Abstract: A MEMS sensor according to the present invention includes a base substrate including a displaceably supported movable portion and a lid substrate covering the movable portion and functioning as a magnetic sensor that detects magnetism by making use of the Hall effect.

Abstract: A photoelectric converter according to the present invention includes an insulating layer, a plurality of lower electrodes that are mutually spaced and disposed on the insulating layer, a photoabsorption layer made of a chalcopyrite compound semiconductor and formed to cover the plurality of lower electrodes all together, and a transparent conductive film formed to cover the photoabsorption layer. Variation of sensitivity among pixels due to influence (damage) by etching of the photoabsorption layer is thereby eliminated and a pixel aperture ratio can be made 100%.

Abstract: Provided is a method for manufacturing a probe card which inspects electrical characteristics of a plurality of semiconductor devices in batch. The method includes: a step of forming a plurality of probes, which are to be brought into contact with external terminals of the semiconductor devices, on one side of a board which forms the base body of the probe card; a step of forming on the board, by photolithography and etching, a plurality of through-holes which reach the probes from the other side of the board; a step of forming, in the through-holes, through electrodes to be conductively connected with the probes, respectively; and a step of forming wiring, which is conductively connected with the through electrodes, on the other side of the board.

Abstract: A capacitive pressure sensor includes a semiconductor substrate, a first insulating portion configured to define a sensor region, a reference pressure chamber configured to divide a lower portion of the sensor region in a direction, a second insulating portion configured to divide a surface portion of the sensor region above the reference pressure chamber in the direction, and a trench configured to divide the sensor region in the direction. The sensor region is divided into at least three semiconductor parts by the reference pressure chamber, the second insulating portion, and the trench.

Abstract: A capacitance type gyro sensor includes a semiconductor substrate, a first electrode integrally including a first base portion and first comb tooth portions and a second electrode integrally including a second base portion and second comb tooth portions, formed by processing the surface portion of the semiconductor substrate. The first electrode has first drive portions that extend from opposed portions opposed to the respective second comb tooth portions on the first base portion toward the respective second comb tooth portions. The second electrode has second drive portions formed on the tip end portions of the respective second comb tooth portions opposed to the respective first drive portions. The first drive portions and the second drive portions engage with each other at an interval like comb teeth.

Abstract: A capacitive pressure sensor includes: a semiconductor substrate having a reference pressure chamber formed therein; a diaphragm which is formed in a front surface of the semiconductor substrate and has a ring-like peripheral through hole penetrating between the front surface of the semiconductor substrate and the reference pressure chamber and defining an upper electrode and a plurality of central through holes; a peripheral insulating layer which fills the peripheral through hole and electrically isolates the upper electrode from other portions of the semiconductor substrate; and a central insulating layer which fills the central through holes.

Abstract: Provided is a method for manufacturing a probe card which inspects electrical characteristics of a plurality of semiconductor devices in batch. The method includes: a step of forming a plurality of probes, which are to be brought into contact with external terminals of the semiconductor devices, on one side of a board which forms the base body of the probe card; a step of forming on the board, by photolithography and etching, a plurality of through-holes which reach the probes from the other side of the board; a step of forming, in the through-holes, through electrodes to be conductively connected with the probes, respectively; and a step of forming wiring, which is conductively connected with the through electrodes, on the other side of the board.

Abstract: A semiconductor substrate of a semiconductor device has a sensor region and an integrated circuit region, and a cavity is formed immediately under a surface layer portion of the sensor region. A capacitive acceleration sensor is formed on the sensor region by working a surface layer portion of the semiconductor substrate opposed to the cavity. The capacitive acceleration sensor includes an interdigital fixed electrode and an interdigital movable electrode. A CMIS transistor is formed on the integrated circuit region. The CMIS transistor includes a P-type well region and an N-type well region formed on the surface layer portion of the semiconductor substrate. A gate electrode is opposed to the respective ones of the P-type well region and the N-type well region through a gate insulating film formed on a surface of the semiconductor substrate.

Abstract: A MEMS mirror device includes a semiconductor substrate, a mirror provided on the semiconductor substrate, a first cavity, a second cavity, and a frame portion to define the first cavity and the second cavity. The semiconductor substrate further includes a swing portion formed just above the first cavity to support the mirror, a straight beam provided just above the first cavity to extend between the frame portion and the swing portion, a comb-teeth-like fixed electrode, and a comb-teeth-like movable electrode, the movable electrode meshing with the fixed electrode with a gap left therebetween, the swing portion configured to swing about the beam as a swing axis in response to movement of the movable electrode.

Abstract: A capacitance type gyro sensor includes a semiconductor substrate, a first electrode integrally including a first base portion and first comb tooth portions and a second electrode integrally including a second base portion and second comb tooth portions, formed by processing the surface portion of the semiconductor substrate. The first electrode has first drive portions that extend from opposed portions opposed to the respective second comb tooth portions on the first base portion toward the respective second comb tooth portions. The second electrode has second drive portions formed on the tip end portions of the respective second comb tooth portions opposed to the respective first drive portions. The first drive portions and the second drive portions engage with each other at an interval like comb teeth.

Abstract: A capacitance type gyro sensor includes a semiconductor substrate, a first electrode integrally including a first base portion and first comb tooth portions and a second electrode integrally including a second base portion and second comb tooth portions, formed by processing the surface portion of the semiconductor substrate. The first electrode has first drive portions that extend from opposed portions opposed to the respective second comb tooth portions on the first base portion toward the respective second comb tooth portions. The second electrode has second drive portions formed on the tip end portions of the respective second comb tooth portions opposed to the respective first drive portions. The first drive portions and the second drive portions engage with each other at an interval like comb teeth.

