Abstract: An image acquiring apparatus for a vehicle includes a light emitting unit configured to emit pulse light to a predetermined direction, an image acquisition unit configured to acquire a plurality of different images of target distance ranges by imaging reflected light returning from the target distance ranges at imaging timings set according to the target distance ranges, and a timing controller configured to control a light emission cycle of the pulse light and the imaging timings. The timing controller is configured to set a light emission interval time to be longer than a delay time which is a time from a light emission start time point of the light emitting unit to an imaging start time point of the image acquisition unit and is required to image a longest-distance range of the target distance ranges from which the reflected light can be imaged.

Abstract: An image acquiring apparatus for a vehicle includes a light emitting unit configured to emit pulse light to a predetermined direction, an image acquisition unit configured to acquire a plurality of different images of target distance ranges by imaging reflected light returning from the target distance ranges at imaging timings set according to the target distance ranges, and a timing controller configured to control a light emission cycle of the pulse light and the imaging timings. The timing controller is configured to set a light emission interval time to be longer than a delay time which is a time from a light emission start time point of the light emitting unit to an imaging start time point of the image acquisition unit and is required to image a longest-distance range of the target distance ranges from which the reflected light can be imaged.

Abstract: In a light emitting module 40, light wavelength conversion ceramic 58 converts the wavelength of the light emitted by a semiconductor light emitting element 52. The light wavelength conversion ceramic 58 is made so transparent that the light wavelength conversion ceramic 58 has 40 percent or more of the total light transmittance of the light with a wavelength within the conversion wavelength range. A reflective film 60 is provided on the surface of the light wavelength conversion ceramic 58 and narrows down the emission area of the light that has transmitted the light wavelength conversion ceramic 58 to an area smaller than the light emitting area of the semiconductor light emitting element 52. In the case, the reflective film 60 guides the light such that the light is emitted in the direction approximately parallel to the light emitting surface of the light emitting element 52.

Abstract: In a light emitting module 40, light wavelength conversion ceramic 58 converts the wavelength of the light emitted by a semiconductor light emitting element 52. The light wavelength conversion ceramic 58 is made so transparent that the light wavelength conversion ceramic 58 has 40 percent or more of the total light transmittance of the light with a wavelength within the conversion wavelength range. A reflective film 60 is provided on the surface of the light wavelength conversion ceramic 58 and narrows down the emission area of the light that has transmitted the light wavelength conversion ceramic 58 to an area smaller than the light emitting area of the semiconductor light emitting element 52. In the case, the reflective film 60 guides the light such that the light is emitted in the direction approximately parallel to the light emitting surface of the light emitting element 52.

Abstract: A light emitting device module is provided. The light emitting device module includes a plurality of light emitting devices; a submount on which the light emitting devices are mounted; and a heat-radiant substrate to which the submount is fixed. The submount includes a positive front surface electrode; a negative front surface electrode; at least one relay front surface electrode, wherein the plurality of light emitting devices are electrically coupled to each other in series via the at least one relay front surface electrode; a plurality of through electrodes; a positive back surface electrode coupled to the positive front surface electrode via a through electrode; a negative back surface electrode coupled to the negative front surface electrode via a through electrode; and at least one relay back surface electrode which is coupled to the at least one relay front surface electrode via a through electrode.

Abstract: In a light emitting module, an electrode receiving the supply of current for light emission is provided on the light emitting surface of a semiconductor light emitting device. A light wavelength conversion member is a plate-like material mounted on the light emitting surface and emits light after converting a wavelength of the light emitted by the light emitting element. The light wavelength conversion member has a notch such that at least a part of the electrode communicates with the external space in a manner perpendicular to the light emitting surface of the semiconductor device when the light wavelength conversion member is mounted on the light emitting surface.

Abstract: A light emitting device module is provided. The light emitting device module includes a plurality of light emitting devices; a submount on which the light emitting devices are mounted; and a heat-radiant substrate to which the submount is fixed. The submount includes a positive front surface electrode; a negative front surface electrode; at least one relay front surface electrode, wherein the plurality of light emitting devices are electrically coupled to each other in series via the at least one relay front surface electrode; a plurality of through electrodes; a positive back surface electrode coupled to the positive front surface electrode via a through electrode; a negative back surface electrode coupled to the negative front surface electrode via a through electrode; and at least one relay back surface electrode which is coupled to the at least one relay front surface electrode via a through electrode.

Abstract: Ceramic granules for producing sintered products of silicon nitride that can be favorably used as structural materials for various heat engines such as automotive parts, gas turbines and the like, and as abrasion resistant materials and corrosion resistant materials. A process for preparing the ceramic granules and a process for preparing sintered products of silicon nitride by using the ceramic granules. Ceramic granules comprise a mixture of a silicon nitride powder, a silicon powder and an assistant, as well as an organic binder, said ceramic granules having an average particle diameter of from 50 to 300 .mu.m and a relative density of from 18 to 30%.