21414B crystal structure, where RH denotes a heavy rare earth element containing at least one of Dy and Tb, and R denotes one or more rare earth elements selected from other than Nd, Pr, Dy, and Tb. The main phase has core sections (11c, 12c) and shell sections (11s, 12s) covering the core sections. The main phase has a first main phase (11) in which CNd > CPr and a second main phase (12) in which CNd < CPr, where CNd denotes the concentration of Nd in the core section and CPr denotes the concentration of Pr in the core section. The concentration of the heavy rare earth element RH in the core section (11c) of the first main phase is higher than the concentration of the heavy rare earth element RH in the core section (12c) of the second main phase. The first and second main phases are mixed.
H01F 1/057 - Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B
H01F 41/02 - Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils or magnets
This water heater (1A) is provided with: a heating device that heats hot water; a hot water storage tank that is disposed below the heating device and stores the hot water heated by the heating device; and a heat insulation member (54) that has a top surface part (541A) disposed between the heating device and the hot water storage tank and covers the hot water storage tank. The top surface part (541A) has at least one of a recess, which is fitted to at least one component constituting the heating device and supports the component, and a protrusion, which abuts on at least one component constituting the heating device and defines the position of the component.
This object detection device (100) comprises a radar signal processor (3), a camera image processor (4), and a fusion processor (5) that executes identity determination processing for the position of an object detected by the radar signal processor (3) and the position of an object detected by the camera image processor (4), and uses the result of the identity determination processing for vehicle control. The camera image processor (4) comprises a region classification unit (13) that performs region classification of a first structure, which is a structure on a road surface that the vehicle can pass, in the vicinity of a detected position in captured image data based on radar detection data. The fusion processor (5) comprises an obstacle determination unit (19) that collates the result of region classification and first radar detection data, which is radar detection data that has produced a failure in the identity determination processing, and if the result of region classification is not included in the position of the first radar detection data, determines that the result of region classification is an obstacle and if the result of region classification is included in the position of the first radar detection data, determines the results of region classification is a first structure.
Provided is a structure formed by stacking a plurality of metal sheets (10, 20) having a conductive base metal covered with an insulating film in a sheet thickness direction, the structure comprising: a protruding section (11) provided to one metal sheet (10) of the metal sheets (10, 20) adjacent to each other and fastened by a screw (51) and protruding toward the other sheet metal (20); an elastically deformable section (12) which is provided in the metal sheet (10) so as to surround the protruding section (11) and is elastically deformed at the time of the fastening by the screw (51); a protruding section (21) protruding toward the metal sheet (10) and disposed in the metal sheet (20) so as to intersect the protruding section (11); and an elastically deformable section (22) which is provided so as to surround the protruding section (21) in the metal sheet (20) and is elastically deformed at the time of the fastening by the screw (51). A distal end of the protruding section (11) and a distal end of the protruding section (21) contact each other at the time of the fastening by the screw (51).
A propeller fan comprising: a motor that rotationally drives a rotating shaft; a boss that is disposed above the motor, is connected to the rotating shaft of the motor, and has formed on the upper surface thereof a plurality of radially extending grooves; and a plurality of blades radially extending from the boss.
In a refrigeration cycle device according to the present disclosure, a heat exchanger is fixed to a housing using a first fixing plate fixed to the housing, a second fixing plate fixed to the first fixing plate, and a mounting plate provided to the heat exchanger. The first fixing plate and the second fixing plate are fixed by screwing a first male screw, which has been inserted into a first elongate hole formed in one of the first fixing plate and the second fixing plate, into a first female screw formed in the other of the first fixing plate and the second fixing plate. The second fixing plate and the mounting plate are fixed by screwing a second male screw, which has been inserted into a second elongate hole formed in one of the second fixing plate and the mounting plate, into a second female screw formed in the other of the second fixing plate and the mounting plate.
Feedback control for controlling a robotic manipulator includes receiving measurement signals from one or more tactile sensors and filtering the measurement signals to align them with the directions of motion of the end effector to produce an impedance-shaping signal. The feedback control determines one or more control signals to the actuators to track a reference state of the end effector based on measurements of the state of the end effector and combines the control signal with the impedance shaping signal to produce control commands. Also, the feedback control may include submitting the determined control commands to the actuators causing a change in the state of the end effector, where the state of the end effector includes one or a combination of an end effector position, an end effector velocity, and an end effector force.
The present invention implements fine-grained control of system calls. This information processing device is provided with: an identification unit for outputting identification results, which are the results of identifying a system call used by a first application and the arguments of the system call, using, as inputs, the first application, file access information, which is information indicating a file accessible by the first application, and a system call list defining system calls to be monitored; and a control unit for controlling whether or not to issue a system call requested by the first application, using the identification results as inputs.
This antenna device comprises: a housing (10) to which an antenna (12) is provided; a control substrate (20) provided to the housing (10); a signal ground (22) that constitutes a reference ground for a circuit in the control substrate (20) and on which a wireless module (21) connected to the antenna (12) by a coaxial cable (11) is mounted; a frame ground (23) that constitutes a ground for the housing (10); a capacitor (24) that connects between the signal ground (22) and the frame ground (23); a housing-side grounding part 13 that grounds the coaxial cable 11; and a substrate-side grounding part (26) that grounds the coaxial cable (11). The loop length of a closed loop (30), which passes through sections connecting between the frame ground (23) and each of the housing-side ground part (13), the substrate-side ground part (26), the capacitor (24), and the housing (10), is less than the wavelength corresponding to the maximum transmission/reception frequency in the wireless module (21).
An electric power conversion apparatus (100) comprises: a plurality of switching elements (Q) connected in series between a pair of first input/output terminals (T1, T2); a plurality of drive circuits (150); and at least one governor circuit (120) each connected to each of at least one switching element of the plurality of switching elements (Q). Each switching element (Q) is turned on and off by a gate voltage applied to a gate terminal from a corresponding drive circuit (120). Each governor circuit (120) includes: an electricity storage element (121) electrically connected between a first main terminal and a second main terminal of the corresponding switching element (Q); a rectifying element (122) connected between the first main terminal and the storage element (121) in a direction in which a current flows to the storage element (121); and a first resistive element (123) electrically connected between a connection point between the rectifying element (122) and the electricity storage element (123) and the gate terminal of the corresponding switching element (Q).
H02M 1/00 - APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF - Details of apparatus for conversion
H02M 3/155 - Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
11.
CYLINDRICAL MEMBER, CYLINDRICAL MEMBER WITH TAPERED PART, SURFACE MAGNET-TYPE MOTOR, AND METHOD FOR MANUFACTURING SURFACE MAGNET-TYPE MOTOR
ij ij , and a stress-strain relational expression in an XY plane is represented as shown in Expression 1 in a Cartesian coordinate system O-XYZ in which an intermediate position in the thickness direction of a microelement (10) of the cylindrical member (1) is defined as an origin O, a tangential direction of the cylinder is defined as an X-axis, a direction parallel to the axial direction of the cylinder is defined as a Y-axis, and a radial direction of the cylinder is defined as a Z-axis.
H02K 15/02 - Methods or apparatus specially adapted for manufacturing, assembling, maintaining or repairing of dynamo-electric machines of stator or rotor bodies
12.
AIR CONDITIONING MANAGEMENT SYSTEM, AIR CONDITIONING MANAGEMENT DEVICE, AND BACKUP METHOD
An air conditioning management system (1000) manages air conditioning-related data related to air conditioning. The air conditioning management system (1000) comprises an air conditioner (Ar1) and an air conditioning management device (100) that manages the air conditioning-related data. The air conditioning management device (100) comprises a first storage device (10M), a second storage device (20M), and a control device (30) that controls the air conditioner (Ar1). The air conditioning-related data includes first data and second data of lower importance than the first data. The control device (30) executes a first update process (S60) for updating storage of first data in the first storage device (10M) and the second storage device (20M) and a second update process (S20) for updating the storage of second data stored in either one of the first storage device (10M) or the second storage device (20M).
F24F 11/49 - Control or safety arrangements for purposes related to the operation of the system, e.g. for safety or monitoring ensuring correct operation, e.g. by trial operation or configuration checks
F24F 11/54 - Control or safety arrangements characterised by user interfaces or communication using one central controller connected to several sub-controllers
First and second semiconductor switching elements (Q1, Q2) are connected in series between first positive electrode wiring (122) and an output node (Nd) via second positive electrode wiring (132). Third and fourth semiconductor switching elements (Q3, Q4) are connected in series between the output node (Nd) and first negative electrode wiring (123) via second negative electrode wiring (133). A flying capacitor (131) is connected between the second positive electrode wiring (132) and the second negative electrode wiring (133). An impedance reduction element (200) including a capacitor (201) is connected between a first node (Nd) and a second node (Nf) in parallel with the flying capacitor (131). The wiring length of a path to the first node (Nd) and the second node (Nf) via the impedance reduction element (200) is shorter than the wiring length of a path to the first node (Nd) and the second node (Nf) via the flying capacitor (131).
H02M 1/00 - APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF - Details of apparatus for conversion
H02M 3/155 - Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
H02M 7/483 - Converters with outputs that each can have more than two voltage levels
14.