Abstract: An infrared sensor according to the present invention includes a semiconductor substrate, a thin-film pyroelectric element made of lead titanate zirconate and disposed on the semiconductor substrate, a coating film coating the pyroelectric element and having a topmost surface that forms a light receiving surface for infrared rays, and a cavity formed to a shape dug in from a top surface of the semiconductor substrate at a portion opposite to the pyroelectric element and thermally isolates the pyroelectric element from the semiconductor substrate.

Abstract: An inkjet printer head includes: a semiconductor substrate; a vibration diaphragm provided on the semiconductor substrate and capable of vibrating in an opposing direction in which the vibration diaphragm is opposed to the semiconductor substrate; a piezoelectric element provided on the vibration diaphragm; a pressure chamber provided on a side of the vibration diaphragm adjacent to the semiconductor substrate as facing the vibration diaphragm, the pressure chamber being filled with an ink; and a nozzle extending through the vibration diaphragm and communicating with the pressure chamber for ejecting the ink supplied from the pressure chamber.

Abstract: The acceleration sensor according to the present invention includes a circuit chip having a prescribed circuit built into a front surface thereof; a sensor chip bonded to the front surface of the circuit chip; and a resin package for sealing the circuit chip and the sensor chip, while the sensor chip includes: a membrane arranged to oppose to the front surface of the circuit chip and having a plurality of openings; a piezoresistor formed on a surface of the membrane opposed to the circuit chip; a support section provided on a side opposite to the circuit chip with respect to the membrane and supporting a peripheral edge portion of the membrane; and a weight section provided on the side opposite to the circuit chip with respect to the membrane and integrally held on a central portion of the membrane.

Abstract: A semiconductor device according to the present invention includes: a semiconductor substrate; a source region formed in a top layer portion of the semiconductor substrate; a drain region formed in the top layer portion of the semiconductor substrate and spaced apart from the source region; a gate electrode formed on the semiconductor substrate and opposing to an interval between the source region and the drain region; a wiring formed on the semiconductor substrate and connected to the source region, the drain region, or the gate electrode; and a MEMS sensor disposed on the semiconductor substrate. The MEMS sensor includes: a thin film first electrode made of the same material as the gate electrode and formed in the same layer as the gate electrode; and a second electrode made of the same material as the wiring, formed in the same layer as the wiring, and spaced apart from the first electrode at a side opposite to the semiconductor substrate side of the first electrode.

Abstract: MEMS sensor including substrate, lower thin film confronting one face of the substrate with a space therebetween and having lower through holes extending in the thickness direction thereof, and upper thin film arranged on the opposite side of the substrate confronting the lower thin film with a space therebetween and having upper through holes extending in the thickness direction. A MEMS sensor manufacturing method includes forming a first sacrificing layer on one face of a substrate, forming a lower thin film on the first sacrificing layer with lower through holes individually extending in the thickness direction, forming a second sacrificing layer on the lower thin film, forming an upper thin film on the second sacrificing layer with upper through holes individually extending in the thickness direction, removing the second sacrificing layer through the upper through holes by etching, and removing the first sacrificing layer through the upper and lower through holes by etching.

Abstract: An inkjet printer head includes: a semiconductor substrate; a vibration diaphragm provided on the semiconductor substrate and capable of vibrating in an opposing direction in which the vibration diaphragm is opposed to the semiconductor substrate; a piezoelectric element provided on the vibration diaphragm; a pressure chamber provided on a side of the vibration diaphragm adjacent to the semiconductor substrate as facing the vibration diaphragm, the pressure chamber being filled with an ink; and a nozzle extending through the vibration diaphragm and communicating with the pressure chamber for ejecting the ink supplied from the pressure chamber.

Abstract: An inkjet printer head includes: a semiconductor substrate; a vibration diaphragm provided on the semiconductor substrate and capable of vibrating in an opposing direction in which the vibration diaphragm is opposed to the semiconductor substrate; a piezoelectric element provided on the vibration diaphragm; a pressure chamber provided on a side of the vibration diaphragm adjacent to the semiconductor substrate as facing the vibration diaphragm, the pressure chamber being filled with an ink; and a nozzle extending through the vibration diaphragm and communicating with the pressure chamber for ejecting the ink supplied from the pressure chamber.

Abstract: A capacitive pressure sensor includes a semiconductor substrate, a first insulating portion configured to define a sensor region, a reference pressure chamber configured to divide a lower portion of the sensor region in a direction, a second insulating portion configured to divide a surface portion of the sensor region above the reference pressure chamber in the direction, and a trench configured to divide the sensor region in the direction. The sensor region is divided into at least three semiconductor parts by the reference pressure chamber, the second insulating portion, and the trench.

Abstract: A capacitance type gyro sensor includes a semiconductor substrate, a first electrode integrally including a first base portion and first comb tooth portions and a second electrode integrally including a second base portion and second comb tooth portions, formed by processing the surface portion of the semiconductor substrate. The first electrode has first drive portions that extend from opposed portions opposed to the respective second comb tooth portions on the first base portion toward the respective second comb tooth portions. The second electrode has second drive portions formed on the tip end portions of the respective second comb tooth portions opposed to the respective first drive portions. The first drive portions and the second drive portions engage with each other at an interval like comb teeth.