Abstract: A capacitive gas sensor in which a second electrode layer made of a nano-carbon material entangled to be three-dimensionally reticulated and a gas-sensitive film are not separated from each other. A capacitive gas sensor includes a substrate; a first electrode layer formed on the substrate; a gas-sensitive film formed on the first electrode layer and having air permeability; and a second electrode layer formed on the gas-sensitive film to be opposed to the first electrode layer and made of a nano-carbon material entangled to be three-dimensionally reticulated. The capacitive gas sensor also includes a reinforcing resin layer having air permeability and disposed at least on the second electrode layer.

Abstract: A piezoelectric sounding element includes a diaphragm made of metal and a piezoelectric element provided on at least one surface of the diaphragm. A non-fixed portion of the diaphragm includes the pair of long sides facing each other, a pair of short sides, shorter than the long sides, that face each other, and a pair of recesses, provided in the pair of long sides, that protrude so as to approach each other. The piezoelectric element is provided in a region between the pair of recesses of the diaphragm and the contour shapes of the non-fixed portion of the diaphragm and the piezoelectric element are defined so as to be symmetric with respect to a first imaginary line that bisects the pair of short sides and symmetric with respect to a second imaginary line that bisects the pair of long sides.

Abstract: A pressure sensor device with good temperature characteristics. An auxiliary fluid introduction path is provided in a bottom wall portion of a first case to introduce a fluid to the vicinity of a recessed portion of the bottom wall portion where an integrated circuit with a large change in temperature characteristics is mounted such that the temperature of the integrated circuit becomes the same as or close to the temperature of the fluid.

Abstract: A semiconductor pressure sensor device in which the shape or the structure of a connector portion can be easily changed and which has high waterproof performance. A terminal housing and a second case are engaged with each other via an engagement structure. The terminal housing and a first case are fitted with each other via a fitting structure. Thus, the first case and the second case are fixed to each other via the terminal housing. The first case is fitted in the second case. Then, the terminal housing is fitted with the first case, and the terminal housing is engaged with the second case substantially at the same time. Through such simple process, an opening portion of the first case is covered and a connector portion configured to enable external terminals to be connected to ends, located on one side, of a plurality of lead terminals is formed.

Abstract: A force detector capable of preventing short-circuit fault between electrodes and allowing for downsizing. A prescribed region encompasses a projection region defined by projecting a deformation region of a force sensor element, which is deformed when a force transmission member applies a force to the force sensor element, onto a base substrate. A plurality of terminals are provided by four soldering land electrodes formed, respectively, at four corners of the base substrate. The soldering land electrodes are shaped such that a portion of each soldering land electrode is located within the projection region to form a soldering portion.

Abstract: Provided herein is a vibration-type angular velocity sensor capable of improving detection precision of angular velocities around the Z axis and preventing detection precision of angular velocities around the X and Y axes from deteriorating. A weight 3 is columnar or conic. The outline of an outer peripheral portion of a diaphragm 1 has such shape that a straight portion ST is formed at each of four corner portions of a square. Four vibration exciting electrodes 11 are respectively located in four regions partitioned by a first imaginary line L1 and a second imaginary line L2. Four angular velocity sensing electrodes 13 are respectively located in four regions partitioned by a first imaginary diagonal line CL1 and a second imaginary diagonal line Cl2.

Abstract: A piezoelectric sound generating element capable of providing flatter and less fluctuated sound pressure frequency characteristics includes a diaphragm that is formed in a circular plate shape with a circular profile. A piezoelectric element is affixed to the side of a bottom wall portion of the diaphragm. The piezoelectric element has an asymmetric octagonal profile including a pair of long side portions opposing each other, a pair of short side portions opposing each other, and four connecting side portions.

Abstract: Provided herein are a gas sensor element in which deformation of a sensitive portion due to stress may be reduced and a method of manufacturing the gas sensor element. A base insulating layer 9 including a heater wiring pattern 19 is formed on a front surface 3A of a support 3. The base insulating layer 9 includes a fixed portion 15 fixed to the front surface 3A of the support 3, and a nonfixed portion 17 located over an opening portion 5. A cavity portion 7 having the opening portion 5 is formed in the support 3. An electrode wiring pattern 27 and a sensitive film 31 are formed over a central portion 21 of the nonfixed portion 17 of the base insulating layer 9. The nonfixed portion 17 includes the central portion 21 and a plurality of connecting portions 23 connecting the central portion 21 and the fixed portion 15. Four connecting portions 23 each include a base portion 33 and an extended portion 35.

Abstract: A piezoelectric sound generating element capable of providing flatter and less fluctuated sound pressure frequency characteristics includes a diaphragm that is formed in a circular plate shape with a circular profile. A piezoelectric element is affixed to the side of a bottom wall portion of the diaphragm. The piezoelectric element has an asymmetric octagonal profile including a pair of long side portions opposing each other, a pair of short side portions opposing each other, and four connecting side portions.

Abstract: Provided herein is a vibration-type angular velocity sensor capable of improving detection precision of angular velocities around the Z axis and preventing detection precision of angular velocities around the X and Y axes from deteriorating. A weight 3 is columnar or conic. The outline of an outer peripheral portion of a diaphragm 1 has such shape that a straight portion ST is formed at each of four corner portions of a square. Four vibration exciting electrodes 11 are respectively located in four regions partitioned by a first imaginary line L1 and a second imaginary line L2. Four angular velocity sensing electrodes 13 are respectively located in four regions partitioned by a first imaginary diagonal line CL1 and a second imaginary diagonal line Cl2.

