摘要:
A process for manufacturing an integrated device includes the steps of: providing a silicon substrate on which a silicon dioxide structure is arranged and forming a trench having first and second essentially vertical walls relative to the substrate in the structure by means of anisotropic-type etching. A concavity having a sloped wall relative to the substrate is formed by isotropic-type etching which removes the second wall so that the concavity is open to the trench and the sloped wall faces the first wall.
摘要:
A process for manufacturing an integrated device includes the steps of: providing a silicon substrate on which a silicon dioxide structure is arranged; and forming a trench having first and second essentially vertical walls relative to the substrate in the structure by means of anisotropic-type etching. A concavity having a sloped wall relative to the substrate is formed by isotropic-type etching which removes the second wall so that the concavity is open to the trench and the sloped wall faces the first wall.
摘要:
The invention relates to a process for manufacturing an integrated optical device. The method involves forming a silicon dioxide multilayer structure on a silicon substrate containing, in a first region a core layer of a waveguide of the optical device. The core includes an electromagnetic radiation inlet/outlet A trench in a second region of the multilayer structure adjacent said first region is formed by a an anisotropic etching, the trench including side walls and a bottom wall spaced from the Substrate. The method further involves forming a coating layer of the side walls and the bottom wall of the trench; defining an opening in the bottom wall by at least partially removing the coating layer in order to expose the lower silicon dioxide of the multilayer structure; performing an isotropic etch through said opening in order to remove, starting from the exposed silicon dioxide, the multilayer structure silicon dioxide until forming a recess in the multilayer structure having a first wall at least one essentially planar portion inclined relative to the substrate. Such inclined portion extends at least partially in the first region, and includes the inlet/outlet port.
摘要:
The invention relates to a process for manufacturing an integrated optical device. The method involves forming a silicon dioxide multilayer structure on a silicon substrate containing, in a first region a core layer of a waveguide of the optical device. The core includes an electromagnetic radiation inlet/outlet A trench in a second region of the multilayer structure adjacent said first region is formed by a an anisotropic etching, the trench including side walls and a bottom wall spaced from the Substrate. The method further involves forming a coating layer of the side walls and the bottom wall of the trench; defining an opening in the bottom wall by at least partially removing the coating layer in order to expose the lower silicon dioxide of the multilayer structure; performing an isotropic etch through said opening in order to remove, starting from the exposed silicon dioxide, the multilayer structure silicon dioxide until forming a recess in the multilayer structure having a first wall at least one essentially planar portion inclined relative to the substrate. Such inclined portion extends at least partially in the first region, and includes the inlet/outlet port.
摘要:
A packaging structure for optoelectronic components is formed by a first body, of semiconductor material, and a second body, of semiconductor material, fixed to a first face of said first body. A through window is formed in the second body and exposes a portion of the first face of the first body, whereon at least one optoelectronic component is fixed. Through connection regions extend through the first body and are in electrical contact with the optoelectronic component. The through connection regions are insulated from the rest of the first body via through insulation regions. Contact regions are arranged on the bottom face of the first body and are connected to said optoelectronic component via the through connection regions.
摘要:
A packaging structure for optoelectronic components is formed by a first body, of semiconductor material, and a second body, of semiconductor material, fixed to a first face of said first body. A through window is formed in the second body and exposes a portion of the first face of the first body, whereon at least one optoelectronic component is fixed. Through connection regions extend through the first body and are in electrical contact with the optoelectronic component. The through connection regions are insulated from the rest of the first body via through insulation regions. Contact regions are arranged on the bottom face of the first body and are connected to said optoelectronic component via the through connection regions.
摘要:
A lighting device (100) including light radiation sources that can be mixed (102) to produce multi-chromatic light radiation (W; W1, W2, W3, W4; WS) as an additive mixture of the radiations generated by said sources, comprising a plurality of sets (1, 1′; 2, 2′; 3, 3′; 1, 2, 3; 1′, 2′, 3′; 1, 1′; 2, 2′; 3, 3′; 4, 4′; 1, 2, 3, 4, 5, 6) of light radiation sources, wherein each set includes light radiation sources that can be mixed (102) to produce multi-chromatic light radiation through additive mixing of the radiations generated by the sources in the set; and a control device (10, 10′, 1000) to selectively activate the sets (1, 1′; 2, 2′; 3, 3′; 1, 2, 3; 1′, 2′, 3′; 1, 1′; 2, 2′; 3, 3′; 4, 4′; 1, 2, 3, 4, 5, 6) of radiation sources in said plurality
摘要:
A coupling structure for coupling optical radiation, i.e., light, between an optical fibre and an optical device, e.g., a laser diode or a photodiode. The coupling structure has an optical through-via which guides the optical radiation to or from the optical fibre. Light exiting the fibre travels through a guidance channel so it remains substantially confined to a narrow optical path that mimics the fibre core. Conversely, light enters the fibre after having traveled through the guidance channel. The guidance channel has a first core region, the “channel core”, having first refractive index surrounded by a second region, the “channel cladding” having a second refractive index smaller than the first refractive index. The coupling structure, including the guidance channel, is preferably made of semiconductor-based material, more preferably of silicon-based material. The guidance channel is preferably silicon oxide. The coupling structure further has a fibre drive-in element, which facilitates insertion and alignment of the optical fibre to the guidance channel.
摘要:
Laminated sheet material 9 comprises a laminate of a polyvinyl alcohol or other water-disintegratable film 12 with a thin coextruded film comprising a melt-bondable layer 15 and an impermeable layer 14. The laminate is odor impermeable but water disposable and so can be used to form a toilet-disposable ostomy bag by melt-sealing around the edges 10 between the facing melt-sealable surfaces 15.
摘要:
A method for bidirectional optical communication comprising the steps of:—at a first optical line terminal, directly modulating a laser source to generate a downstream optical signal which has an optical power spectrum comprising two peaks having a frequency separation and a non zero power difference at generation;—propagating said downstream optical signal at a distance along an optical line comprising at least a first optical fiber propagating said downstream optical signal to a second optical line terminal;—at the second optical line terminal: power splitting said downstream optical signal to generate a first and a second power portion of said downstream optical signal, spatially separated; passive filtering said first power portion of said downstream optical signal so as to increase in absolute value a respective power difference of said two peaks, so as to obtain a filtered optical signal which is thereafter detected; and amplitude modulating the second power portion of the downstream optical signal so as to obtain an upstream optical signal having a second amplitude modulation;—propagating back along said optical line the upstream optical signal to the first optical line terminal;—at said first optical line terminal, detecting said upstream optical signal; wherein the method further comprises the step of passive filtering said downstream optical signal and/or said second power portion of the downstream optical signal and/or said upstream optical signal, so as to lower, in absolute value, a respective non zero power difference of said two peaks.