Abstract: Oscillators (101a and 101b) are attached to a spring material (100) whose both ends (105a and 105b) are held, and piezoelectric elements (103a, 103b, and 106) are attached to the spring material or the oscillators. Assuming that an axis parallel to an axis connecting the both ends of the spring material is a Y-axis, an axis parallel to a plane including the Y-axis and the oscillators and orthogonal to the Y-axis is an X-axis, and an axis orthogonal to the Y-axis and the X-axis is a Z-axis, the oscillators are asymmetric with respect to a plane including the Y-axis and the Z-axis. Consequently, when acceleration is applied, torsional vibrations act on the spring material. When the torsional rigidity of the spring material is set to be low, the resonant frequency of the torsional vibrations can be reduced. Since the both ends of the spring material are held, the spring material is bent in a small amount.

Abstract: A plurality of lenses 102a to 102d arranged in the same plane form a plurality of subject images on a plurality of imaging regions 104a to 104d. Vertical line directions and horizontal line directions of the pixel arrangement in the respective plurality of imaging regions are equal to one another among the plurality of imaging regions. Further, at least one pair of subject images received by at least one pair of imaging regions having a parallax in the vertical line (or horizontal line) direction among the plurality of imaging regions are shifted from each other by a predetermined amount in the horizontal line (or vertical line) direction. By performing pixel shifting in a direction perpendicular to the direction in which a parallax is generated, it always is possible to obtain a high-resolution image even when the subject distance varies.

Abstract: A multi-eye imaging apparatus comprises a plurality of imaging systems (106a, 106b) each including an optical system (107a, 107b) and an imaging element (108a, 108b) and having a different optical axis. The plurality of imaging systems (106a, 106b) include a first imaging system (106b) having a pixel shift means (101) for changing a relative positional relationship between an image formed on the imaging element (108b), and the imaging element (108b), and a second imaging system (106a) in which a relative positional relationship between an image formed on the imaging element (108a), and the imaging element (108a), is fixed during time-series image capture.

Abstract: Multiple imaging areas (101a, 101b) are disposed in a one-to-one relationship with multiple optical lenses (100a, 100b) disposed in a substantially coplanar alignment. A baffle wall (110) interposed between the multiple imaging areas is provided with means for diffusively reflecting incident light rays. Low frequency components are removed from the spatial frequencies of multiple images captured in the multiple imaging areas, whereupon the multiple images are compared to determine the amount of parallax and measure the distance to the object. This allows for preventing degradation in the accuracy of distance measurement when light rays emanating from a high-intensity object located outside of the field angle are reflected from the baffle wall and impinge on the imaging area.

Abstract: A plurality of imaging optical lenses (301a to 301c) form a plurality of subject images on a plurality of imaging regions (302a to 302c), respectively. When viewed along a direction parallel with optical axes, at least one straight line connecting corresponding points in at least one pair of the subject images that are formed by at least one pair of the imaging optical lenses is inclined with respect to a direction in which pixels are arranged in the imaging regions. In this way, a high-resolution image always can be obtained regardless of the subject distance.

Abstract: Oscillators (101a and 101b) are attached to a spring material (100) whose both ends (105a and 105b) are held, and piezoelectric elements (103a, 103b, and 106) are attached to the spring material or the oscillators. Assuming that an axis parallel to an axis connecting the both ends of the spring material is a Y-axis, an axis parallel to a plane including the Y-axis and the oscillators and orthogonal to the Y-axis is an X-axis, and an axis orthogonal to the Y-axis and the X-axis is a Z-axis, the oscillators are asymmetric with respect to a plane including the Y-axis and the Z-axis. Consequently, when acceleration is applied, torsional vibrations act on the spring material. When the torsional rigidity of the spring material is set to be low, the resonant frequency of the torsional vibrations can be reduced. Since the both ends of the spring material are held, the spring material is bent in a small amount.

