Abstract: A cell supervising circuit includes: a measurement circuit which measures a state of charge of a secondary battery cell; a transformer which is provided for the measurement circuit to contactlessly receive power supply from a power source different from the secondary battery cell; and a communication circuit which transmits, via the transformer to a BMU which manages a status of a battery pack, the state of charge measured by the measurement circuit.

Abstract: A BMS includes cell supervising circuits connected to an alternating current power line via a transformer, and a BMU connected to the alternating current power line via a transformer. The BMU includes a control microcomputer which instructs at least one of the cell supervising circuits to control the state of charge of a secondary battery cell monitored by the at least one of the cell supervising circuits, based on pieces of information in the cell supervising circuits, the pieces of information indicating states of charge of secondary battery cells monitored by the cell supervising circuits.

Abstract: A battery monitoring device includes: a pair of terminals for measuring voltage or current of a battery, and to which a filter unit including a capacitive element is connected; an AD converter that measures a waveform of voltage between the terminals during charging or discharging of the capacitive element; and a time constant calculation unit that calculates a time constant of the filter unit based on the waveform measured. The AD converter is, for example, a first AD converter or a second AD converter. The filter unit is, for example, a first filter unit or a second filter unit.

Abstract: A battery monitoring device includes a first reference resistor disposed in a path different from a path of current flowing from a battery to a load; a transistor for passing current from the battery to the first reference resistor; and an integrated circuit. The integrated circuit includes: a current measurement unit that measures a first current flowing through the first reference resistor; a voltage measurement unit that measures a first voltage of the battery; and a first calculation unit that calculates an AC impedance of the battery based on the first current measured and the first voltage measured.

Abstract: An optimization device is applied to a production line in which multiple production devices respectively execute a production process. The optimization device includes a cycle time setting section configured to set a cycle time for each production device, a target time setting section configured to set a target time based on a cycle time and a time required for periodic operation in each of multiple production devices except for the component mounter, and a line design section configured to calculate the unit number of the component mounters constituting the production line based on the target time.

Abstract: A semiconductor device includes a first semiconductor layer having a first surface and a second surface. A first metal film is disposed on the first surface. An outer portion of the first surface beyond an outer periphery of the first metal film is left uncovered by the first metal film. A semiconductor substrate has an inner region of a first thickness and a peripheral region of a second thickness, greater than the first thickness. A portion of the first semiconductor layer is between the inner region and the first metal layer. The peripheral region of the semiconductor substrate is below the outer portion of the first surface of the first semiconductor layer. A second metal film is below the inner region of the semiconductor substrate and adjacent to the peripheral region of the semiconductor substrate.

Abstract: Provided is a method for producing a negative electrode for an electric storage device, the method comprising the steps of preparing a negative electrode composition comprising a negative electrode active material that reversibly carries a sodium ion, metal sodium, and a liquid dispersion medium for dispersing them; allowing a negative electrode current collector to hold the negative electrode composition; evaporating at least part of the liquid dispersion medium from the negative electrode composition held by the negative electrode current collector, thereby giving a negative electrode precursor comprising the negative electrode active material, the metal sodium, and the negative electrode current collector; and bringing the negative electrode precursor into contact with an electrolyte having sodium ion conductivity, thereby doping the negative electrode active material with sodium eluted from the metal sodium.

Abstract: The information processing device is a device used in a mounting system configured as a production line including a mounting device configured to mount components on a board. The information processing device comprises: a control section configured to obtain the operator workload to be performed within a time block between a first point-in-time and a second point-in-time based on correspondence information linking work content and operator working time required for the work content, and the production job of the production line; create a workload table linking the time block and the workload; and output the created workload table.

Abstract: A paper sheet bundling apparatus includes: a reel unit, in which a tape roll is set, configured to rotate the tape roll in a direction in which the tape is fed, and a direction in which the tape is wound; a tape transport unit, having a transport path provided between the reel unit and a tape bundling unit, configured to transport the tape, along the transport path, to supply the tape to the tape bundling unit when the tape bundling unit performs bundling, and to cause, when the tape bundling unit does not perform bundling, the tape to be in a stand-by state in which the tape is arranged continuously along the transport path; and specific operation execution means for executing, at a predetermined time, a specific operation of reducing tensile force in the tape arranged continuously along the transport path, when the tape bundling unit does not perform bundling.

Abstract: There are provided a plurality of first ADCs that respectively have voltages of a plurality of power storage cells of a power storage module as inputs. There are provided first reference voltage portions that are provided to respectively correspond to the first ADCs and supply reference voltages VRn used as a criterion for a conversion operation. A selector selects any one of the reference voltages VRn and supplies the selected reference voltage to a second ADC. A voltage value corrector corrects a voltage value of the power storage cell obtained by a voltage value acquirer on the basis of correction data obtained by using a digital signal output from the second ADC.

