Abstract: A semiconductor apparatus is disclosed. The semiconductor apparatus includes a semiconductor substrate that has a first surface and a second surface opposite to each other. The semiconductor apparatus further includes multiple double-sided electrode elements each having a pair of electrodes located respectively on the first and second surfaces of the semiconductor substrate. A current flows between the first and second electrode. Each double-sided electrode element has a PN column region located in the semiconductor substrate. The semiconductor apparatus further includes an insulation trench that surrounds each of multiple double-sided electrode elements, and that insulates and separates the multiple double-sided electrode elements from each other.

Abstract: A semiconductor device includes a semiconductor substrate that includes a plurality of section having different thicknesses. The sections include a first section having a first thickness and a second section having a second thickness, the second section is the thinnest section among all the sections, and the first thickness is greater than the second thickness. A plurality of isolation trenches penetrates the semiconductor substrate for defining a plurality of element-forming regions in the first section and the second section. A plurality of elements is located at respective ones of the plurality of element-forming regions. The elements include a double-sided electrode element that includes a pair of electrodes separately disposed on the first surface and the second surface, and the double-sided electrode element is located in the second section.

Abstract: A magnetic sensor includes: a substrate; a semiconductor region; a magnetic field detection portion; a pair of first electrodes; and two pairs of second electrodes. One pair of second electrodes includes first and second terminals, and the other pair includes third and fourth terminals. The first and third terminals are disposed on one side, and the second and fourth terminals are disposed on the other side. The first and fourth terminals are electrically coupled, and the second and third terminals are electrically coupled. The magnetic field detection portion and the first and second electrodes provide a vertical Hall element. One of the first and second electrodes supplies a driving current, and the other one detects the Hall voltage.

Abstract: A semiconductor device includes a first substrate including first, second and third layers; and a second substrate including fourth, fifth and sixth layers. The first substrate provides an electric device. The second substrate provides a physical quantity sensor. The first layer of the first substrate and the fourth layer of the second substrate are shields for protecting the electric device and the physical quantity sensor. The device is protected from outside disturbance without adding an additional shield.

Abstract: A pressure sensor for a pressure medium includes: a sensor chip (3) including a semiconductor substrate (3a), a diaphragm (3b) in the substrate and a gauge resistor (3c) on the diaphragm; a protection cap (5) covering the diaphragm; a case (2) for accommodating the chip, introducing the pressure medium to the cap, and atmospheric air to the substrate; a terminal (2c); a wiring (4); and a seal member (7). An embedded portion (4a-4c, 4e) of the wiring is coupled with the gauge resistor. A connection portion (4d, 4f) of the wiring couples the embedded portion and the terminal. The embedded portion is covered with the cap to be isolated from the pressure medium. The seal member is disposed between the case and the substrate to isolate the connection portion from the pressure medium and the atmospheric air.

Abstract: In a manufacturing of a semiconductor device, at least one of elements is formed in each of element formation regions of a substrate having a main side and a rear side, and the substrate is thinned by polished from a rear side of the substrate, and then, multiple trenches are formed on the rear side of the substrate, so that each trench reaches the main side of the substrate. After that, an insulating material is deposited over an inner surface of each trench to form an insulating layer in the trench, so that the element formation regions are isolated. Thereby, generation of cracks and structural steps in the substrate and separation of element formation regions from the substrate can be suppressed.

Abstract: An ultrasonic sensor for detecting an object includes: a piezoelectric element having a piezoelectric body and first and second electrodes for sandwiching the piezoelectric body; an acoustic matching element having a reception surface, which receives an ultrasonic wave reflected by the object; and a circuit electrically coupled with the piezoelectric element via a wire. The piezoelectric element is embedded in the acoustic matching element so that the acoustic matching element covers at least the first electrode, a part of a sidewall of the piezoelectric element and a part of the wire between the circuit and the piezoelectric element, and the sidewall of the piezoelectric element is adjacent to the first electrode.

Abstract: A semiconductor mechanical sensor having a new structure in which a S/N ratio is improved. In the central portion of a silicon substrate 1, a recess portion 2 is formed which includes a beam structure. A weight is formed at the tip of the beam, and in the bottom surface of the weight in the bottom surface of the recess portion 2 facing the same, an electrode 5 is formed. An alternating current electric power is applied between the weight portion 4 and the electrode 5 so that static electricity is created and the weight is excited by the static electricity. In an axial direction which is perpendicular to the direction of the excitation of the weight, an electrode 6 is disposed to face one surface of the weight and a wall surface of the substrate which faces the same. A change in a capacitance between the facing electrodes is electrically detected, and therefore, a change in a physical force acting in the same direction is detected.

Abstract: An ultrasonic sensor includes a piezoelectric element and an acoustic matching member that are joined together to form an ultrasonic detector base. The ultrasonic detector base is sectioned by a clearance extending in an ultrasonic propagation direction to form multiple ultrasonic detectors arranged in an array. The clearance does not entirely section the ultrasonic detector base so that the ultrasonic detectors are joined together by a portion of the ultrasonic detector base.

Abstract: A semiconductor device includes: a sensor element having a plate shape with a surface and including a sensor structure disposed in a surface portion of the sensor element; and a plate-shaped cap element bonded to the surface of the sensor element. The cap element has a wiring pattern portion facing the sensor element. The wiring pattern portion connects an outer periphery of the surface of the sensor element and the sensor structure so that the sensor structure is electrically coupled with an external element via the outer periphery. The sensor element does not have a complicated multi-layered structure, so that the sensor element is simplified. Further, the dimensions of the device are reduced.

