Abstract: There is provided a method of mounting conductive balls on pads on a substrate. The method includes: (a) placing the substrate having the pads coated with an adhesive over a container for containing the conductive balls therein and whose top surface is open such that the pads faces the top surface of the container; and (b) throwing up the conductive balls in the container by moving the container up and down at a given stroke, thereby allowing the conductive balls to adhere to the adhesive coated on the pads. Step (b) is repeatedly performed.

Abstract: A method of producing a chip embedded substrate is disclosed. This method comprises a first step of mounting a semiconductor chip on a first substrate on which a first wiring is formed; and a second step of joining the first substrate with a second substrate on which a second wiring is formed. In the second step, the semiconductor chip is encapsulated between the first substrate and the second substrate and electrical connection is made between the first wiring and the second wiring so as to form multilayered wirings connected to the semiconductor chip.

Abstract: There is provided a conductive ball mounting apparatus. The conductive ball mounting apparatus includes: a conductive ball mounting mask disposed to oppose a substrate having a plurality of pads coated with an adhesive flux, the conductive ball mounting mask having a plurality of ball mounting through holes for mounting each of conductive balls on each of the plurality of pads, the plurality of ball mounting through holes being arranged to oppose to the plurality of pads; and a conductive ball supplying unit for moving or removing the conductive balls on the conductive ball mounting mask by sucking an air on an upper surface side of the conductive ball mounting mask. The conductive ball mounting mask includes through portions formed to block passing of the conductive balls.

Abstract: The optical device 10 includes a light source 13, a mirror element 12 including a mirror 36 for reflecting light emitted from the light source 13 in a predetermined direction, and a mirror element housing body 11 that accommodates the mirror element 12 as well as seals a space D where the mirror element 12 is accommodated, characterized in that the light source 13 is provided inside the mirror element housing body 11.

Abstract: A substrate manufacturing apparatus 100 has a substrate delivery path 120 through which a multi-unit substrate 110 is delivered and a mask delivery path 140 through which an individual mask 130 is delivered. The substrate delivery path 120 has a pad detecting device 160 for detecting a position of a pad 112 formed on a surface of the substrate 110. The mask delivery path 140 has a mask hole detecting device 220 for detecting a position of a conductive ball inserting hole 132 of the individual mask 130. A moving position of an adsorbing head 212 is adjusted in such a manner that the position of the conductive ball inserting hole 132 is coincident with that of the pad 112 of the substrate 110 based on pad position information of the pad detecting device 160 and mask hole position information of the mask hole detecting device 220.

Abstract: An optical device includes a translucent member, and a light shielding member formed on the translucent member and having a first opening. A portion of the light shielding member corresponding to a side surface of the first opening is formed into an inclined surface. A method of manufacturing the optical device includes: forming a mask having a second opening on the translucent member such that the second opening corresponds to a shape and a forming area of the light shielding member; filling a Cr-containing resin, in which particles containing Cr are contained in a resin, into the second opening by a printing method; curing the Cr-containing resin filled in the opening to form the light shielding member made of the cured Cr-containing resin; and removing the mask.

Abstract: In a conductive ball mounting apparatus for mounting one conductive ball on each of a plurality of pads which are provided on a substrate and on which an adhesive is formed, the conductive ball mounting apparatus includes: a conductive ball container for containing a plurality of conductive balls therein and having an opening to pass through the plurality of conductive balls; a substrate holder disposed over the conductive ball container to face the opening, and holding the substrate in such a manner that the plurality of conductive balls and the plurality of pads face each other and the substrate is disposed over the conductive ball container with a space therebetween; and a conductive ball supplying unit for supplying the plurality of conductive balls to the plurality of pads via the opening by moving up the plurality of conductive balls.

Abstract: A solder ball mounting method includes a step of providing a flux on electrodes of a substrate, a step of arranging a plurality of solder ball mounting masks in which ball feeding openings are formed in positions opposing to the electrodes and opening areas of the ball feeding openings are set to increase toward an upper layer on the substrate, a step of mounting solder balls on the electrodes by feeding the solder balls into the ball feeding openings while moving the solder ball mounting mask as an upper layer in a surface direction of the substrate, a step of removing the solder ball mounting masks from the substrate, and a step of joining the solder balls to the electrodes.

Abstract: A solder resist having first opening portions on positions corresponding to electrodes and a second opening portion on a mask providing position is formed on the substrate. A flux mask whose thickness is substantially same as the solder resist is arranged in the second opening portion and then a flux is filled in the first opening portions. The flux mask is removed and then a solder ball mounting mask is arranged over the substrate such that its supporting portion is positioned in the second opening portion. Solder balls are mounted on the flux formed on the electrodes by using the solder ball mounting mask. The solder ball mounting mask is removed and then the solder balls are joined to the electrodes by executing the heating process.

Abstract: A method of forming solder connection portions on first electrode pads and on second electrode pads, comprises a first step of arranging solder balls on the first electrode pads by arranging a first mask on a base mask; a second step of arranging solder balls on the second electrode pads by arranging a second mask on the base mask; and a third step of melting the solder balls. The base mask has first opening portions corresponding to the first electrode pads and second opening portions corresponding to the second electrode pads and having a size different from that of the first opening portions. The first mask has opening portions corresponding to the first opening portions and covering the second opening portions. The second mask has opening portions corresponding to the second opening portions and covers the first opening portions.

