Abstract: A transparent display panel with driving electrode regions, circuit wiring regions, and optically transparent regions is provided. The driving electrode regions are arranged into an array in a first direction and a second direction. An average light transmittance of the circuit wiring regions is less than ten percent, and an average light transmittance of the optically transparent regions is greater than that of the driving electrode regions and the circuit wiring regions. The first direction intersects the second direction. The circuit wiring regions connect the driving electrode regions at intervals, such that each optically transparent region spans among part of the driving electrode regions. The transparent display panel includes first signal lines and second signal lines extending along the circuit wiring regions, and each circuit wiring region is provided with at least one of the first signal lines and at least one of the second signal lines.

Abstract: An intelligent IIoT system using two-way channel ANN without gateway, the intelligent IIoT system is connected to sensing devices and motion devices. comprising a PLC with I/O module, communication module, perception database, motion database, edge computing module and the first MQTT data module; a Cloud server with MQTT agent, Big Data module, Human-Cloud visual database and Human-Cloud control database; and a remote device with Human-Cloud visual interface program, Human-Cloud control interface program and the second MQTT data module; and the three components are connected via network; it is unnecessary to construct gateways and network communication equipment, low construction cost, short construction period, easy maintenance, low power consumption, faster communication speed, two-way many-many transmission, stably synchronous real-time processing, and very reliable.

Abstract: An intelligent IIoT system using two-way channel ANN without gateway, the intelligent IIoT system is connected to sensing devices and motion devices. comprising a PLC with I/O module, communication module, perception database, motion database, edge computing module and the first MQTT data module; a Cloud server with MQTT agent, Big Data module, Human-Cloud visual database and Human-Cloud control database; and a remote device with Human-Cloud visual interface program, Human-Cloud control interface program and the second MQTT data module; and the three components are connected via network; it is unnecessary to construct gateways and network communication equipment, low construction cost, short construction period, easy maintenance, low power consumption, faster communication speed, two-way many-many transmission, stably synchronous real-time processing, and very reliable.

Abstract: A module for equalizing light in liquid crystal display, having a light source and at least one gapless microlens array, is described. The gapless microlens array has a substrate and a plurality of bumps located on the substrate, and the bumps are connected closely with each other so that there is no gap between the bumps. Light is gathered, equalized and diffused by using the gapless microlens array.

Abstract: A process of fabricating a non-gap 3-D microstructure array mold core comprises a first step in which a buffer layer is coated on a substrate. A photomask layer is then coated of the buffer layer. A pattern is subsequently formed on the photomask by photo-lithography. The patterned photomask layer is subjected to a reflow by which a microstructure array is formed on the photomask layer. The microstructure array is coated with a metal conductive layer. The microgaps of the microstructure array are eliminated by an electrocasting layer which is coated on the microstructure array. The non-gap microstructure array mold core so fabricated is made into a metal molding tool by microinjection molding or microthermo-pressure molding.

Abstract: A process of fabricating a non-gap 3-D microstructure array mold core comprises a first step in which a buffer layer is coated on a substrate. A photomask layer is then coated of the buffer layer. A pattern is subsequently formed on the photomask by photo-lithography. The patterned photomask layer is subjected to a reflow by which a microstructure array is formed on the photomask layer. The microstructure array is coated with a metal conductive layer. The microgaps of the microstructure array are eliminated by an electrocasting layer which is coated on the microstructure array. The non-gap microstructure array mold core so fabricated is made into a metal molding tool by microinjection molding or microthermo-pressure molding.

Abstract: The present invention provides a fabrication process for making an integrated micro spherical lens for an optical switch. Through a semiconductor micro imaging process and a wet-etching process of micro electromechanical working, a plurality of V-shape grooves and mesas are formed on the surface of a base. A further micro imaging process, an etching process and a heat tempering process are used to form a micro spherical lens on the mesa, so that an integrated micro spherical lens and fiber array can be precisely arranged.

Abstract: The present invention provides a fabrication process for making an integrated micro spherical lens for an optical switch. Through a semiconductor micro imaging process and a wet-etching process of micro electromechanical working, a plurality of V-shape grooves and mesas are formed on the surface of a base. A further micro imaging process, an etching process and a heat tempering process are used to form a micro spherical lens on the mesa, so that an integrated micro spherical lens and fiber array can be precisely arranged.

Abstract: A simple method for fabricating three-dimensional microlens in batch is disclosed. The method for fabricating three-dimensional microlens includes (A) providing a substrate;(B) coating a layer of first polymer or compositions comprising first polymer on said substrate; (C) coating a layer of second polymer or compositions comprising second polymer on said layer of first polymer; (D) forming patterns of said layer of second polymer or compositions comprising second polymer; (E) heating said substrate coated with said polymers to a temperature ranging from said glass transition temperature (Tg) of second polymer to said glass transition temperature (Tg) of first polymer; (F) maintaining said coated substrate at said temperature to form microlens; and (G) cooling said microlens.

Abstract: A simple method for fabricating three-dimensional microlens in batch is disclosed. The method for fabricating three-dimensional microlens includes (A) providing a substrate; (B) coating a layer of first polymer or compositions comprising first polymer on said substrate; (C) coating a layer of second polymer or compositions comprising second polymer on said layer of first polymer; (D) forming patterns of said layer of second polymer or compositions comprising second polymer; (E) heating said substrate coated with said polymers to a temperature ranging from said glass transition temperature (Tg) of second polymer to said glass transition temperature (Tg) of first polymer; (F) maintaining said coated substrate at said temperature to form microlens; and (G) cooling said microlens.

Abstract: A method of making a micro magneto-controlled optical path-guiding platform comprises an optical path-guiding platform, couples of the optical routes, a micro magneto-flux prism located at the intersection of the optical route on the topside of the platform, and a magnetic field generator oppositely mounted under the location of the micro magneto-flux prism of the platform bottom side respectively. Therefore, the reflection ratio and refraction ratio to the incident optical signal traveling through this designed micro magneto-flux prism will be completely manipulated by adjusting the magnetic field intensity that is generated by the magnetic generator. Conclusively, this invention can be used to change the traveling orientation of the optical route or control the optical energy intensity as desired.