Abstract: A signal detection circuit includes: a power terminal; a first current limitation circuit; a second current limitation circuit; a current-voltage conversion circuit; a first p-channel MOS transistor including a source, a gat, and a drain; a first n-channel MOS transistor including a drain, a gate, and a source; and a second n-channel MOS transistor in which a drain is connected to a first connection point connecting the resistor with the drain of the first n-channel MOS transistor, a gate is connected to a second connection point connecting the drain of the first p-channel MOS transistor with the current-voltage conversion circuit, and a source is grounded.

Abstract: This remaining stored power amount estimation device 3 includes: sensors 5, 6 for observing the state of the storage battery 2; and a remaining amount estimation unit 15 which, on the basis of a state vector xk representing the state of the storage battery 2 by a plurality of elements included in an equivalent circuit model 20 modeling the storage battery 2, and an observation vector yk representing an observed value based on the observation result, updates the state of the storage battery 2, using a Kalman filter, and estimates the SOC of the storage battery 2. The remaining amount estimation unit 15 changes the internal impedance of the storage battery 2 modeled by the equivalent circuit model 20, in accordance with values influencing the internal impedance.

Abstract: A bidirectional insulated DC/DC converter includes a first single-phase 3-level inverter, a second single-phase 3-level inverter, and an insulated transformer. The first single-phase 3-level inverter generates a first AC voltage between output terminals based on a first DC voltage received from a first DC circuit. The second single-phase 3-level inverter generates a second AC voltage between output terminals based on a second DC voltage received from a second DC circuit. The insulated transformer includes a primary winding that receives the first AC voltage from the output terminals and a secondary winding that receives the second AC voltage from the output terminals.

Abstract: This replacement necessity assessment apparatus for an absorbent member includes: a power generator which is configured to generate power as a result of contact with liquid absorbed in the absorbent member, and of which power generation amount changes in accordance with an amount of the liquid; a signal output unit configured to output a detection signal according to the power generation amount; and a processing unit configured to acquire a parameter regarding the amount of the liquid based on the detection signal, the processing unit configured to determine, based on the parameter, whether or not replacement of the absorbent member is necessary.

Abstract: In an in-vivo signal source detection method, three electrodes are arranged on the circumference of a surface of an living body to surround multiple muscle fibers; a first voltage Vi generated when a first external resistor is connected to between each electrode and a ground potential and a second voltage V?i generated when a second external resistor is connected to between each electrode and the ground potential; and a ratio Vi/V?i is calculated from the first voltage Vi and the second voltage V?i, and the position of a signal source in the living body is detected based on three ratios Vi/V?i.

Abstract: A solid-state imaging device having a pixel portion in which a plurality of pixels each including a photodiode are arranged in rows and columns, a reading part for reading pixel signals from the pixel portion, and a key generation part which generates a unique key by using, as the key generation-use data, at least one of fluctuation information of pixels and fluctuation information of the reading part, wherein the key generation part includes a tamper resistance enhancement processing part for processing the key generation-use data to enhance the tamper resistance making it difficult to break the unique key as tamper resistance enhancement processing. Due to this, it is possible to generate a unique key having a high confidentiality. Further, it is possible to improve reproducibility and uniqueness of the unique ID, is possible to secure a high tamper resistance of the unique key, and consequently is possible to reliably prevent tampering and forgery of an image.

Abstract: A power source device has: a storage unit configured to receive a generated power and store as a storage power; a boost unit configured to generate, from a storage power supplied from the storage unit, a boosted power having a higher voltage than a voltage of the storage power, and supply the boosted power to a load; and a voltage detection unit configured to output a boost operation permission signal permitting a boost operation of the boost unit to the boost unit when the storage voltage of the boost unit increases to become a voltage equal to or higher than a minimum operation voltage of the boost unit. The boost unit is configured to start the boost operation by the storage power supplied from the storage unit and operates on the boosted power generated by the boost operation as an operation power source when the boost operation permission signal is output from the voltage detection unit.