Abstract: Provided herein are a display apparatus with a touch panel to which a piezoelectric actuator may readily be mounted, and a piezoelectric actuator used in such a display apparatus with a touch panel. A support structure for supporting a piezoelectric actuator 3 on a front surface of a circuit substrate 5 is constituted from a pair of electrically conductive support members 13A, 13B which are each formed of an electrically conductive foam. The piezoelectric actuator 3 may be mounted by locating the piezoelectric actuator 3 with the pair of electrically conductive support members 13A, 13B attached thereto in a predetermined position on the circuit substrate 5, and connecting the pair of electrically conductive support members 13A, 13B to the pair of output electrodes 5A, 5B of the circuit substrate 5.

Abstract: An X-axis acceleration level determining section determines whether an X-axis acceleration signal output from a three-axis acceleration sensor has a value equal to or more than a predetermined positive threshold level, a value equal to or less than a predetermined negative threshold level, a value between the positive threshold level and a level of 0, or a value between the level of 0 and the negative threshold level. A Y-axis acceleration level determining section also makes a similar determination for a Y-axis acceleration signal output from the three-axis acceleration sensor. An attitude determining section determines the rotated attitude of a device equipped with the three-axis acceleration sensor with respect to the Z axis based on results of determinations made by the X-axis acceleration level determining section and the Y-axis acceleration level determining section.

Abstract: A method of manufacturing a connector chip includes preparing a plate-like insulating substrate material with a plurality of through hole rows arranged therein; forming a plurality of first and second base layers on opposite surfaces of the insulating substrate material; forming insulating layers between each two adjoining first base layers and between each two adjoining second base layers; forming third base layers on the one side over edge portions of the first base layers, internal surfaces of the through holes, and edge portions of the second base layers; forming fourth base layers on the other side over edge portions of the first base layers, the internal surfaces of the through holes, and edge portions of the second base layers; cutting the insulating substrate material along a middle of each of the through hole rows; and forming one or more plated layers over the first to fourth base layers.

Abstract: Provided is a manufacturing method of a metal oxide semiconductor material for gas sensors by which an oxide precursor and noble metal colloid particles will not readily cohere in the manufacturing process. The manufacturing process implements a precursor solution synthesis step 1 of synthesizing an oxide precursor solution in which an oxide precursor is dispersed, a pH adjustment step 3 of adjusting the pH of the oxide precursor solution, a precursor-colloid dispersion preparation step 5 of preparing an oxide precursor-noble metal colloid dispersion in which the oxide precursor and the noble metal colloid are dispersed substantially uniformly, a purifying step 7 of purifying the oxide precursor-noble metal colloid dispersion to obtain a purified oxide precursor noble metal colloid dispersion, and a freeze-drying step 11 of freeze-drying an precipitate of the purified oxide precursor-noble metal colloid dispersion.

Abstract: A biaxial angular velocity sensor provided herein has good detection sensitivity and allows an oscillator to be fixed stably. The biaxial angular velocity sensor includes an oscillator (3) made of a non-piezoelectric material, an electromechanical energy converting element (23) for driving and electromechanical energy converting element (25) for detection, both of which are provided in the oscillator (3), a plurality of drive electrodes (27) provided corresponding to the electromechanical energy converting element (23) for driving, and a plurality of detection electrodes (29) provided corresponding to the electromechanical energy converting element (25) for detection. The oscillator (3) includes a central portion (5) located in the center of the oscillator and eight first to eighth arm portions (7) to (21). The distal end portions of the fifth to eighth arm portions (15) to (21), located on the opposite side to the central portion (5), are fixed.

Abstract: Provided herein are a gas sensor element in which deformation of a sensitive portion due to stress may be reduced and a method of manufacturing the gas sensor element. A base insulating layer 9 including a heater wiring pattern 19 is formed on a front surface 3A of a support 3. The base insulating layer 9 includes a fixed portion 15 fixed to the front surface 3A of the support 3, and a nonfixed portion 17 located over an opening portion 5. A cavity portion 7 having the opening portion 5 is formed in the support 3. An electrode wiring pattern 27 and a sensitive film 31 are formed over a central portion 21 of the nonfixed portion 17 of the base insulating layer 9. The nonfixed portion 17 includes the central portion 21 and a plurality of connecting portions 23 connecting the central portion 21 and the fixed portion 15. Four connecting portions 23 each include a base portion 33 and an extended portion 35.

Abstract: An X-axis acceleration level determining section determines whether an X-axis acceleration signal output from a three-axis acceleration sensor has a value equal to or more than a predetermined positive threshold level, a value equal to or less than a predetermined negative threshold level, a value between the positive threshold level and a level of 0, or a value between the level of 0 and the negative threshold level. A Y-axis acceleration level determining section also makes a similar determination for a Y-axis acceleration signal output from the three-axis acceleration sensor. An attitude determining section determines the rotated attitude of a device equipped with the three-axis acceleration sensor with respect to the Z axis based on results of determinations made by the X-axis acceleration level determining section and the Y-axis acceleration level determining section.