MODEL TRAINING DEVICE, MODEL TRAINING METHOD, AND MODEL TRAINING PROGRAM
This model training device (1) comprises: a fixed branch selection unit (16) that selects, from among a plurality of branches included in a training model, a fixed branch that is a branch to be excluded from a training target; a calculation graph change unit (13) that changes a calculation graph to be used to one of a first calculation graph using a plurality of branches or a second calculation graph using training target branches obtained by excluding the fixed branch from the plurality of branches; an inter-branch distance calculation unit (11) that calculates inter-branch distances including distances between features generated by the respective plurality of branches under a state in which the calculation graph to be used is changed to the first calculation graph; a loss function calculation unit (12) that calculates total loss on the basis of a predetermined loss function and the inter-branch distances; and a branch update unit (14) that updates weighting parameters in the training target branches on the basis of the total loss under a state in which the calculation graph to be used is changed to the second calculation graph.
An information processing device (100) comprises: an acquisition unit (120) that acquires an estimation target image (10) and a learned model; an estimation unit (130) that performs estimation using the estimation target image (10) and the learned model; a generation unit (140) that generates a heat map (11) using the estimation result; an extraction unit (150) that extracts a plurality of characteristics on the basis of the heat map (11); and a relearning processing unit (180). The generation unit (140) uses the estimation target image (10) to execute changes with respect to each of the characteristics, and thereby generates a plurality of change images. The estimation unit (130) executes estimation using the change images (21-26) and the learned model. The generation unit (140) uses a plurality of the estimation results to generate heat maps (21a to 26a). If the grounds for estimation are mistaken, the relearning processing unit (180) uses learning data to generate relearning data in which the characteristic indicated by the grounds for estimation has been changed, and the relearning processing unit then relearns the learned model.
This linear motor control apparatus (100) comprises: a plurality of inverters (1) for supplying power to a stator winding (20) of a linear motor (200); a plurality of PWM signal generation units (10) for operating the plurality of inverters (1), respectively; carrier signal generation circuits (4) for generating a carrier signal (Cw) to be used for generating a PWM signal (Pw); and a phase control device (11) comprising a clock circuit (6) and counter circuits (6) for outputting timing signals (Tm) to the plurality of carrier signal generation circuits (4), respectively. When receiving the timing signals (Tm), the carrier signal generation circuits (4) generate carrier signals (Cw) having different phases and supply the carrier signals (Cw) to the plurality of PWM signal generation units (10), respectively, and the plurality of PWM signal generation units (10) use the carrier signals (Cw) to generate PWM signals (Pw) having different phases, and output the PWM signals to the plurality of inverters (1), respectively, for operation thereof.
Provided is a refrigerator that manages a cooled object, said refrigerator comprising a storage chamber that stores a cooled object, a cooler that generates cold air, an air blow duct that has an airflow path through which cold air flows, a lid part that adjusts the flow rate of cold air which flows into the storage chamber, a plurality of heaters that are provided in a respective plurality of areas into which a floor surface of the storage chamber has been virtually divided, a plurality of sensors that are provided on a ceiling surface of the storage chamber and that each measure the temperature of a cooled object which is placed in an area, and a control device. The control device: determines whether or not measurement values of the plurality of sensors belong to a set temperature range; when there is a high-temperature area in which a measurement value is higher than in the set temperature range among the plurality of areas, controls the lid part such that the high-temperature area is cooled with cold air, thereby keeping the temperature of a cooled object placed in the high-temperature area within the set temperature range; and when there is a low-temperature area in which a measurement value is lower than in the set temperature range among the plurality of areas, controls a heater provided in the low-temperature area such that the low-temperature area is heated, thereby keeping the temperature of a cooled object placed in the low-temperature area within the set temperature range.
A blower comprising an impeller which is rotationally driven by a motor and has a plurality of blades, and a cylindrical bell mouth which covers the outer periphery of the impeller and rectifies the flow of air introduced by the rotation of the impeller, wherein the bell mouth comprises a cylindrical suction part on the side into which air introduced by the rotation of the impeller is sucked, and a blowout part which is connected to the whole of the suction part on the side where the air introduced by the rotation of the impeller is blown out, which extends from the suction part obliquely at a uniform inclination angle, and a part of which is a cut-out notched part.
An air-conditioning device according to the present invention comprises: a housing that has a suction port at a front surface and a blowing port at an upper part and contains an air passage that goes from the suction port to the blowing port; a blower that is provided on the air passage; a heat exchanger that is provided on the air passage upstream of the blower; and a plurality of sprinkling mechanisms that are provided on the air passage and spray a fluid toward at least the heat exchanger. The heat exchanger divides the air passage inside the housing into a primary-side space that is below the heat exchanger and a secondary-side space that is above the heat exchanger, and the plurality of sprinkling mechanisms are respectively provided in the primary-side space and the secondary-side space.
A laser radar device (100) comprises: a polarization direction rotation unit (7) that rotates a polarization direction by a predetermined angle with respect to an input laser beam; a polarizing beamsplitter (8) that branches the laser beam, the polarization direction of which has been rotated by the polarization direction rotation unit (7), into a first direction and a second direction different from the first direction; a rotation control unit (15) that realizes circular scanning by the laser beam branched in the first direction and conical scanning by the laser beam branched in the second direction by rotating the polarization direction rotation unit (7) and the polarizing beamsplitter (8) at mutually different rotational angular velocities; and a signal processing unit (14) that calculates a wind velocity field using reflected light reflected by an object irradiated by the laser beams in each scanning.
An inference device (10) is a device that infers control data for controlling a plurality of motors of an air conditioner (1), and includes a data acquisition unit (111) that acquires environment data relating to an environment of the air conditioner (1), and an inference unit (113) that infers the control data on the basis of the environment data acquired by the data acquisition unit (111) using a trained model (20) for inferring the control data on the basis of the environment data.
F24F 11/62 - Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
An air conditioner (1A) comprises: an outdoor unit (20A) connected to a commercial power supply (30); and an indoor unit (10A) connected to the commercial power supply via the outdoor unit. The outdoor unit includes: a body circuit (22) that generates a voltage for driving functional components by using a voltage supplied from the commercial power supply; and a switch (SW2) that is disposed on a connection line for connecting between the body circuit and the commercial power supply, and that switches between connection and opening. When the bus voltage of a bus line connected to the body circuit exceeds a first threshold value, the switch is turned off for only a period of standby time (tx) to stop the power supply to the body circuit, and after the lapse of the period of standby time (tx), the switch is turned on to restart the power supply to the body circuit. When the bus voltage at the restart exceeds a second threshold value that is smaller than the first threshold value, the switch is turned off again for only the period of standby time (tx) to stop the power supply to the body circuit.
A total heat exchange element (100) comprises a plurality of partition members (1) arranged in parallel at intervals, and waveform-shaped interval-retaining members (2) disposed between the adjacent partition members (1). A plurality of the partition members (1) and the interval-retaining members (2) are alternately laminated, and an air supply flow path (3) and an exhaust flow path (4) are formed by the partition members (1) and the interval-retaining members (2). The partition members (1) are made of a water-retentive material to which a water-soluble moisture absorbent is added. The interval-retaining member (2) has a waterproof layer (20) formed on some or all of the apexes of the waveform by using a waterproof agent, and an adhesive part (21) formed by bonding the waterproof layer (20) and the partition members (1) using an adhesive.
F28F 3/00 - Plate-like or laminated elements; Assemblies of plate-like or laminated elements
F28F 3/06 - Elements or assemblies thereof with means for increasing heat-transfer area, e.g. with fins, with recesses, with corrugations the means being attachable to the element
F28F 3/08 - Elements constructed for building-up into stacks, e.g. capable of being taken apart for cleaning
24.
SEMICONDUCTOR DEVICE AND CONTROL METHOD FOR SEMICONDUCTOR DEVICE
The present disclosure relates to a semiconductor device comprising: an n-type first semiconductor layer which is provided between a first main surface and a second main surface of a semiconductor substrate; a p-type second semiconductor layer which is provided between the first semiconductor layer and the first main surface; an n-type third semiconductor layer which is provided on the side of the second semiconductor layer that is toward the first main surface; a p-type fourth semiconductor layer which is provided between the first semiconductor layer and the second main surface; a first and a second trench which penetrate through the second semiconductor layer from the first main surface and which reach the inside of the first semiconductor layer; a first and a second control electrode which are embedded inside of the first and the second trench, respectively, with a first and a second gate insulating film therebetween; and an n-type fifth semiconductor layer which is the upper layer part of the first semiconductor layer below the second semiconductor layer and which is provided so as to be in contact with the second gate insulating film of the second trench, wherein the fifth semiconductor layer has a second impurity concentration higher than a first impurity concentration of the first semiconductor layer and is provided so as to not be in contact with the first gate insulating film of the first trench.
A wind control device (1100) for controlling wind at a target position by controlling a wind control plate device having a wind control plate, said device being equipped with: a wind direction/wind speed acquisition unit (1110) that acquires the wind direction and wind speed at the target position; an external control-related information acquisition unit (1120) that acquires external control-related information, which is information used to control an external wind control plate device other than said wind control plate device; and a drive control unit (1130) that controls the wind control plate device on the basis of the wind direction and wind speed acquired by the wind direction/wind speed acquisition unit, and the external control-related information acquired by the external control information acquisition unit.