Abstract: A solid-state imaging device 10 includes a pixel portion 20 in which a plurality of pixels including photodiodes are arranged in rows and columns, a reading part 90 for reading pixel signals from the pixel portion, and a key generation part 82 which generates a unique key by using at least one of pixel fluctuation information or reading part fluctuation information. According to this configuration, the tamper resistance of the unique key can be secured and consequently alteration and falsification of images can be prevented.

Abstract: A solid-state imaging device having a pixel portion in which a plurality of pixels each including a photodiode are arranged in rows and columns, a reading part for reading pixel signals from the pixel portion, and a key generation part which generates a unique key by using, as the key generation-use data, at least one of fluctuation information of pixels and fluctuation information of the reading part, wherein the key generation part includes a tamper resistance enhancement processing part for processing the key generation-use data to enhance the tamper resistance making it difficult to break the unique key as tamper resistance enhancement processing. Due to this, it is possible to generate a unique key having a high confidentiality. Further, it is possible to improve reproducibility and uniqueness of the unique ID, is possible to secure a high tamper resistance of the unique key, and consequently is possible to reliably prevent tampering and forgery of an image.

Abstract: A solid-state imaging device having a pixel portion in which a plurality of pixels each including a photodiode are arranged in rows and columns, a reading part for reading pixel signals from the pixel portion, and a key generation part which generates a unique key by using, as the key generation-use data, at least one of fluctuation information of pixels and fluctuation information of the reading part, wherein the key generation part includes a tamper resistance enhancement processing part for processing the key generation-use data to enhance the tamper resistance making it difficult to break the unique key as tamper resistance enhancement processing. Due to this, a unique key having a high confidentiality can be generated. Further, reproducibility and uniqueness of the unique ID can be improved to secure a high tamper resistance of the unique key, and tampering and forgery of an image can be reliably prevented.

Abstract: A power source device includes a storage capacitor, a voltage detection circuit, input terminals, and output terminals, further includes: a boost circuit which converts a storage power provided to the input terminals to a boosted power under the condition that a stored voltage becomes equal to or greater than the predetermined voltage, and outputs the boosted power from the output terminals; and a MOS transistor which controls a supply of the boosted power to a load. One of the input terminals is connected to a gate terminal of the MOS transistor, and one of the output terminals is connected to a source terminal of the MOS transistor. The MOS transistor turns on to convert the storage power to the boosted power in the boost circuit, while the MOS transistor turns off not to convert the storage power to the boosted power in the boost circuit.

Abstract: A bidirectional insulated DC/DC converter (1) includes a first single-phase 3-level inverter (INV-A), a second single-phase 3-level inverter (INV-B), and an insulated transformer (3). The first single-phase 3-level inverter (INV-A) generates a first AC voltage (VA) between output terminals (1a, 1b) based on a first DC voltage received from a first DC circuit (5). The second single-phase 3-level inverter (INV-B) generates a second AC voltage (VB) between output terminals (2a, 2b) based on a second DC voltage received from a second DC circuit (6). The insulated transformer (3) includes a primary winding (3a) that receives the first AC voltage (VA) from the output terminals (1a, 1b) and a secondary winding (3b) that receives the second AC voltage (VB) from the output terminals (2a, 2b).

Abstract: This remaining stored power amount estimation device 3 includes: sensors 5, 6 for observing the state of the storage battery 2; and a remaining amount estimation unit 15 which, on the basis of a state vector xk representing the state of the storage battery 2 by a plurality of elements included in an equivalent circuit model 20 modeling the storage battery 2, and an observation vector yk representing an observed value based on the observation result, updates the state of the storage battery 2, using a Kalman filter, and estimates the SOC of the storage battery 2. The remaining amount estimation unit 15 changes the internal impedance of the storage battery 2 modeled by the equivalent circuit model 20, in accordance with values influencing the internal impedance.