Abstract: A semiconductor device includes a first substrate including first, second and third layers; a second substrate; and a loop bump. The first and second substrates provides an electric device and physical quantity sensor. The first layer is a shield for protecting the electric device and physical quantity sensor. The physical quantity sensor includes a movable portion surrounded by a first loop layer of the third layer. The loop bump is disposed between the first and second substrates and surrounds the movable portion, and is electrically coupled with the first loop layer so that the loop bump, first loop layer, first layer and second substrate shield the electric device and physical quantity sensor. The first substrate includes inner and outer pads which are electrically coupled through a wire layer which is electrically insulated from the loop bump, so that a signal from the movable portion is output to and external circuit.

Abstract: A semiconductor device includes: a first substrate made of semiconductor and having first regions, which are insulated from each other and disposed in the first substrate; and a second substrate having electric conductivity and having second regions and insulation trenches. Each insulation trench penetrates the second substrate so that the second regions are insulated from each other. The first substrate provides a base substrate, and the second substrate provides a cap substrate. The second substrate is bonded to the first substrate so that a sealed space is provided between a predetermined surface region of the first substrate and the second substrate. The second regions include an extraction conductive region, which is coupled with a corresponding first region.

Abstract: A semiconductor apparatus comprises: a semiconductor substrate; and a lateral type MIS transistor disposed on a surface part of the semiconductor substrate. The lateral type MIS transistor includes: a line coupled with a gate of the lateral type MIS transistor; a polycrystalline silicon resistor that is provided in the line, and that has a conductivity type opposite to a drain of the lateral type MIS transistor; and an insulating layer through which a drain voltage of the lateral type MIS transistor is applied to the polycrystalline silicon resistor.

Abstract: A semiconductor mechanical sensor having a new structure in which a S/N ratio is improved. In the central portion of a silicon substrate 1, a recess portion 2 is formed which includes a beam structure. A weight is formed at the tip of the beam, and in the bottom surface of the weight in the bottom surface of the recess portion 2 facing the same, an electrode 5 is formed. An alternating current electric power is applied between the weight portion 4 and the electrode 5 so that static electricity is created and the weight is excited by the static electricity. In an axial direction which is perpendicular to the direction of the excitation of the weight, an electrode 6 is disposed to face one surface of the weight and a wall surface of the substrate which faces the same. A change in a capacitance between the facing electrodes is electrically detected, and therefore, a change in a physical force acting in the same direction is detected.

Abstract: A semiconductor device having plural active and passive elements on one semiconductor substrate is manufactured in the following cost effective manner even when the active and passive elements include double sided electrode elements. When the semiconductor substrate is divided into plural field areas, an insulation separation trench that penetrates the semiconductor substrate surrounds each of the field areas, and each of the either of the plural active elements or the plural passive elements. Further, each of the plural elements has a pair of power electrodes for power supply respectively disposed on each of both sides of the semiconductor substrate to serve as the double sided electrode elements.

Abstract: A method for manufacturing a physical quantity sensor includes: forming a sensor element in a first wafer; stacking a support substrate, a connection layer and a cap layer in this order so that a second wafer is prepared; bonding the cap layer of the second wafer to the first wafer in such a manner that the sensor element is disposed in a space between the first wafer and the second wafer; removing the support substrate and the connection layer from the second wafer; and dividing the first wafer together with the cap layer into a plurality of chips so that a plurality of physical quantity sensors is formed.

Abstract: A semiconductor device includes: a semiconductor substrate; a lateral MOS transistor disposed in the substrate; a Zener diode disposed in the substrate; and a capacitor disposed in the substrate. The transistor includes a drain and a gate, and the diode and the capacitor are coupled in series between the drain and the gate. This device has minimized dimensions and high switching speed. Further, both of a switching loss and a surge voltage are improved.

Abstract: A physical quantity sensor for detecting a physical quantity includes: a first substrate having a first physical quantity detection element; a second substrate having a second physical quantity detection element, wherein the second substrate contacts the first substrate; and an accommodation space disposed between the first substrate and the second substrate. The first physical quantity detection element is disposed in the accommodation space. The first physical quantity detection element is protected with the first substrate and the second substrate since the first physical quantity detection element is sealed in the accommodation space.

Abstract: A single crystal silicon substrate (1) is bonded through an SiO2 film (9) to a single crystal silicon substrate (8), and the single crystal silicon substrate (1) is made into a thin film. A cantilever (13) is formed on the single crystal silicon substrate (1), and the thickness of the cantilever (13) in a direction parallel to the surface of the single crystal silicon substrate (1) is made smaller than the thickness of the cantilever in the direction of the depth of the single crystal silicon substrate (1), and movable in a direction parallel to the substrate surface. In addition, the surface of the cantilever (13) and the part of the single crystal silicon substrate (1), opposing the cantilever (13), are respectively, coated with an SiO2 film (5), so that an electrode short circuit is prevented in a capacity-type sensor. In addition, a signal-processing circuit (10) is formed on the single crystal silicon substrate (1), so that signal processing is performed as the cantilever (13) moves.

Abstract: A single crystal silicon substrate (1) is bonded through an SiO2 film (9) to a single crystal silicon substrate (8), and the single crystal silicon substrate (1) is made into a thin film. A cantilever (13) is formed on the single crystal silicon substrate (1), and the thickness of the cantilever (13) in a direction parallel to the surface of the single crystal silicon substrate (1) is made smaller than the thickness of the cantilever in the direction of the depth of the single crystal silicon substrate (1), and movable in a direction parallel to the substrate surface. In addition, the surface of the cantilever (13) and the part of the single crystal silicon substrate (1), opposing the cantilever (13), are, respectively, coated with an SiO2 film (5), so that an electrode short circuit is prevented in a capacity-type sensor. In addition, a signal-processing circuit (10) is formed on the single crystal silicon substrate (1), so that signal processing is performed as the cantilever (13) moves.