E04H 9/14 - Buildings, groups of buildings or shelters adapted to withstand or provide protection against abnormal external influences, e.g. war-like action, earthquake or extreme climate against other dangerous influences, e.g. tornadoes, floods
An antenna apparatus according to the present disclosure comprises: a metal housing (10) that has an opening (10a) in one surface and that has disposed therein a liquid crystal display device (40) having a transparent conductive film facing the opening (10a); an antenna conductor (30) that transmits visible light, forms a gap serving as a slot line between the end surface and an edge surrounding the opening (10a) in the metal housing (10), constitutes a right-handed/left-handed composite transmission line in at least a part of the slot line, and causes the right-handed/left-handed composite transmission line in the slot line to function as a leakage wave antenna; and a power supply point (50) disposed in the gap.
H01Q 13/20 - Non-resonant leaky-waveguide or transmission-line antennas; Equivalent structures causing radiation along the transmission path of a guided wave
27.
PARAMETER OPTIMIZATION DEVICE AND PARAMETER OPTIMIZATION METHOD
This parameter optimization device (1) is provided with: an evolutionary algorithm unit (2) that uses parameters of an evolutionary algorithm, which are set for each creation of a next-generation subpopulation, to create a next-generation subpopulation that is a next-generation group including fewer individuals than those set for each generation of a target problem, and evaluates the next-generation subpopulation; and an optimization unit (3) that learns creation of the subpopulation on the basis of the result of evaluating the next-generation subpopulation, and selects parameters to be used for creating the next-generation subpopulation on the basis of the result of learning.
21414B crystal structure, where RH denotes a heavy rare earth element containing at least one of Dy and Tb, and R denotes one or more rare earth elements selected from other than Nd, Pr, Dy, and Tb; and a subphase (20) present among a plurality of the main phases. The main phase has core sections (11c, 12c) and shell sections (11s, 12s) covering the core sections. The main phase has a first main phase (11) in which CNd > CPr and a second main phase (12) in which CNd < CPr, where CNd denotes the concentration of Nd in the core section and CPr denotes the concentration of Pr in the core section. The concentration of the heavy rare earth element RH in the core section of the first main phase is higher than the concentration of the heavy rare earth element RH in the core section of the second main phase. The first and second main phases are mixed and heavy rare earth elements are present on at least a part of the surfaces in the first main phase and the second main phase.
H01F 1/057 - Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B
H01F 41/02 - Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils or magnets
29.
POWER MODULE, METHOD FOR MANUFACTURING SAME, AND POWER CONVERSION DEVICE
This power module (1) comprises a circuit board (12), a semiconductor element (30), a terminal (40), and a conductive connection member (52). The circuit board (12) includes an insulating layer (13) having a main surface (13b), and a conductive circuit pattern (15) provided on the main surface (13b). The semiconductor element (30) is joined to the conductive circuit pattern (15). The conductive circuit pattern (15) includes a conductive pattern (20). The terminal (40) includes a first end part (41). The first end part (41) of the terminal (40) includes a first surface (42) joined to the conductive pattern (20), and a second surface (43) on the opposite side of the first surface (42). The conductive connection member (52) is bridged between the second surface (43) of the terminal (40) and the conductive pattern (20).
H01L 23/48 - Arrangements for conducting electric current to or from the solid state body in operation, e.g. leads or terminal arrangements
H01L 23/12 - Mountings, e.g. non-detachable insulating substrates
H01L 25/07 - Assemblies consisting of a plurality of individual semiconductor or other solid state devices all the devices being of a type provided for in the same subgroup of groups , or in a single subclass of , , e.g. assemblies of rectifier diodes the devices not having separate containers the devices being of a type provided for in group
H01L 25/18 - Assemblies consisting of a plurality of individual semiconductor or other solid state devices the devices being of types provided for in two or more different subgroups of the same main group of groups , or in a single subclass of ,
30.
DATA PROCESSING DEVICE, DATA PROCESSING METHOD, AND DATA PROCESSING PROGRAM
Hierarchical structure data (200) includes: a first hierarchical structure in which first nodes are hierarchized, the first hierarchical structure corresponding to a first analysis axis, which is an analysis axis of a GHG emission amount; a second hierarchical structure in which second nodes are hierarchized, the second hierarchical structure corresponding to a second analysis axis different from the first analysis axis; and a plurality of emission amount nodes, which are nodes of the GHG emission amount. Two or more first connection nodes connected to the emission amount nodes are included in the plurality of first nodes, and two or more second connection nodes connected to the emission amount nodes are included in the plurality of second nodes. When any one of the first nodes is selected as a first selection node and any one of the second nodes is selected as a second selection node, an extraction unit (104) extracts a chain of nodes from the emission amount node to which the first connection node is connected to the first selection node via the first connection node, and extracts a chain of nodes from the emission amount node to which the second connection node is connected to the second selection node via the second connection node.
This laser processing apparatus (100) performs laser processing in which laser light (3) is condensed by an fθ lens (4) to irradiate a workpiece (25). The laser processing apparatus (100) comprises a protection window (5), a holder (6), a first air nozzle (7) for ejecting first air (A1), and a dust collection device (40) including: a dust collection duct (12) having a first opening (12a), a second opening (12b), a second air nozzle (9) for ejecting second air (A2), and a duct exhaust port (11); and a suction device (20) for sucking the second air (A2). The first opening (12a) and the second opening (12b) have an opening shape capable of surrounding the protection window (5), and the second air nozzle (9) ejects the second air (A2) to a range wider than the diameter of the protection window (5).
An air purifier (1) is mounted to a mounting surface in a room and purifies the air in the room. The air purifier (1) comprises: a non-conductive housing (10) provided with a suction port (13) for sucking in air and an outlet port for blowing out air; a blower (70) that is accommodated in the housing (10) and generates an air flow for sucking in air from the suction port (13) and blowing out air from the outlet port; and a filter that is accommodated in the housing (10) and removes impurities in the air flow. The filter is grounded.
F24F 8/108 - Treatment, e.g. purification, of air supplied to human living or working spaces otherwise than by heating, cooling, humidifying or drying by separation, e.g. by filtering using dry filter elements
F24F 8/192 - Treatment, e.g. purification, of air supplied to human living or working spaces otherwise than by heating, cooling, humidifying or drying by separation, e.g. by filtering by electrical means, e.g. by applying electrostatic fields or high voltages
A bottom plate (1) is laid on a lower part of a loaded object. The bottom plate (1) is provided with: a plurality of coupling protrusions (11) that can be coupled to the loaded object and each of which is in a protruding form in a direction perpendicular to a plate surface of the bottom plate; and an annular protrusion that is annularly disposed in an area surrounded by the coupling protrusions (11).
An information processing device (100) comprises: an acquisition unit (120) that acquires an estimation target image (10) and a learned model; an estimation unit (130) that performs estimation using the estimation target image (10) and the learned model; a generation unit (140) that generates a heat map (11) using the estimation result; an extraction unit (150) that extracts a plurality of characteristics on the basis of the heat map (11); and an output unit (160). The generation unit (140) uses the estimation target image (10) to execute changes with respect to each of the characteristics, and thereby generates a plurality of change images. The estimation unit (130) executes estimation using the change images (21-26) and the learned model. The generation unit (140) uses a plurality of the estimation results to generate heat maps (21a-26a). The output unit (160) outputs: the change images (21-26) and heat maps (21a-26a); or grounds-for-estimation information (40, 61, 62, 80).
A transfer device (10) transfers a reception frame. A frame identification unit (121) assigns a corresponding identifier to the reception frame on the basis of the content in the reception frame. An allocation unit (122) stores the reception frame in a reception queue (123) corresponding to the identifier assigned to the reception frame. A reception gate control unit (124) executes a reception gate control process to read the reception frame from the reception queue (123) on the basis of a gate control setting that is set by a setting unit (104), the gate control setting being adapted for causing the reception queue to wait for a reception frame that has caused a cycle violation of a communication cycle.
Provided is a blower wherein a control device acquires, as a ripple voltage initial value, a ripple voltage value of a DC voltage generated by an electrolytic capacitor, sets a lifespan assessment reference value on the basis of the ripple voltage initial value, acquires, as an assessment target value, the ripple voltage value of the DC voltage generated by the electrolytic capacitor, after setting the lifespan assessment reference value, and assesses the lifespan of the electrolytic capacitor on the basis of the lifespan assessment reference value and the assessment target value.
A calculation circuit (10) is characterized by including a conversion unit (100) that divides a quantized signal other than the most significant bit, which is a sign bit, into a plurality of bit strings, converts each of the plurality of divided bit strings into a sequence of stochastic representations representing a numerical value as the ratio of ones present, and outputs the sign bit and the plurality of sequences of stochastic representations.
H03M 13/03 - Error detection or forward error correction by redundancy in data representation, i.e. code words containing more digits than the source words
A water heater (1A) comprises: a first heat insulation member which has a cylindrical shape having a first recess recessed from a cylindrical surface, and which houses a tank for storing hot water inside a cylinder; a panel (40) to which an electrical component (60) connected to a heating device for supplying heated hot water to the tank is attached, and which is disposed in the first recess; and a first fixing member which is insert-molded in the first recess and fixes the panel (40).
