily and with high precision. Such system includes: a unit that produces a mixed solution by mixing a first solution, which includes a first organic compound that has affinity with metal ions to be measured, and a second solution to be measured and supplies the mixed solution to a container; and a unit that detects the metal ions to be measured in the second solution based on a spectrum obtained by ionizing gas in a head space of the container. An example of the first organic compound is siderophores, such as catechol or AHA. The unit that detects the concentration is an ion mobility sensor and is capable of detecting the concentration of metal ions in a solution in real time.

Abstract: A movable olfactory robot dog (1) includes an IMS unit (100) acquiring chemical substance-related information relating to chemical substances included in external air (19) respectively obtained from left and right nostrils (12L) and (12R), and an event monitoring unit (30) that determines the occurrence of an event and occurrence direction of the event relative to the robot dog (1) based on a change in the chemical substance-related information respectively acquired at the left and right nostrils (12L) and (12R).

Abstract: An exchange membrane unit includes a first separation membrane, a first space that is connected to a second space via the first separation membrane, a first path that supplies a first fluid (carrier gas) to the first space and supplies chemical substances, which have passed through the first separation membrane from the second space into the first space and diffused, to an ion detector using the first fluid discharged from the first space, and a first ionizing unit provided in the first space. It is possible to provide a preprocessing system that produces little pollution and enables an ion detector to operate with high sensitivity. The present invention can be applied to FAIMS.

Abstract: There is provided a transfer device (30) that transfers ionized substances in a first direction. The transfer device (30) includes a drift tube (50) and the drift tube (50) includes electrode plates (71) and (72) constructing an outer wall and a plurality of ring electrodes (60, 61, 62) disposed inside the tube. The ring electrodes (60) forms a first AC electric field for linear driving that causes the ionized substances to travel in the first direction that is the axial direction. The electrode plates (71) and (72) form an asymmetric second AC electric field that deflects the direction of travel of the ionized substances.

Abstract: There is provided a water quality monitoring apparatus including: an air quality analyzing unit detecting, using an ion mobility sensor, air quality in a space that is at least partially enclosed by a partition wall and a boundary surface with water whose water quality is to be monitored; and an alarm unit that outputs a signal indicating an abnormality if an air quality pattern obtained by the air quality analyzing unit is outside a tolerated range for air quality patterns of air that contacts the water to be monitored. Such water quality monitoring apparatus is capable of monitoring the water quality of drinking water inside a water tank or the like indirectly but precisely by detecting the quality of the air contacting the water using an ion mobility sensor.

Abstract: There is provided a chip-type sampling apparatus to be attached so that a sampling side of the sampling apparatus faces the skin, the apparatus including a porous adsorption layer that faces the sampling side and has a pore diameter in a range of 0.1 to 1000 nm. One example of the adsorption layer includes at least three porous layers with different central pore diameters that are laminated from the sampling side in descending order of the central pore diameters. The sampling apparatus should preferably also include a layer that sucks air through the adsorption layer.

Abstract: There is provided an analysis apparatus including a unit for preparing a sample gas to be supplied to an ion mobility sensor and a control unit equipped with a function of controlling the unit that prepares the gas. The unit for preparing the gas includes a concentration adjusting mechanism that changes the concentration of the target chemical included in the sample gas, and the control unit includes a driver that acquires a measurement result of the ion mobility sensor and a flow control unit that controls the concentration adjusting mechanism in a direction where is improvement in the measurement result.