Abstract: A neuromuscular disease evaluation device that is less invasive, highly sensitive, quantitative and objective, and capable of easily evaluating neuromuscular diseases. A device for evaluating motor functions related to neuromuscular diseases, comprising: a memory unit storing a reference value for evaluating a predetermined movement, which is calculated based on a position of at least one body part; an analysis unit for identifying a position of a body part of the user by analyzing information based on an image captured of the predetermined movement, including the user's body; and an evaluation unit for evaluating the motor function based on the numerical value calculated based on the position of the body part of the user and the reference value.

Abstract: An object of the present invention is to stop the driving of a semiconductor element swiftly at a time of abnormality while sharing an output terminal between temperature information and an error signal in an IPM. In the intelligent power module of the present invention, each drive circuit includes an output control circuit configured to select the error signal while the error signal generation circuit outputs the error signal, to select the temperature signal while the error signal generation circuit does not output the error signal, and to output a selected signal as an alarm signal. The temperature signal generation circuit is configured to change the voltage value of the temperature signal in accordance with the element temperature of the specific semiconductor element within a voltage range different from the voltage value of the error signal.

Abstract: An object of the present invention is to stop the driving of a semiconductor element swiftly at a time of abnormality while sharing an output terminal between temperature information and an error signal in an IPM. In the intelligent power module of the present invention, each drive circuit includes an output control circuit configured to select the error signal while the error signal generation circuit outputs the error signal, to select the temperature signal while the error signal generation circuit does not output the error signal, and to output a selected signal as an alarm signal. The temperature signal generation circuit is configured to change the voltage value of the temperature signal in accordance with the element temperature of the specific semiconductor element within a voltage range different from the voltage value of the error signal.

Abstract: A power conversion system includes: a plurality of power modules connected in parallel to each other, a plurality of drive circuits driving the plurality of power modules based on input signals respectively; a plurality of correction sections correcting the input signals inputted to the plurality of drive circuits based on a plurality of correction values respectively; a temperature detection section detecting operating temperatures of the plurality of power modules; and a calculation section estimating current switching characteristics of the plurality of power modules based on the measured operating temperatures and temperature dependency of switching characteristics of the plurality of power modules, and calculating the plurality of correction values based on the estimated current switching characteristics so as to reduce variations of currents flowing through the plurality of power modules.

Abstract: A power conversion system includes: a plurality of power modules connected in parallel to each other; a plurality of drive circuits driving the plurality of power modules based on input signals respectively; a plurality of correction sections correcting the input signals inputted to the plurality of drive circuits based on a plurality of correction values respectively; a temperature detection section detecting operating temperatures of the plurality of power modules; and a calculation section estimating current switching characteristics of the plurality of power modules based on the measured operating temperatures and temperature dependency of switching characteristics of the plurality of power modules, and calculating the plurality of correction values based on the estimated current switching characteristics so as to reduce variations of currents flowing through the plurality of power modules.

Abstract: First and second external terminals are connected to high-voltage and low-voltage terminals, respectively, of a direct-current voltage source circuit in which first and second direct-current voltage sources are connected in series. A third external terminal is connected to a connecting point between the first and second direct-current voltage sources. A first switching element is connected between the first and fourth external terminals. A second switching element is connected between the fourth and second external terminals. A first AC switch unit includes third and fourth switching elements connected in inverse series between the third and fourth external terminals. A second AC switch unit includes fifth and sixth switching elements connected in inverse series between the third and fourth external terminals. The first and second AC switch units are connected in parallel. The first and second switching elements and the first and second AC switch units are incorporated in one module.

Abstract: First and second external terminals are connected to high-voltage and low-voltage terminals, respectively, of a direct-current voltage source circuit in which first and second direct-current voltage sources are connected in series. A third external terminal is connected to a connecting point between the first and second direct-current voltage sources. A first switching element is connected between the first and fourth external terminals. A second switching element is connected between the fourth and second external terminals. A first AC switch unit includes third and fourth switching elements connected in inverse series between the third and fourth external terminals. A second AC switch unit includes fifth and sixth switching elements connected in inverse series between the third and fourth external terminals. The first and second AC switch units are connected in parallel. The first and second switching elements and the first and second AC switch units are incorporated in one module.

Abstract: First and second external terminals are connected to high-voltage and low-voltage terminals, respectively, of a direct-current voltage source circuit in which first and second direct-current voltage sources are connected in series. A third external terminal is connected to a connecting point between the first and second direct-current voltage sources. A first switching element is connected between the first and fourth external terminals. A second switching element is connected between the fourth and second external terminals. A first AC switch unit includes third and fourth switching elements connected in inverse series between the third and fourth external terminals. A second AC switch unit includes fifth and sixth switching elements connected in inverse series between the third and fourth external terminals The first and second AC switch units are connected in parallel. The first and second switching elements and the first and second AC switch units are incorporated in one module.

Abstract: An optical sheet is incorporated in a direct type surface light source device including a light source and is configured to allow light emitted from the light source to exit after changing a travel direction of the light. The optical sheet has a light exiting side lens part including unit lenses juxtaposed to one another and each unit lens is convex toward a light exiting side. A light scattering layer, configured to scatter the light, is provided to each unit lens. The light scattering layer extends along a light exiting side surface of each convex unit lens and constitutes the light exiting side surface of the unit lens. A thickness of the light scattering layer around an apex portion of each unit lens is greater than the thickness of the light scattering layer around each end portion of the unit lens.

Abstract: An optical sheet is incorporated in a direct type surface light source device including a light source and is configured to allow light emitted from the light source to exit after changing a travel direction of the light. The optical sheet has a light exiting side lens part including unit lenses juxtaposed to one another and each unit lens is convex toward a light exiting side. A light scattering layer, configured to scatter the light, is provided to each unit lens. The light scattering layer extends along a light exiting side surface of each convex unit lens and constitutes the light exiting side surface of the unit lens. A thickness of the light scattering layer around an apex portion of each unit lens is greater than the thickness of the light scattering layer around each end portion of the unit lens.