MITSUBISHI ELECTRIC BUILDING SOLUTIONS CORPORATION (Japan)
Inventor
Takewa Tomoaki
Sanda Takayoshi
Wakabayashi Masao
Kato Chikara
Abstract
An authentication device (100) comprises: a first wireless communication control unit (130) capable of performing first wireless communication simultaneously with N1 (N1 is a positive integer) terminals (200); and a second wireless communication control unit (140) capable of performing second wireless communication simultaneously with, among the terminals (200) that are performing the first wireless communication, N2 (N2 is a positive integer) terminals (200). N2 is smaller than N1.
Provided is a brake control device (4) that controls the use of, as brakes for a railway vehicle (100), a regenerative brake and a tread brake (6) that generates a braking force by pressing a brake shoe (12) against a wheel (13), the brake control device (4) comprising: an acquisition unit (41) that acquires position information of the railway vehicle (100); and a control unit (42) which, on the basis of position information (7A), skidding information indicating a skidding position at which the wheel (13) has the potential to skid on a railway track on which the railway vehicle (100) travels, and brake information indicating a braking position at which the railway vehicle (100) applies the brakes, changes a brake usage condition in which the regenerative brake is more preferentially used than the tread brake (6), and in a case in which a brake command (1A) is acquired when the brake usage condition is changed, causes the tread brake (6) to be used at a prescribed ratio with respect to the braking force required by the brake command (1A) to thereby roughen the tread surface of the wheel (13) with the brake shoe (12).
The present invention comprises: a light source (1101) that generates laser light; a light modulator (1102) that superimposes a communication signal on the laser light generated by the light source (1101); an OHPA (1103) that amplifies the laser light superimposed by the light modulator (1102); a collimator (1105) that has a fiber connector (11051) and a collimator lens (11052), that converts the laser light amplified by the OHPA (1103) into spatial light, and that radiates transmitted light constituting the spatial light; an optical telescope (1108) that enlarges the beam width of the transmitted light radiated by the collimator (1105) and radiates the transmitted light along a spatial transmission path; a drive mechanism (1112) capable of adjusting the focal length of the collimator lens (11052); and a drive controller (1113) that determines the drive amount of the drive mechanism (1112) so as to render constant the product of free space loss, which is calculated from the distance between a host device and a spatial optical communication transceiver (11) serving as a communication partner, and transmission gain determined by a beam divergence angle of the transmitted light.
This magnetocaloric material includes a coating powder and a resin. The coating powder is obtained by coating, with a coating film, a material powder of a La(Fe, Si)H-based compound in which hydrogen is adsorbed onto a La(Fe, Si)13-based compound. The coating film has a higher thermal conductivity and a lower hardness than the material powder. The coating films of the coating powders adjacent to each other form a mesh-like structure.
H01F 1/01 - Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials
43.
ATTACK ANALYSIS DEVICE, ATTACK ANALYSIS METHOD, AND ATTACK ANALYSIS PROGRAM
An attack analysis device (100) comprises an analysis priority changing unit (130) that, when equipment to be analyzed that is provided in a system under attack comprising a plurality of equipment each having a set analysis priority is subjected to an attack in question, namely a cyberattack, changes the analysis priority corresponding to the equipment to be analyzed according to the details of the attack in question. Let a group of equipment under attack be defined as a plurality of equipment provided in a system under attack. When each piece of equipment included in the group of equipment under attack is subjected to a cyberattack, the respective cyberattacks on each piece of equipment included in the group of equipment under attack are analyzed sequentially according to the analysis priority corresponding to each piece of equipment included in the group of equipment under attack.
A control device (10) comprises: an external-force calculation unit (11) that, on the basis of a force and moment applied to a robot by an operator and the position and posture of a robot control point that is a control point for the operator to control the robot, calculates force information that is information on the force and moment applied to the robot by the operator; a control mode determination unit (12) that, on the basis of the force information and velocity information that is information on the velocity or angular velocity of the robot, determines which of a normal control mode and a detailed control mode is to be selected, the normal control mode controlling the robot such that the larger the force and moment of the force information, the faster the robot operates, the detailed control mode controlling the robot while limiting at least one of the operation velocity and operation direction of the robot; and an operation command generation unit (13) that, when the normal control mode is selected, generates an operation command corresponding to the normal control mode and outputs the operation command to the robot, and, when the detailed control mode is selected, generates an operation command corresponding to the detailed control mode and outputs the operation command to the robot.
A refrigeration device provided with a refrigerant circuit through which a refrigerant circulates, wherein the refrigerant contains R32, a fluorescent agent for detecting refrigerant leakage from the refrigerant circuit is sealed inside the refrigerant circuit, and the fluorescent agent concentration, which is the concentration of the fluorescent agent contained in a mixture of refrigeration oil flowing through the refrigerant circuit and the fluorescent agent sealed in the refrigerant circuit, is less than or equal to 0.41 wt%.
MITSUBISHI ELECTRIC BUILDING SOLUTIONS CORPORATION (Japan)
MITSUBISHI ELECTRIC CORPORATION (Japan)
Inventor
Yamamoto, Tatsuya
Kanno, Kyohei
Takahashi, Hiroto
Ohta, Yoshihiro
Okazato, Atsushi
Abstract
The processor (411) executes update processing for updating the content of a plurality of tests. The monitoring system executes internal processing on the basis of a supplied input value and outputs an output value as a result. A confirmation test includes a first confirmation test and a second confirmation test performed after the first confirmation test. In the update processing, the processor (411) adds a test to the second confirmation test on the basis of the difference between the content of the first confirmation test and the content of the second confirmation test.
An inspection device (10) is provided with: a task setting unit (142) that sets an inspection task including a processing block that indicates processing content relating to an inspection; a task execution unit (143) that, when the inspection task includes a plurality of processing blocks, executes the plurality of processing blocks in sequence and retains some or all of the data output by each processing block of the plurality of processing blocks, on a per inspection task basis; and a data storage unit (144) that stores the data retained on a per inspection task basis by the task execution unit (143), in a file server on a per inspection task basis. The inspection device (10) makes it possible to collectively manage various data relating to an inspection.
G05B 19/418 - Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control (DNC), flexible manufacturing systems (FMS), integrated manufacturing systems (IMS), computer integrated manufacturing (CIM)
48.
TERMINAL DEVICE, INSPECTION SYSTEM, USER INTERFACE PROVIDING METHOD, AND PROGRAM
A terminal device (20) comprises: a display unit (22); and a control unit (24) that causes the display unit (22) to display a user interface. The control unit (24) causes the display unit (22) to display, as user interfaces having an identical form, a user interface relating to the setting of an external device relating to an inspection and a user interface relating to the setting of a learning device that generates a trained model to be used in the inspection.
G06F 3/0481 - Interaction techniques based on graphical user interfaces [GUI] based on specific properties of the displayed interaction object or a metaphor-based environment, e.g. interaction with desktop elements like windows or icons, or assisted by a cursor's changing behaviour or appearance
49.
PARAMETER ADJUSTMENT DEVICE AND PARAMETER ADJUSTMENT METHOD
This parameter adjustment device comprises a feature amount calculation unit, an evaluation index calculation unit, a first optimal solution search unit, and a display control unit. The feature amount calculation unit simulates the operation of a machine tool-to-be-controlled from a tool movement command, and calculates a feature amount of machining. The evaluation index calculation unit calculates one or more evaluation index values that evaluate the machining result on the basis of the feature amount of machining. The first optimal solution search unit uses a first training result for inferring the evaluation index values from a command value generation parameter set to infer an evaluation index value corresponding to a first search command value generation parameter set, and searches for command value generation parameter set candidates that are a plurality of command value generation parameter sets for simultaneously optimizing the respective evaluation index values by using the inferred result. The display control unit causes the command value generation parameter set candidates to be set in a command value generation device that generates the tool movement command, and displays, on a display unit, the respective evaluation index values in association with feature amounts of machining calculated when the command value generation device operates.
G05B 19/4093 - Numerical control (NC), i.e. automatically operating machines, in particular machine tools, e.g. in a manufacturing environment, so as to execute positioning, movement or co-ordinated operations by means of programme data in numerical form characterised by part programming, e.g. entry of geometrical information as taken from a technical drawing, combining this with machining and material information to obtain control information, named part programme, for the NC machine
G05B 19/4155 - Numerical control (NC), i.e. automatically operating machines, in particular machine tools, e.g. in a manufacturing environment, so as to execute positioning, movement or co-ordinated operations by means of programme data in numerical form characterised by programme execution, i.e. part programme or machine function execution, e.g. selection of a programme
50.
TARGET TRAJECTORY ESTIMATION DEVICE AND TARGET TRAJECTORY ESTIMATION METHOD
This target trajectory estimation device is provided with: an azimuth information reading unit (41) that reads azimuth information indicating an azimuth measurement value obtained by each of a plurality of azimuth sensors (10) that have received an incoming radio wave from an object target (100), and azimuth measurement error information indicating an azimuth measurement error that accompanies the azimuth measurement value indicated by the azimuth information or is set uniformly; a time domain division unit (43) that divides the time at which each of the plurality of azimuth sensors (10) has observed the object target (100) into a plurality of time domains in chronological order, and divides the azimuth information read by the azimuth information reading unit (41) for each divided time domain; an abnormal value determination unit (44) that determines whether the azimuth measurement value indicates an abnormal value on the basis of whether the positions indicated by the azimuth measurement values indicated by the azimuth information present in each time domain are concentrated at one point or are concentrated around a state vector comprising a position and speed, resets the azimuth measurement error associated with the azimuth measurement value determined to be an abnormal value to a setting for lowering the reliability with respect to the trajectory estimation of the azimuth measurement value, and resets the azimuth measurement error associated with the azimuth measurement value determined not to be an abnormal value with the reliability with respect to the trajectory estimation of the azimuth measurement value unchanged; a positioning processing unit (45) that estimates a positioning value in each time domain with respect to an object target (100) using the azimuth measurement value indicated by the azimuth information present in each time domain and the reset azimuth measurement error associated with the azimuth measurement value, for each time domain divided by the time domain division unit (43); and an output unit (46) that connects, in time series, the positioning values for each time domain estimated by the positioning processing unit (45) and outputs object trajectory information indicating the trajectory of the object target (100).