Abstract: A plurality of lenses 102a to 102d arranged in the same plane form a plurality of subject images on a plurality of imaging regions 104a to 104d. Vertical line directions and horizontal line directions of the pixel arrangement in the respective plurality of imaging regions are equal to one another among the plurality of imaging regions. Further, at least one pair of subject images received by at least one pair of imaging regions having a parallax in the vertical line (or horizontal line) direction among the plurality of imaging regions are shifted from each other by a predetermined amount in the horizontal line (or vertical line) direction. By performing pixel shifting in a direction perpendicular to the direction in which a parallax is generated, it always is possible to obtain a high-resolution image even when the subject distance varies.

Abstract: A plurality of imaging optical lenses (301a to 301c) form a plurality of subject images on a plurality of imaging regions (302a to 302c), respectively. When viewed along a direction parallel with optical axes, at least one straight line connecting corresponding points in at least one pair of the subject images that are formed by at least one pair of the imaging optical lenses is inclined with respect to a direction in which pixels are arranged in the imaging regions. In this way, a high-resolution image always can be obtained regardless of the subject distance.

Abstract: In an actuator 11, which includes a driver 10 including: a substrate 1 having a predetermined width and a predetermined length when viewed from the direction of thickness of the substrate; a reinforcing member 2 provided on one of the thickness-wise faces of the substrate 1; and displacement means (a piezoelectric element 3), provided on the other thickness-wise face of the substrate 1, for displacing, with respect to one of the lengthwise ends of the substrate, the other lengthwise end in the direction of width of the substrate, the reinforcing member 2 is configured so that the flexural rigidity thereof in the substrate's width direction is lower than that in the substrate's thickness direction.

Abstract: In a piezoelectric element, an adhesive layer 12 is provided on a substrate 11, a first electrode layer 14 made of a noble metal containing titanium or titanium oxide is provided on the adhesive layer 12, and an orientation control layer 15 that is preferentially oriented along a (100) or (001) plane is provided on the first electrode layer 14. In the vicinity of a surface of the orientation control layer 15 that is closer to the first electrode layer 14, a (100)- or (001)-oriented region extends over titanium or titanium oxide located on one surface of the first electrode layer 14 that is closer to the orientation control layer 15, and the cross-sectional area of the region in the direction perpendicular to the thickness direction gradually increases in the direction away from the first electrode layer 14 toward the opposite side. Further, a piezoelectric layer 16 that is preferentially oriented along a (001) plane is provided on the orientation control layer 15.

Abstract: A first electrode thin film is formed on an upper surface of the oxygen ion conductive thin film so as to have a through hole. A resistor is formed on part of the upper surface of the oxygen conductive thin film located in the through hole. Thus, the oxygen ion conductive thin film can be directly heated by the resistor, so that oxygen ions can be speedily transferred with a low power. Therefore, the oxygen ion conductivity of the oxygen ion conductive thin film can be improved.

Abstract: A multi-eye imaging apparatus comprises a plurality of imaging systems (106a, 106b) each including an optical system (107a, 107b) and an imaging element (108a, 108b) and having a different optical axis. The plurality of imaging systems (106a, 106b) include a first imaging system (106b) having a pixel shift means (101) for changing a relative positional relationship between an image formed on the imaging element (108b), and the imaging element (108b), and a second imaging system (106a) in which a relative positional relationship between an image formed on the imaging element (108a), and the imaging element (108a), is fixed during time-series image capture.

Abstract: In a piezoelectric element 20, a first electrode layer 2 made of an alloy of at least one metal selected from the group consisting of cobalt, nickel, iron, manganese and copper and a noble metal is formed on a silicon substrate 1, and a piezoelectric layer 3 made of a rhombohedral or tetragonal perovskite oxide (e.g., PZT) is formed on the first electrode layer 2 so that the piezoelectric layer 3 is preferentially oriented along the (001) plane.

Abstract: In an actuator 11, which includes a driver 10 including: a substrate 1 having a predetermined width and a predetermined length when viewed from the direction of thickness of the substrate; a reinforcing member 2 provided on one of the thickness-wise faces of the substrate 1; and displacement means (a piezoelectric element 3), provided on the other thickness-wise face of the substrate 1, for displacing, with respect to one of the lengthwise ends of the substrate, the other lengthwise end in the direction of width of the substrate, the reinforcing member 2 is configured so that the flexural rigidity thereof in the substrate's width direction is lower than that in the substrate's thickness direction.