Abstract: A supporter according to the present invention includes a first supporting section provided so as to extend along a lateral side of a knee joint, a second supporting section extending diagonally upwardly from a first long side along an upper edge of a kneecap so as to reach a second long side, and a third supporting section extending diagonally downwardly from the first long side along a lower edge of the kneecap so as to reach the second long side.

Abstract: A method for detecting a position of a signal source in a living body includes: arranging three electrodes on a surface of the living body and alternately connecting a first external resistance and a second external resistance in parallel between the electrodes and a ground potential; measuring first voltages Vi (i=1, 2, 3) generated at the respective electrodes when the first external resistance is connected in parallel between the electrodes and the ground potential, and second voltages Vi (i=1, 2, 3) generated at the respective electrodes when the second external resistance is connected in parallel between the electrodes and the ground potential; and calculating three ratios Vi/V?i (i=1, 2, 3) from the first and second voltages Vi and V?i, and detecting the position of the signal source in the living body based on the three ratios Vi/V?i (i=1, 2, 3).

Abstract: Provided is a cell culture apparatus capable of constructing cultured cells under an environment closer to that in a living body. The cell culture apparatus includes: a culture substrate (11) having a culture surface (11a) on which cells S are cultured; and a drive unit (12) configured to allow opening and closing of the culture substrate (11) between a closed form and an open form. The closed form is a form in which the culture substrate (11) forms a flow path having an internal volume with the culture surface (11) being an internal surface of the flow path. The open form is a form in which the culture surface (11a) of the culture substrate (11) is opened outward more than the culture surface (11a) of the culture substrate (11) in the closed form.

Abstract: A power source device has: a storage unit configured to receive a generated power and store as a storage power; a boost unit configured to generate, from a storage power supplied from the storage unit, a boosted power having a higher voltage than a voltage of the storage power, and supply the boosted power to a load; and a voltage detection unit configured to output a boost operation permission signal permitting a boost operation of the boost unit to the boost unit when the storage voltage of the boost unit increases to become a voltage equal to or higher than a minimum operation voltage of the boost unit. The boost unit is configured to start the boost operation by the storage power supplied from the storage unit and operates on the boosted power generated by the boost operation as an operation power source when the boost operation permission signal is output from the voltage detection unit.

Abstract: A bidirectional insulated DC/DC converter narrows a pulse width of an AC fundamental wave voltage corresponding to a higher DC voltage of two DC voltages, to cause effective values of the AC fundamental wave voltages to coincide with each other, and then, sets a phase difference between the AC fundamental wave voltages in accordance with a value and a direction of a current that is desired to flow. Accordingly, even when the difference between the two DC voltages greatly varies, DC power can be stably transmitted and received.

Abstract: A solid-state imaging device having a pixel portion in which a plurality of pixels each including a photodiode are arranged in rows and columns, a reading part for reading pixel signals from the pixel portion, and a key generation part which generates a unique key by using, as the key generation-use data, at least one of fluctuation information of pixels and fluctuation information of the reading part, wherein the key generation part includes a tamper resistance enhancement processing part for processing the key generation-use data to enhance the tamper resistance making it difficult to break the unique key as tamper resistance enhancement processing. Due to this, a unique key having a high confidentiality can be generated. Further, reproducibility and uniqueness of the unique ID can be improved to secure a high tamper resistance of the unique key, and tampering and forgery of an image can be reliably prevented.

Abstract: A solid-state imaging device 10 includes a pixel portion 20 in which a plurality of pixels including photodiodes are arranged in rows and columns, a reading part 90 for reading pixel signals from the pixel portion, and a key generation part 82 which generates a unique key by using at least one of pixel fluctuation information or reading part fluctuation information. According to this configuration, the tamper resistance of the unique key can be secured and consequently alteration and falsification of images can be prevented.