Abstract: An optimization device of a component mounting line of the present invention includes a cycle time calculating section which calculates respective cycle times required for mounting components of component types which are allocated to each of the component mounting machines by the optimization process onto a single board, an excluded machine setting section which sets a specific portion of the component mounting machines to be excluded from further calculation processes, a balance efficiency calculating section which calculates a line balance efficiency indicating a degree to which the cycle times of the component mounting machines which are not excluded are equalized, and a balance efficiency display section which displays the line balance efficiency. Accordingly, the results of the optimization process which is carried out before starting production of the board are evaluated appropriately and the original device performance of the component mounting line can be utilized.

Abstract: Disclosed herein is a banknote handling apparatus 100 functioning as a paper sheet bundling device configured to bundle stacked banknotes with a tape T. The apparatus includes bundling stackers 4, 4 configured to bundle the banknotes, a tape loop forming unit 92 configured to form a small tape loop L1 from the tape T and then feed the tape T to enlarge the small tape loop L1 into a large tape loop L2, and a second transport unit 8 configured to grip the banknotes stacked in the bundling stackers 4 to transport the banknotes into the large tape loop L2.

Abstract: A work management device includes an operator information memory section, a work item memory section, an operator detection sections, and a work instruction section. The operator detection sections are installed at a plurality of spots of the electronic component mounting line and detect the operators near the spots. In a case in which the operator detection section detects the operator, when operator information regarding the operator is identical to operator information in the operator information memory section and the work item group of the work item memory section includes one work item or a plurality of work items which are able to be performed by the operator detected by the operator detection section, the work instruction section instructs the operator detected by the operator detection section in one work item or a plurality of work items selected from the one work item or the plurality of work items.

Abstract: Provided is control apparatus for an electric vehicle, which is capable of suppressing simultaneous slip of front and rear wheels. The control apparatus for an electric vehicle controls a front electric motor and a rear electric motor so that a difference between a torque command value of the front electric motor and a torque command value of the rear electric motor is larger than a predetermined value.

Abstract: A work management device manages a board work line having multiple board work machines for performing work on a board. The work management device includes a problem detection section configured to detect that a problem has occurred in any of the multiple board work machines; a handling method database configured to accumulate handling methods for problems; an updating section configured to update handling methods for problems at any time; and a work instruction section configured to extract and indicate to an operator a handling method for a problem from the handling method database when the problem detection section detects that the problem has occurred.

Abstract: An optimization device is applied to a production line in which multiple production devices respectively execute a production process. The optimization device includes a cycle time setting section configured to set a cycle time for each production device, a target time setting section configured to set a target time based on a cycle time and a time required for periodic operation in each of multiple production devices except for the component mounter, and a line design section configured to calculate the unit number of the component mounters constituting the production line based on the target time.

Abstract: Provided are a device for controlling an electric vehicle and a method of controlling an electric vehicle that are capable of appropriately suppressing a vibration. In the device for controlling an electric vehicle according to the present invention, when a motor configured to generate a torque for braking or driving a drive wheel is controlled based on a torque command value based on an accelerator operation or a brake operation by a driver and a vibration suppression control torque command value for suppressing a vibration component caused by a resonance of the vehicle, the vibration suppression control torque command value is restricted based on a state of the drive wheel during a travel.

Abstract: Provided is a control apparatus for an electric vehicle, which is capable of suppressing simultaneous slip of front and rear wheels. The control apparatus for an electric vehicle includes a control portion configured to control a front electric motor and a rear electric motor so that an achievement rate of a torque command with respect to a target torque in one motor of the front and rear electric motors is lower than the achievement rate in the other motor of the front and rear electric motors.

Abstract: A semiconductor device of an embodiment includes a nitride semiconductor layer, a source electrode provided in a first region and a second region on the nitride semiconductor layer, a drain electrode provided in the first region and the second region, an insulating film provided in the first region and the second region between the source electrode and the drain electrode, and a gate electrode provided in the first region and the second region on the nitride semiconductor layer between the source electrode and the drain electrode. A first distance between the source electrode and the drain electrode in a gate length direction of the first region is shorter than a second distance between the source electrode and the drain electrode in a gate length direction of the second region. A first length of the insulating film in the gate length direction of the first region is shorter than a second length of the insulating film in the gate length direction of the second region.

Abstract: Provided is a method for producing a negative electrode for an electric storage device, the method comprising the steps of: preparing a negative electrode composition comprising a negative electrode active material that reversibly carries a sodium ion, metal sodium, and a liquid dispersion medium for dispersing them; allowing a negative electrode current collector to hold the negative electrode composition; evaporating at least part of the liquid dispersion medium from the negative electrode composition held by the negative electrode current collector, thereby giving a negative electrode precursor comprising the negative electrode active material, the metal sodium, and the negative electrode current collector; and bringing the negative electrode precursor into contact with an electrolyte having sodium ion conductivity, thereby doping the negative electrode active material with sodium eluted from the metal sodium.