A power conversion device (50) includes a converter (3) that converts an alternating current to a direct current and outputs the direct current to a load (130) and a microcomputer (14) that controls the converter (3). A reference potential of converter control signals (S1-S6) for controlling the converter (3) is a potential of an emitter or a source of a lower element of a plurality of semiconductor elements (Q1-Q6) provided in the converter (3), and the emitter or the source and the microcomputer (14) are connected without through a component that generates a potential difference.
H02M 7/12 - Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
52.
ELECTRIC POWER CONVERSION DEVICE AND REFRIGERATION CYCLE APPLYING DEVICE
An electric power conversion device (1) comprises: an electric power supply unit (100) that converts AC electric power into DC electric power by using semiconductor elements (131–136); a smoothing unit (200) that smooths the DC electric power; an electric current and voltage detection unit (400) that detects an electric current and a voltage that indicate the operating states of the electric power supply unit (100) and the smoothing unit (200); and a control unit (800) that generates a gate voltage command value (600) for controlling the operation of the semiconductor elements (131–136) by using detected values of the electric current and the voltage detected by the electric current and voltage detection unit (400), wherein the control unit (800) comprises a high power factor control unit (500) that generates a modulated wave based on an output voltage command value by using the detection values and generates the gate voltage command value (600) on the basis of the result of comparing the modulated wave and the carrier signal; and an output voltage command value correction unit (700) that generates a correction term by using the detection values and a parameter that is used when generating the modulated wave, the modulated wave being corrected using the correction term.
H02M 7/12 - Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
In the present invention, an electronic substrate unit (9), which is for supplying power to a compressor (5) and on which a power conversion circuit (13) is formed, is accommodated within an outdoor unit housing (3) of an air conditioner outdoor unit (1). The electronic substrate unit (9) is provided with a substrate body (15) and a metal plate (17). The electronic substrate unit (9) is disposed so as to face the outdoor unit housing (3) with an interval therebetween. The metal plate (17) on the electronic substrate unit (9) and the outdoor unit housing (3) are electrically connected via a connection body (31). A first connected part (33), to which one end of the connection body (31) is connected, is formed on the electronic substrate unit (9). A second connected part (35), to which the other end of the connection body (31) is connected, is formed on the outdoor unit housing (3).
H02M 7/48 - Conversion of dc power input into ac power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
54.
AIR CONDITIONING CONTROL DEVICE MOUNTING STRUCTURE AND AIR CONDITIONING CONTROL DEVICE
A housing (7) of an air conditioning control device (1) comprises a front side cover member (9) having a front cover member (11a) and a side cover member (11b). The side cover member (11b) includes a lower side cover member (11ba) and an upper side cover member (11bb). A mounting part (14) including a support member (43), a mounting sheet metal (17a), and a fixing screw (19) is disposed in a recessed section (13) provided in the lower side cover member (11ba). In a state in which the air conditioning control device (1) attached to a front board (33) is viewed from the front, the mounting part (14) is disposed behind the front cover member (11a).
FORMING DEVICE FOR COIL OF ROTARY ELECTRIC MACHINE, FORMING METHOD FOR COIL OF ROTARY ELECTRIC MACHINE, COIL OF ROTARY ELECTRIC MACHINE, MANUFACTURING METHOD FOR STATOR OF ROTARY ELECTRIC MACHINE, AND ROTARY ELECTRIC MACHINE
A forming device (99) for a coil of a rotary electric machine forms the coil from a straight coil conductor, said coil having: a top part (13) that is a triangular vertex; a crank part (12) that is positioned at the top part (13); and shoulder parts (15a, 15b) that connect oblique side parts (14a, 14b) and straight parts (16a, 16b). The forming device (99) comprises: a forming die (41) that is a die for the crank part (12), the top part (13), and the shoulder parts (15a, 15b) of the coil (10) of the rotary electric machine (100); a crank part forming punch (42) for forming the crank part (12); a top part forming punch (43) for forming the top part (13); shoulder part forming rollers (44a, 44b) for preliminarily forming the shoulder parts (15a, 15b); and shoulder part forming punches (45a, 45b) for finally forming the shoulder parts (15a, 15b).
H02K 15/04 - Methods or apparatus specially adapted for manufacturing, assembling, maintaining or repairing of dynamo-electric machines of windings, prior to mounting into machines
A refrigeration device provided with a refrigerant circuit through which a refrigerant circulates, wherein the refrigerant contains R32, a fluorescent agent for detecting refrigerant leakage from the refrigerant circuit is sealed inside the refrigerant circuit, and the fluorescent agent concentration, which is the concentration of the fluorescent agent contained in a mixture of refrigeration oil that flows through the refrigerant circuit and the fluorescent agent sealed in the refrigerant circuit, is less than or equal to 0.41 wt%.
In this signal processing circuit (1), an input circuit (2) generates an input signal (SIN) by binarizing an external input wave (EW). A digital filter circuit (4) samples the input signal (SIN) on the basis of a clock signal (CLK), and removes noise included in the input signal (SIN) on the basis of a plurality of sampling values. A counter circuit (5) counts the number of pulses included in the input signal (SIN) from which the noise has been removed by the digital filter circuit (4). A clock supply circuit (3) which generates the clock signal (CLK) selectively outputs one of a phase synchronization circuit output and a timer circuit output as the clock signal (CLK).
A brake control device (1) controls a mechanical brake device (30) comprising a force-multiplying mechanism, a pressing mechanism (31), and a transmission mechanism (38). The force-multiplying mechanism generates braking force by pressing a friction material against a rotating body in response to received pressing force. The pressing mechanism (31) presses the force-multiplying mechanism. The transmission mechanism (38) is in contact with the pressing mechanism (31) and the force-multiplying mechanism, and presses the force-multiplying mechanism with force exerted by the pressing mechanism (31). The brake control device (1) comprises a target brake force determination unit (11), a target mechanical brake force determination unit (12), a brake control unit (13), and a transmission control unit (18). The transmission control unit (18) allows or inhibits the pressing of the force-multiplying mechanism by the transmission mechanism (38).
B60T 8/00 - Arrangements for adjusting wheel-braking force to meet varying vehicular or ground-surface conditions, e.g. limiting or varying distribution of braking force
59.
BRAKE CONTROL DEVICE, BRAKE CONTROL SYSTEM, AND BRAKE CONTROL METHOD
A brake control device (1) comprises a target brake force determination unit (11), a target mechanical brake force determination unit (12), an adjustment unit (13), and a brake control unit (14). The target brake force determination unit (11) obtains a target brake force from a brake command. From the target brake force, the target mechanical brake force determination unit (12) obtains a first target mechanical brake force, which is a target value of the brake force to be exerted by a mechanical brake device (30). The adjustment unit (13) adjusts the first target mechanical brake force to obtain a second target mechanical brake force that repeatedly increases or decreases with respect to the first target mechanical brake force. The brake control unit (14) controls the mechanical brake device (30) according to the first target mechanical brake force or the second target mechanical brake force.
B61H 1/00 - Applications or arrangements of brakes with a braking member or members co-operating with the periphery of the wheel rim, a drum, or the like
B60T 8/17 - Using electrical or electronic regulation means to control braking
The present disclosure relates to a travel planning device. The travel planning device according to the present disclosure changes a travel plan of a vehicle and comprises: a travel plan changing unit that changes the travel plan on the basis of at least one of people flow information, popular attraction information, real estate information, facility-related information, road information, and roadside unit installation information, these being information pertaining to people flow, popular attractions, real estate, facilities, roads, and installed roadside units, respectively, in a geographical area where the vehicle travels; and a travel plan output unit that outputs the changed travel plan, wherein the people flow information includes information pertaining to people flow according to the number of people using commercial facilities or tourist attractions.
An automatic docking device (100) comprises a point group generation unit (120) and a navigation scenario generation unit (140). On the basis of a result of measurement of the position and orientation of a subject ship by a GNSS/INS composite navigation device (200), the point group generation unit (120) converts, into absolute coordinates, relative coordinates that respectively correspond to points in a point group corresponding to a result of distance measurement by a subject radar at a subject berth, and generates a subject map which, on the basis of the converted absolute coordinates respectively corresponding to the points, indicates a navigable area at the subject berth and indicates the absolute coordinates. When a target position and a target orientation of the subject ship at the subject berth are designated on the basis of the subject map, the navigation scenario generation unit (140) generates a plan to guide the subject ship for arrival at the target position in the target orientation on the basis of the subject map and the measured position and orientation of the subject ship.
