Abstract: A flexible biomonitor comprises: a flexible substrate having a circuit apparatus, a hybrid sensor, a plurality of IC devices, a central processing module, a RF transmitter circuit, an antenna, and a power supply. Thereupon the flexible biomonitor can be plastered on the skin where the human body needs to be monitored to achieve the purposes of reducing occupied area, providing comfortable wear and achieve compactness, module expansion and EMI shielding. Besides, it is capable of remote real-time monitoring this signal to achieve the purpose of home care.

Abstract: A fiber waveguide optical subassembly uses the multi-mode fiber to increase the alignment tolerance between the active optical element and the waveguide. The filter is thinner to lower the dispersion due to the optical coupling gap. The subassembly further combines the optical bench to achieve passive positioning. Therefore it reduces the cost and enhances the transmission rate.

Abstract: A projector projecting several images simultaneously is provided. The projector includes a main body having a first opening and a second opening, and an optical system disposed in the main body and projecting a first image through the first opening and a second image through the second opening. The optical system includes a laser source comprising a plurality of mono laser sources, and a first reflector with a first reflective surface and a second reflective surface corresponding to the first opening and the second opening.

Abstract: An electrode and a method for forming the electrode. The electrode comprises: a substrate; and a plurality of metal particles adhering to the substrate. The method comprises steps of: providing a substrate; providing a solution including a solvent and a plurality of metal particles on the substrate; removing the solvent; and making the plurality of metal particles adhere to the substrate.

Abstract: A parallel optical subassembly module structure comprises an opto-electronic device array, a base with a reflecting slope, and a micro-lens array plate with an inclined plane provided with a specific angle. The optical signal emitted from the opto-electronic device array reflects by the reflecting slope and is incident into the inclined plane of the micro-lens array plate with the specific angle. The inclined plane rectifies the optical signal to output in horizontal direction. Then the optical signal couples with the external fibers through each micro lens of the micro-lens array. The pathway of receiving the optical signal is the same as described above, but in reverse direction.

Abstract: A flexible biomonitor comprises a flexible substrate, a circuit apparatus, a plurality of gauges, a RFID sensing chip, a micro-antenna, and a power supply. The flexible substrate has a plurality of through holes formed thereon. The circuit apparatus is electrically connected with the gauges via the through holes to sense and treat a physiological signal. The micro-antenna is electrically connected with the circuit apparatus to transmit this physiological signal. The power supply is designed to provide electric power. Thereupon the flexible biomonitor can be plastered on the skin where the human body needs to be monitored to achieve the purposes of reducing occupied area and providing comfortable wear. Besides, it is capable of remote real-time monitoring this signal to achieve the purpose of home care.

Abstract: A fiber waveguide optical subassembly uses the multi-mode fiber to increase the alignment tolerance between the active optical element and the waveguide. The filter is thinner to lower the dispersion due to the optical coupling gap. The subassembly further combines the optical bench to achieve passive positioning. Therefore it reduces the cost and enhances the transmission rate.

Abstract: A parallel optical subassembly module structure comprises an opto-electronic device array, a base with a reflecting slope, and a micro-lens array plate with an inclined plane provided with a specific angle. The optical signal emitted from the opto-electronic device array reflects by the reflecting slope and is incident into the inclined plane of the micro-lens array plate with the specific angle. The inclined plane rectifies the optical signal to output in horizontal direction. Then the optical signal couples with the external fibers through each micro lens of the micro-lens array. The pathway of receiving the optical signal is the same as described above, but in reverse direction.