Abstract: In a semiconductor device 100, a light emitting device 102 is mounted on a substrate 101. A light reflection preventing film 130 for preventing a reflection of a light is formed on an upper surface of the light emitting device 102. Moreover, a plate-shaped cover 103 formed of a glass having a light transparency is disposed above the light emitting device 102, and a light reflection preventing film 140 for preventing a reflection of a light is also formed on an upper surface of the cover 103.

Abstract: The invention provides a light-emitting device 10 including an light-emitting element 12 and a substrate 11 where the light-emitting element 12 is arranged, characterized in that a housing part 28 housing the light-emitting element 12 and having a shape that is tapered upward from the substrate 11 and a metal frame 15 surrounding the light-emitting element 12 and including the side face 28A of the housing part 28 made into an almost mirror-polished surface are provided on the substrate 11.

Abstract: A light emitting apparatus, includes: a light emitting device accommodating body, which has a recessed portion wherein a light emitting device is accommodated; a wiring pattern, which is provided for the light emitting device accommodating body 11 and is electrically connected to the light emitting device; a light transmitting substrate, which is mounted on the light emitting device accommodating body and completely closes the recessed portion; and a phosphor-containing, ultraviolet curing resin, which is so deposited that, opposite to the light emitting device accommodating body, the face of the light transmitting member is covered.

Abstract: The optical device 10 includes a light source 13, a mirror element 12 including a mirror 36 for reflecting light emitted from the light source 13 in a predetermined direction, and a mirror element housing body 11 that accommodates the mirror element 12 as well as seals a space D where the mirror element 12 is accommodated, characterized in that the light source 13 is provided inside the mirror element housing body 11.

Abstract: According to a sealed structure 60 constituted by anodically bonding a silicon board 20 and a glass plate 40, an upper opening of a recessed portion 22 is sealed in an airtight state by the glass plate 40 by bonding an upper face of a wall portion 26 to the glass plate 40. A voltage applying pattern 70 is formed to surround a light transmitting region to which an optical conversion element 24 is opposed. Further, the voltage applying pattern 70 functions as a cathode pattern applied with a voltage by being brought into contact with a lower face of the cathode plate 50.

Abstract: A semiconductor device 10 has such a structure that a plurality of through electrodes 30 is formed on a substrate 20 and each of terminals of light emitting devices (LEDs) 40 is electrically connected to each of the through electrodes 30 via a bump 50 on a lower surface side. In the semiconductor device 10, moreover, a partition wall 80 for surrounding a mounting region of each of the light emitting devices 40 is formed on the substrate 20. The partition wall 80 is formed by laminating a metal film (Cu) using a thin film forming method such as a plating method. Furthermore, the partition wall 80 is formed to be opposed close to each of side surfaces of the light emitting devices 40 and is provided to surround each of the light emitting devices 40.

Abstract: A method of producing a light emitting apparatus including a light emitting element, a light emitting element housing having a recess for housing the light emitting element, and a translucent substrate placed on the light emitting element housing is disclosed. The disclosed method includes a fluorescent-substance-containing resin forming step of forming a fluorescent-substance-containing resin on a first side of the translucent substrate which first side is opposite to a second side of the translucent substrate which second side faces the recess. In the fluorescent-substance-containing resin forming step, luminance and chromaticity of light that is emitted from the light emitting element and then transmitted by the fluorescent-substance-containing resin are measured and a thickness of the fluorescent-substance-containing resin is adjusted based on the measured luminance and chromaticity so that light emitted from the light emitting apparatus attains the specified luminance and chromaticity.

Abstract: A disclosed method for manufacturing a semiconductor device having a structure where a semiconductor element is mounted on a first substrate includes the steps of: bonding the first substrate on which the semiconductor element is mounted and a second substrate made of a material different from a material of the first substrate so as to encapsulate the semiconductor element; forming a first groove in the first substrate and a second groove in the second substrate; and cleaving a portion between the first groove and the second groove so as to individualize the semiconductor device.

Abstract: A method of manufacturing a light emitting apparatus including a light emitting device and a light emitting device installing body having a concave part for installing the light emitting device therein is disclosed. The method includes the steps of a) forming a coating of plural fluorophor particles covering the light emitting device installed in the concave part, and b) forming a transparent resin covering the plural fluorophor particle coating. Step b) includes a step of performing illumination with the light emitting device so that the light emitted from the light emitting apparatus has a predetermined luminance and chromaticity.

Abstract: A light emitting device is disclosed. The light emitting device includes a light emitting element (15), and a light emitting element container (11) having a concave section (20) for containing the light emitting element (15). The concave section (20) includes a side surface (20A) and a bottom surface (20B) almost orthogonal to the side surface (20A). The light emitting device further includes a conductive paste layer (17) formed of a conductive paste in which metal particles are dispersed in a solution, and the conductive paste layer (17) includes a slanting surface (17A) on the side surface (20A) and the bottom surface (20B).