G01C 21/12 - Navigation; Navigational instruments not provided for in groups by using measurement of speed or acceleration executed aboard the object being navigated; Dead reckoning
62.
AIR CONDITIONING UNIT AND REFRIGERATION CYCLE DEVICE
This air conditioning unit is provided with: a housing that constitutes an outer shell; a U-shaped first heat exchanger that is provided inside the housing and has a first portion, a second portion that faces the first portion, and a third portion that connects the first portion and the second portion; and one or more blowers that are disposed between the opposing first portion and second portion. Each of the one or more blowers is provided with: a centrifugal fan provided with a rotating shaft; and a casing that accommodates the centrifugal fan. The casing is formed with one or more suction ports and one or more blowout ports. The casing is disposed in a direction such that at least a part of the suction ports face any of the first portion, the second portion, or the third portion, and the one or more blowout ports do not face any of the first portion, the second portion, or the third portion.
A request reception unit (21) receives a request indicating a condition index and a subject index and designating a value of the condition index. Here, one of the condition index and the subject index is an index relating to environmental load reduction, and the other is an index relating to economic effect. When the degree of maturity of productivity improvement is represented by a combination of a maturity level, which is the maturity level of automation, and a scale level, which is the scale level of a management target, an index calculation unit (223) sets each of at least some combinations of the maturity level and the scale level as a target combination. The index calculation unit (223) calculates the value of the subject index where a target combination is achieved and the designated value of the condition index indicated by the request is satisfied.
A power transmission apparatus (10) comprising an extending power transmission coupler (14, 140), a high-frequency power supply (12) that supplies high-frequency power to the power transmission coupler (14, 140) via a matching circuit (13), object detection sensors (3a, 3b) that are respectively installed at one end and the other end of the power transmission coupler (14, 140) and that detect power reception devices passing through the respective installed positions, and a control device (15) that controls the matching circuit (13), wherein the matching circuit (13) is configured with a circuit that can be switched to a plurality of circuit configurations, and the control device (15) receives signals from the respective object detection sensors (3a, 3b), analyzes the received signals, determines the number of power reception devices (20) positioned on the power transmission coupler (14, 140), and then performs control so as to switch the circuit configuration of the matching circuit (13) on the basis of the determined number of power reception devices (20).
An electric power conversion apparatus (100A, 100B, 100C, 100D) comprises a cooler (10) and a component (50) disposed on the cooler. A refrigerant flow path (40) through which a refrigerant flows is provided in the cooler. A flow path surface area of the refrigerant flow path is reduced in a temperature range in which the temperature of the component is equal to or higher than a reference temperature.
H02M 7/48 - Conversion of dc power input into ac power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
66.
DISPLAY CONTROL DEVICE, INSPECTION SYSTEM, SCREEN IMAGE DISPLAY METHOD, AND PROGRAM
An inspection device (10) comprises: a storage unit (13) that stores task setting information relating to a processing block indicating processing content related to an inspection, correspondence information indicating an association between the processing block and a monitor component, and layout setting information relating to setting of a layout of a monitor screen image using a monitor component selected as a display target by a user; and a layout generation unit (151) that, on the basis of the task setting information and the layout setting information, generates monitor layout information for displaying the information related to the inspection.
A moving body system (10) comprises: one or a plurality of moving bodies (100); and an information processing unit (102) that manages a map composed of links and the patrol of each moving body (100) and sets a target link for each moving body (100) and a route for each moving body (100) to the target link. The information processing unit (102) has: a location information inquiry function (105) for determining whether each moving body (100) has reached the target link thereof; a target link setting function (106) for setting a target link for a moving body that has reached the current target link thereof or a moving body that does not have a target link; and a route generation function (107) for setting a route to a set target link on the basis of a passage schedule, elapsed patrol time, patrol history, patrol count, and link distance. The information processing unit (102) repeats the operation of setting a route for each moving body (100) and the operation of setting, after each moving body (100) has traveled a set first target link, a second target link different from the first target link for the moving body (100).
An outdoor unit (10) of a refrigeration cycle device (100) has a compressor (11), an outdoor heat exchanger (13), and a plurality of expansion valves (14a, 14b, 14c). A piping diameter of first piping (30a, 30b, 30c) is set to a first diameter (d1) when a piping length is longer than a prescribed length (Ls), and the piping diameter is set to a second diameter (d2) that is smaller than the first diameter (d1) when the piping length is shorter than the prescribed length (Ls). The prescribed length (Ls) is set to a first length (Ls21) when the number of a plurality of indoor units is a first number (N1), and is set to a second length (Ls22) that is shorter than the first length (Ls21) when the number of the plurality of indoor units is a second number (N2) that is greater than the first number (N1).
A filter device (31) comprises a first filtration member (41) having: a plurality of first front surface parts (42); a plurality of first back surface parts (43); and a plurality of first side-surface parts (44). Main surfaces (42a) of the respective first front surface parts (42) intersect the inflow direction of outside air. The first front surface parts (42) are positioned with first gaps (45) sandwiched therebetween. Main surfaces (43a) of the respective first back surface parts (43) each face a corresponding one of the first gaps (45) between two of the first front surface parts (42) adjacent to each other. The first back surface parts (43) are, with intervals therebetween, positioned downstream of the first front surface parts (42). The first side-surface parts (44) connect the first front surface parts (42) and the first back surface parts (43). The interval between the two first side surface parts (44) connected to the same first back surface part (43) on the downstream side in the inflow direction is equal to or greater than that on the upstream side in the inflow direction, and the total surface area of the first side-surface parts (44) is larger than the total surface area of the first front surface parts (42) and the total surface area of the first back surface parts (43).
This drowsiness estimation device is provided with: a sensing unit (11) that, on the basis of frames of captured images of the face of an occupant of a moving body, acquires drowsiness-related information for each frame; a first noise factor detection unit (12) that detects noise factor activity of the occupant on the basis of the drowsiness-related information; a feature quantity calculation unit (13) that calculates a drowsiness estimation feature quantity on the basis of noise factor-removed drowsiness-related information, which is obtained by removing, from the original drowsiness-related information, the drowsiness-related information on the basis of which the first noise factor detection unit (12) detected the noise factor activity; a drowsiness score calculation unit (14) that calculates a drowsiness score using the drowsiness estimation feature quantity calculated by the feature quantity calculation unit (13); and a drowsiness estimation unit (15) that estimates the occupant's drowsiness on the basis of the drowsiness score calculated by the drowsiness score calculation unit (14).
B60W 40/08 - Estimation or calculation of driving parameters for road vehicle drive control systems not related to the control of a particular sub-unit related to drivers or passengers
A61B 5/18 - Devices for psychotechnics; Testing reaction times for vehicle drivers
71.
ADDRESS SETTING DEVICE, REFRIGERATION CYCLE SYSTEM, AND ADDRESS SETTING METHOD
An address setting device for setting an address related to communication with a plurality of apparatuses which are connected in a system comprises: an initial address determining unit for determining, for each apparatus in the system, an initial address to serve as an initial value; a modified address determining unit for deciding, on the basis of the operation states of the apparatuses while the system is working, an order of the apparatuses for which communication should be prioritized, and determining an address based on the order; and an address setting unit for setting an address related to the determinations of the initial address determining unit and the modified address determining unit.
This storage battery system is provided with: a battery rack that is disposed in a space surrounded by a wall surface and accommodates a plurality of storage battery modules; and a first air conditioner that blows out cooling air. The battery rack has a cooling surface that is at least one of a side surface in which an intake hole for taking in the cooling air is formed inside the battery rack, and a side surface that has the largest area among the plurality of side surfaces of the battery rack. The first air conditioner is provided on the wall surface facing the cooling surface.
A brake control device (1) comprises: a weight determination unit (11); a target brake force determination unit (12); a target mechanical brake force determination unit (14); a control unit (15); and a compensation unit (16). The weight determination unit (11) obtains the weight for each of a vehicle, a truck, an axle, and a wheel. The target brake force determination unit (12) obtains a target brake force from a braking command and the weights. The target mechanical brake force determination unit (14) obtains a target mechanical brake force from the target brake force. The control unit (15) controls mechanical brake devices (71a-71h) in accordance with the target mechanical brake force. The compensation unit (16) adjusts at least one of the target mechanical brake force, the target brake force, and the weights, to compensate for variations in adhesive force between rails and a plurality of wheels provided to the same vehicle, truck, or axle.
This electric motor comprises: a stator assembly that includes a stator and a circuit board; a metal member that is disposed so as to face the stator assembly; and a resin part that covers the stator assembly and the metal member so that a part of the metal member is exposed. The stator assembly has a contact member that abuts against the metal member. The metal member has a rough surface part between at least a contact part abutting against the contact member and a boundary part between the inside and the outside of the resin part. The surface roughness of the rough surface part is higher than the surface roughness of the exposed surface of the metal member exposed from the resin part and/or the surface roughness of the center part of the surface of the metal member facing the stator assembly.
