A light emitting device includes: a ceramic substrate; a plurality of LED chips; a printed resistor(s) connected in parallel with the plurality of LED chips; a dam resin made of a resin having a low optical transmittance; a fluorescent-material-containing resin layer; and an anode-side electrode and a cathode-side electrode, (a) which are provided on a primary surface of the ceramic substrate so as to face each other along a first direction on the primary surface and (b) which are disposed below at least one of the dam resin and the fluorescent-material-containing resin layer. With the configuration in which a plurality of LEDs, which are connected in a series-parallel connection, are provided on a substrate, it is possible to provide a light emitting device which can achieve restraining of luminance unevenness and an improvement in luminous efficiency.

The present invention relates to a light emitting device comprising a transparent substrate which light can pass through and at least one LED chip emitting light omni-directionally. Wherein the LED chip is disposed on one surface of the substrate and the light emitting angle of the LED chip is wider than 180, and the light emitted by the LED chip will penetrate into the substrate and at least partially emerge from another surface of the substrate. According to the present invention, the light emitting device using LED chips can provide sufficient lighting intensity and uniform lighting performance.

An optoelectronic component includes a housing having a cavity in which an optoelectronic semiconductor chip having an emission face that emits light rays and a transparent potting material are arranged, wherein the cavity includes at least one side wall at least partly reflecting light rays incident on the side wall and reflectivity of which decreases as an operating period of the component increases, conversion particles are embedded into the potting material, which conversion particles convert light rays having a first wavelength incident on the conversion particles into light rays having a second wavelength, and scattering particles are embedded into the potting material, which scattering particles scatter light rays incident on the scattering particles and the scattering capability of which scattering particles increases as the operating period increases.

A light emitting device includes a substrate, a light emitting element provided on the substrate, a first resin layer provided on the substrate to directly cover the light emitting element having a first side surface and a second side surface, and the first side surface and the second side surface differ from each other in inclination angle with respect to the substrate, and a second resin layer provided so as to surround side surfaces of the first resin layer.

A light bulb shaped lamp according to the present invention includes a translucent base board, an LED chip mounted on the base board, a base for receiving power from outside, at least two power-supply leads for supplying power to the LED chip, and a globe partially attached to the base for housing the base board, the LED chip, and the power-supply leads. Each of the two power-supply leads extends from a side of the base toward inside of the globe and connected to the base board, and the LED chip is provided between a portion at which one of the two power-supply leads and the base board are connected and a portion at which the other of the two power-supply leads and the base board are connected.

The invention relates to a method of manufacturing optoelectronic devices including light-emitting diodes, including the steps of: a) forming a first integrated circuit chip including light-emitting diodes; b) bonding a second integrated chip to a first surface of the first chip; c) decreasing the thickness of the first chip on the side opposite to the first surface to form a second surface opposite to the first surface; d) bonding, to the second surface, a cap including a silicon wafer provided with recesses opposite the light-emitting diodes; e) decreasing the thickness of the second chip; f) decreasing the thickness of the silicon wafer before step d) or after step e), each recess being filled with a photoluminescent material; and g) sawing the structure obtained at step f) into a plurality of separate optoelectronic devices.

An LED wafer includes LED dies on an LED substrate. The LED wafer and a carrier wafer are joined. The LED wafer that is joined to the carrier wafer is shaped. Wavelength conversion material is applied to the LED wafer that is shaped. Singulation is performed to provide LED dies that are joined to a carrier die. The singulated devices may be mounted in an LED fixture to provide high light output per unit area.

A semiconductor light emitting device includes an LED chip, which includes an n-type semiconductor layer, active layer, and p-type semiconductor layer stacked on a substrate. The LED chip further includes an anode electrode connected to the p-type semiconductor, and a cathode connected to the n-type semiconductor. The anode and cathode electrodes face a case with the LED chip mounted thereon. The case includes a base member including front and rear surfaces, and wirings including a front surface layer having anode and cathode pads formed at the front surface, a rear surface layer having anode and cathode mounting electrodes formed at the rear surface, an anode through wiring connecting the anode pad and the anode mounting electrode and passing through a portion of the base member, and a cathode through wirings connecting the cathode pad and the cathode mounting electrode and passing through a portion of the base member.

The present invention relates to a light-emitting diode (LED) structure, which comprises an LED unit. The LED unit is doped with a plurality of fluorescent powders in at least an arbitrary layer on one side of a light-emitting layer. Alternatively, the LED unit includes a plurality of fluorescent powder particles arranged on at least a light-emitting surface of the LED unit. No gel is adopted for disposing or packaging fluorescent powders. Thereby, gel yellowing caused by long-term high-temperature heating of the LED structure will not occur. The yellowing phenomenon will affect the light-emitting efficiency of LED and induce color deviation.

A method of manufacturing a light emitting device includes: providing on a mounting substrate a soluble member which is soluble in a solvent and which has a lower surface, an upper surface opposite to the lower surface in a height direction, and an outer side surface provided between the lower surface and the upper surface, the lower surface contacting the mounting substrate; providing a light blocking member made of resin to cover the outer side surface of the soluble member so that an inner side wall of the light blocking member contacts the outer side surface of the soluble member; removing the soluble member using the solvent to provide a recess surrounded by the inner side wall of the light blocking member; and mounting a light emitting element in the recess.