Abstract: First, a first electrode layer 4, a piezoelectric layer 5, a second electrode layer 6 and an oscillation layer 7 are stacked in this order over one surface of a silicon substrate 1. Next, an ink chamber partition 8 and a nozzle plate 11 are stacked over the oscillation layer 7. Subsequently, the silicon substrate 1 is ground away to a predetermined thickness from a surface thereof opposite to the first electrode layer 4, and then a remnant silicon substrate 13 is dry etched away. Thereafter, the first electrode layer 4 is patterned to form a plurality of inkjet mechanisms 2, 2, . . . . Finally, the plurality of inkjet mechanisms 2, 2, . . . are divided to simultaneously fabricate a plurality of inkjet heads 3, 3, . . . .

Abstract: In a piezoelectric element 20, a first electrode layer 2 made of an alloy of at least one metal selected from the group consisting of cobalt, nickel, iron, manganese and copper and a noble metal is formed on a silicon substrate 1, and a piezoelectric layer 3 made of a rhombohedral or tetragonal perovskite oxide (e.g., PZT) is formed on the first electrode layer 2 so that the piezoelectric layer 3 is preferentially oriented along the (001) plane.

Abstract: In a piezoelectric element 20, a first electrode layer 2 made of an alloy of at least one metal selected from the group consisting of cobalt, nickel, iron, manganese and copper and a noble metal is formed on a silicon substrate 1, and a piezoelectric layer 3 made of a rhombohedral or tetragonal perovskite oxide (e.g., PZT) is formed on the first electrode layer 2 so that the piezoelectric layer 3 is preferentially oriented along the (001) plane.

Abstract: In a piezoelectric element, an adhesive layer 12 is provided on a substrate 11, a first electrode layer 14 made of a noble metal containing titanium or titanium oxide is provided on the adhesive layer 12, and an orientation control layer 15 that is preferentially oriented along a (100) or (001) plane is provided on the first electrode layer 14. In the vicinity of a surface of the orientation control layer 15 that is closer to the first electrode layer 14, a (100)- or (001)-oriented region extends over titanium or titanium oxide located on one surface of the first electrode layer 14 that is closer to the orientation control layer 15, and the cross-sectional area of the region in the direction perpendicular to the thickness direction gradually increases in the direction away from the first electrode layer 14 toward the opposite side. Further, a piezoelectric layer 16 that is preferentially oriented along a (001) plane is provided on the orientation control layer 15.

Abstract: In a piezoelectric element, an adhesive layer 12 is provided on a substrate 11, a first electrode layer 14 made of a noble metal containing titanium or titanium oxide is provided on the adhesive layer 12, and an orientation control layer 15 that is preferentially oriented along a (100) or (001) plane is provided on the first electrode layer 14. In the vicinity of a surface of the orientation control layer 15 that is closer to the first electrode layer 14, a (100)- or (001)-oriented region extends over titanium or titanium oxide located on one surface of the first electrode layer 14 that is closer to the orientation control layer 15, and the cross-sectional area of the region in the direction perpendicular to the thickness direction gradually increases in the direction away from the first electrode layer 14 toward the opposite side. Further, a piezoelectric layer 16 that is preferentially oriented along a (001) plane is provided on the orientation control layer 15.

Abstract: A piezoelectric element includes a first electrode layer 14 provided on a substrate 11 and made of a noble metal to which at least one additive selected from the group consisting of Mg, Ca, Sr, Ba, Al and oxides thereof is added, an orientation control layer 15 provided on the first electrode layer 14 and made of a cubic or tetragonal perovskite oxide that is preferentially oriented along a (100) or (001) plane, and a piezoelectric layer 16 provided on the orientation control layer 15 and made of a rhombohedral or tetragonal perovskite oxide that is preferentially oriented along a (001) plane.