A brake control device (1) controls a mechanical brake device (30) comprising: a booster mechanism; a pressing mechanism (31) that presses the booster mechanism by means of an output shaft that slides in response to rotation of a motor (32); and a biasing mechanism that applies force to the booster mechanism by means of a biasing member. The brake control device (1) comprises a drive driver (14) and a mechanism control unit (19). The drive driver (14) converts, in accordance with a target torque, electric power supplied from a power supply device (42) into electric power that is to be supplied to the motor (32), and outputs the converted electric power to the motor (32). The mechanism control unit (19) either permits or limits applying of force to the booster mechanism by the biasing mechanism provided to the mechanical brake device (30).
B61H 1/00 - Applications or arrangements of brakes with a braking member or members co-operating with the periphery of the wheel rim, a drum, or the like
F16D 65/18 - Actuating mechanisms for brakes; Means for initiating operation at a predetermined position arranged in or on the brake adapted for drawing members together
F16D 125/68 - Lever-link mechanisms, e.g. toggles with change of force ratio
76.
SOLID INSULATION BUSBAR CONNECTION DEVICE AND ASSEMBLY METHOD FOR SOLID INSULATION BUSBAR CONNECTION DEVICE
A solid insulation busbar connection device (50) comprises: a pair of tank connection units (51, 52) attached to each of two electric devices to be connected; and a solid insulation busbar unit (30) installed between the tank connection units (51, 52). The solid insulation busbar unit (30) comprises: a vertical busbar unit (55, 57) having a first central conductor covered with an insulating resin and disposed so as to extend in the vertical direction; and a horizontal busbar unit (56) having a second central conductor covered with an insulating resin and disposed so as to extend in the horizontal direction.
A power conversion device (50) is provided with a converter (3) that converts AC into DC and outputs the DC to a load (130). The converter (3) is provided with semiconductor elements (Q1 to Q6) and a drive circuit (16) for driving the semiconductor elements (Q1 to Q6). The drive circuit (16) is provided with a boot capacitor (64c) for applying a drive voltage to each of the upper elements of the semiconductor elements (Q1 to Q6), and the boot capacitor (64c) is configured such that electric charge is stored by causing a current to flow to the load side of the converter (3).
H02M 7/12 - Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
78.
POWER CONVERSION DEVICE, MOTOR DRIVE DEVICE, AND EQUIPMENT FOR REFRIGERATION CYCLE APPLICATIONS
A power conversion device (50) comprises: a converter (3) that converts an alternating current into a direct current and that outputs the direct current to a load (130); a capacitor (4) that smooths the output voltage of the converter (3); a shunt resistor (7) and a current detection unit (10) that detect a converter current (I1) which flows between the converter (3) and the low potential side of the capacitor (4); and a control unit (14) that controls the operation of the converter (3). The control unit (14) uses the polarity of a first current to perform a protective operation against the converter (3).
H02M 7/12 - Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
79.
POWER CONVERSION DEVICE AND REFRIGERATION CYCLE APPLICATION APPARATUS
A power conversion device (1) is equipped with a power supply unit (100) comprising: a rectifying/boosting unit (170) that has a switching element (142) capable of pulse width modulation driving and that converts AC power into DC power; and a reactor (120) that is disposed between an AC power supply (110) for supplying AC power and a smoothing unit (200) for smoothing DC power. The capacity of the reactor (120) is set from the power factor of the power supply unit (100) and the reactor peak current flowing through the reactor (120) during non-pulse width modulation driving in which a current flows through a diode connected in parallel to the switching element (142), and the drive frequency of the switching element (142) is set from the magnetic characteristics of the reactor (120).
H02M 7/12 - Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
80.
POWER CONVERSION DEVICE AND APPARATUS USING REFRIGERATION CYCLE
A power conversion device (1) comprises: a power factor improvement circuit (100) that includes at least one reactor and operates at a carrier frequency; and a noise filter part (400) that is electrically connected between the power factor improvement circuit (100) and an alternating-current power supply (600). The power conversion device (1) has at least two resonant frequencies.
H02M 1/12 - Arrangements for reducing harmonics from ac input or output
H02M 7/12 - Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
81.
INFORMATION TRANSFER DEVICE AND INFORMATION TRANSFER METHOD
The objective of the present invention is to provide a technology that can ensure real-time control for control equipment. This information transfer device comprises a real-time data processing unit and a non-real-time data processing unit. The real-time data processing unit includes a control data generation unit, a first data collection unit, a first OS-to-OS communication unit, and a first data management unit that manages data to and from a real-time data storage unit. The non-real-time data processing unit includes a second data collection unit, a second OS-to-OS communication unit, and a second data management unit that manages data to and from a non-real-time data storage unit.
A communication control device (1) comprises: a telegram acquisition unit (111) that, on the basis of a UDP protocol, acquires, via a local network, a device telegram generated by a device (3); a transmission request determination unit (118) that determines whether transmission request information requesting transmission of a device telegram to the device (3) is to be multicast or broadcast to the device (3); and a processing order management unit (119) that, when it is determined that the transmission request information is to be multicast or broadcast to the device (3), causes a telegram acquisition process for acquiring a device telegram to be preferentially executed before other processes, among a plurality of processes sequentially executed to relay information transmitted and received between the device (3) and a cloud server (2).
The present invention manages processing of data with high priority-order while reducing a load caused by data processing. This priority-order change device comprises: a priority-order change unit that changes the priority-order of data; and a data selection unit that, on the basis of the priority-order, selects data for reducing processing from a plurality of pieces of data. The priority-order change unit changes the priority-order of priority-related data, which is data related to priority-order-changed data that is the data for which the priority order has been changed, on the basis of the degree of relevance of the priority-order-changed data. The data selection unit selects, from the plurality of pieces of data including the priority-order-changed data and the priority-related data, data for reducing the processing on the basis of the priority order.
The present invention comprises: a plurality of ultrasonic sensors (2) installed on the surface of an electric apparatus (900); a detection time difference calculation unit (7) for calculating the detection time difference with respect to ultrasonic waves from respective sensor signals (S) of the plurality of ultrasonic sensors (2); and a discharge position calculation unit (8) for calculating, from the results of calculating the detection time difference, the generation position of partial discharge generated inside the electric apparatus (900). The present invention is configured so that either a method for reading a first peak or a cross-correlation method can be selected as a method used for calculating the detection time difference.
This spatial optical communication transceiver comprises: a light source (1101) that generates laser light; an optical modulator (1102) that superimposes a communication signal on the laser light generated by the light source (1101); an OHPA (1103) that amplifies the laser light after superimposition by the optical modulator (1102); a collimator (1105) that includes a fiber connector (11051) and a collimator lens (11052), converts the laser light after amplification by the OHPA (1103) into spatial light, and emits transmission light, which is the spatial light; an optical telescope (1108) that expands the beam width of the transmission light emitted by the collimator (1105) and emits the same onto a spatial transmission path; a drive mechanism (1112) capable of adjusting the focal length of the collimator lens (11052); and a drive controller (1113) that determines a drive amount of the drive mechanism (1112) such that the product of a free space loss calculated from the distance between the host device and a communication partner spatial optical communication transceiver (11) and a transmission gain determined by a beam divergence angle of the transmission light is constant.
This arrangement work assistance device (100) is provided with an evaluation value calculation unit (160) and an arrangement pattern presentation unit (170). The evaluation value calculation unit (160) calculates a plurality of evaluation values on the basis of a work result stored in advance for each worker for each of arrangement patterns for arranging a plurality of workers in a production line along which the workers each perform given works to produce products. The arrangement pattern presentation unit (170) associates the arrangement patterns with the calculated evaluation values and presents the associated result to the user.
Provided is a semiconductor device in which pores generated in a junction between an electrode and an object to be joined are reduced. The semiconductor device includes a first electrode, a plurality of granular materials, and a second electrode. The first electrode is provided on a semiconductor substrate. The plurality of granular materials is formed on the first electrode. The second electrode is provided on the first electrode on which the plurality of granular materials is formed. The surface of the second electrode includes an uneven portion. The uneven portion is formed in accordance with the plurality of granular materials on the first electrode, which is the base of the second electrode.
This metal deposition modeling apparatus (100) is provided with: a powder container (16) that retains a metal powder (25); a modeling plate (19) that is disposed in a modeling region (11) which is irradiated with an electron beam; and a squeegee (13) that moves the metal powder (25) supplied from the powder container (16) to the modeling plate (19) and evenly spreads the metal powder (25) so as to form a powder bed (12). This metal deposition modeling apparatus (100) forms a three-dimensional model by irradiating the metal powder (25) in the modeling region (11) with an electron beam, and melting and solidifying the metal powder (25). An oxide film removal part for removing an oxide film on the surface of the metal powder (25) by applying a kinetic energy to the metal powder (25) is provided in the flow path of the metal powder (25) from the outlet of the powder container (16) to the squeegee (13).
B22F 10/28 - Powder bed fusion, e.g. selective laser melting [SLM] or electron beam melting [EBM]
B22F 12/58 - Means for feeding of material, e.g. heads for changing the material composition, e.g. by mixing
B33Y 30/00 - ADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING - Details thereof or accessories therefor
89.
SYSTEMS AND METHODS FOR DECISION MAKING FOR AUTONOMOUS VEHICLES
A control system for controlling a motion of an ego-vehicle traveling to a target destination is provided. The control system includes a memory and a processor to execute instruction stored by the memory. The memory stores multiple trajectory-generating functions corresponding to a maneuver defined by a parameter vector associated with a driving decision. The parameter vector is defined by one or multiple parameters. Each of the multiple trajectory-generating functions is configured to generate an achieving sequence of regions of states and values of the parameter vector reaching an input target region within a prediction horizon. The stored instructions cause the control system to test control admissibility of at least some of the driving decisions consistent with the target destination of the ego-vehicle at a current state. The stored instruction also caused the control system to control the ego-vehicle according to one of the admissible driving decisions.
The present invention provides a visualization result display control device comprising a display control unit (55) that carries out display control to display a first similar portion superimpose display (V521) and a second similar portion superimpose display (V522) side by side, the first similar portion superimpose display having a misclassified sample (D211), which is a sample that has been misclassified into a certain prediction class by an object detection model, onto which is superimposed a first display (D661) visualizing a first similar portion, of the misclassified sample, that is similar to an extracted sample (D251), which is a sample with features similar to the misclassified sample, and the second similar portion superimpose display having the extracted sample onto which is superimposed a second display (D662) visualizing a second similar portion, of the extracted sample, that is similar to the misclassified sample.
Provided is a radar device in which a trigger signal distribution circuit (30) distributes a trigger signal from a transmission/reception module (10M) of a master module system (100) to the transmission/reception module (10M) of the master module system (100) and a transmission/reception module (20M) of a plurality of sub-module systems (200) via respectively different trigger signal cables (41), (42), and outputs a reference signal from the transmission/reception module (10M) of the master module system (100) to the transmission/reception module (20M) of the plurality of sub-module systems (200). In the transmission/reception module (20M) of the plurality of sub-module systems (200), target parameters, which are obtained by performing FFT processing on a beat signal obtained from a high-frequency chirp signal of a transmitted RF signal in a correspondence relationship with a high-frequency chirp signal of a received RF signal due to a reflected wave received by a receiving antenna (20R), are corrected by a timing deviation obtained from the beat frequency of a received beat signal, which is obtained by performing complex FFT processing on a beat signal that has been I/Q separated using the received RF signal.
G01S 13/34 - Systems for measuring distance only using transmission of continuous waves, whether amplitude-, frequency-, or phase-modulated, or unmodulated using transmission of continuous, frequency-modulated waves while heterodyning the received signal, or a signal derived therefrom, with a locally-generated signal related to the contemporaneously transmitted signal
92.
RADIO WAVE SHIELDING STRUCTURE AND CHASSIS DYNAMOMETER SYSTEM
This radio wave shielding structure (1) is provided with: a conductive flat belt (3) which is wound around a pair of rollers (2) arranged in parallel under the surface of a metal floor (103), and on which tires (101 and 102) of a vehicle (100) are placed so as to be exposed from an opening (104) formed in the metal floor (103); and a conductive radio wave shielding roller (4) which is disposed between the metal floor (103) and the flat belt (3) in the opening (104), which is electrically connected to the metal floor (103), and which touches the flat belt (3) and rotates together with the movement of the flat belt (3).
A stationary induction apparatus (100) is provided with a winding (120) that is covered by first insulating paper (1), a thermometer (192), a heating unit (193), second insulating paper (2), and a control unit (190). The thermometer (192) measures a temperature of or around the winding (120). The heating unit (193) is connected to a power supply system different from that of the winding (120). The second insulating paper is heated by the heating unit (193). The control unit (190) is electrically connected to each of the thermometer (192) and the heating unit (193). The control unit (190) adjusts the value of a current flowing to the heating unit (193) such that a temperature of or around the second insulating paper (2) is equal to a measurement of the thermometer (192).
H01F 27/00 - MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES - Details of transformers or inductances, in general
94.
CONGESTION DEGREE MEASUREMENT DEVICE, CONGESTION DEGREE MEASUREMENT SYSTEM, CONGESTION DEGREE MEASUREMENT METHOD, AND CONGESTION DEGREE MEASUREMENT PROGRAM
A congestion degree measurement device (1) includes: a data reception unit (10) that receives wireless data based on wireless signals received by one or more wireless sensors (Sen#1 to Sen#I) at a location (9) set for receiving visitors (Gst#1 to Gst#Z); a visitor count calculation unit (20) that, on the basis of wireless data, or on the basis of permanently installed wireless terminal information acquired as information relating to the wireless data and to permanently installed wireless terminals (Dev#1 to Dev#X) for transmitting wireless signals, calculates a mobile wireless terminal count, which is the number of mobile wireless terminals (Mob#1 to Mob#Y) that are carried by the visitors (Gst#1 to Gst#Z) present at the location (9) and that transmit wireless signals, and calculates a visitor count, which is the number of visitors (Gst#1 to Gst#Z), from the mobile wireless terminal count; and a congestion degree calculation unit (30) that, on the basis of the visitor count, calculates a congestion degree indicating the degree of congestion by the visitors (Gst#1 to Gst#Z) at the location (9).
A modulation unit converts a transmission bit sequence into a data symbol sequence by modulating the transmission bit sequence. A spreading unit directly performs spread spectrum processing on the modulated data symbol sequence using a spreading code to generate a spread signal. A waveform shaping unit up-samples the spread signal and band-limits a transmission spectrum. A frequency conversion unit convers the band-limited spread signal into a plurality of arbitrary carrier frequencies to generate spread signals of the plurality of carrier frequencies. A weighting unit has a plurality of weight coefficients that have different amplitudes for the respective spread signals of the plurality of carrier frequencies, and that vary in amplitude according to samples of the spread signals of the plurality of carrier frequencies, multiplies all samples of the spread signals of the plurality of carrier frequencies by the weight coefficients corresponding thereto, respectively, and generates weighted signals of the spread signals of the plurality of carrier frequencies. A channel synthesis unit adds the weighted signals of the spread signals of the plurality of carrier frequencies to generate a synthesized signal of the spread signals of the plurality of carrier frequencies.
A wireless communication device (1) for transmitting data on the basis of a routing table is provided with a transmission processing unit (31) that determines which of unicast transmission and broadcast transmission is to be executed on the basis of the presence or absence of the routing table and the registration status of the destination of data to be transmitted on the routing table, and transmits the data to be transmitted by a transmission method corresponding to a determination result.
H04W 40/00 - Communication routing or communication path finding
H04W 16/26 - Cell enhancers, e.g. for tunnels or building shadow
H04W 40/26 - Connectivity information management, e.g. connectivity discovery or connectivity update for hybrid routing by combining proactive and reactive routing
H04W 84/18 - Self-organising networks, e.g. ad hoc networks or sensor networks
H04W 88/04 - Terminal devices adapted for relaying to or from another terminal or user
This sensing system comprises: a detection data storage unit that stores detection data detected by a household electrical appliance installed in a building to be sensed, a detection time for the detection data, and appliance identification information for identifying the household electrical appliance, the storing being done such that the detection data, the detection time, and the appliance identification information are associated with each other; a determination standard storage unit that stores a determination standard for determining whether a person is present in the building in accordance with the detection data; and a determination processing unit that, if predetermined specific communication has been received, determines whether a person is present in the building on the basis of the determination standard stored by the determination standard storage unit and the detection data that is stored by the detection data storage unit and pertains to a determination period based on a reception time at which the specific communication was received.
A control device (3) comprises: a trained model storage unit (26) for storing a plurality of trained models that are the result of learning a relationship between feature quantities representing the state of processing performed by a processing machine and the state of processing performed by the processing machine; a processing state evaluation unit (23) that evaluates the state of processing performed by the processing machine by inputting feature quantities into each of the plurality of trained models, or by inputting feature quantities into a combinations of the trained models; a monitoring model determination unit (24) that determines, on the basis of the result of evaluating the processing state by observing a workpiece processed by the processing machine and the result of evaluation by the processing state evaluation unit (23), a trained model or a combination of trained models serving as a monitoring model for use in monitoring the state of processing performed by the processing machine; and a processing control unit (28) that controls the processing machine on the basis of the result of monitoring the state of processing performed by the processing machine using the monitoring model.
A PLC (10) comprises: a storage unit (100) that includes a master region (M) and a plurality of user regions (U) corresponding to a plurality of users; a user authentication unit (102) that authenticates each of the plurality of users; and a version management unit (103) that saves a first dataset created by a user authenticated by the user authentication unit (102) in the storage unit (100) and carries out version management. The version management unit (103) stores the first dataset in the master region (M), or in a user region (U) corresponding to the user authenticated by the user authentication unit (102) from among the plurality of user regions (U), in association with a second dataset that is already saved in the storage unit (100), the second dataset being an immediate parent to the first dataset.
G06F 21/57 - Certifying or maintaining trusted computer platforms, e.g. secure boots or power-downs, version controls, system software checks, secure updates or assessing vulnerabilities
100.
OUTDOOR UNIT AND REFRIGERATION CYCLE DEVICE PROVIDED WITH SAID OUTDOOR UNIT
This outdoor unit comprises: a heat exchanger provided with a plurality of heat transfer pipes extending in a vertical direction, a communication part via which lower ends of adjacent heat transfer pipes among the plurality of heat transfer pipes communicate with each other, and fins provided in a region above a first position separated upward from the lower ends of the plurality of heat transfer pipes; and a lower cover provided with a body part, at least two connection parts protruding downward from the lower end of the body part, and an opening provided between the at least two connection parts. The lower cover is disposed facing a region between the communication part and the first position, and the opening is disposed at a position facing a space below the communication part.