Abstract: An optical system affixed to an electronic apparatus is provided, including a first optical module, a second optical module, and a third optical module. The first optical module is configured to adjust the moving direction of a first light from a first moving direction to a second moving direction, wherein the first moving direction is not parallel to the second moving direction. The second optical module is configured to receive the first light moving in the second moving direction. The first light reaches the third optical module via the first optical module and the second optical module in sequence. The third optical module includes a first photoelectric converter configured to transform the first light into a first image signal.

Abstract: A composite photovoltaic structure having the following components is illustrated. A first photovoltaic unit is disposed on a transparent substrate, and electrically connected to a second photovoltaic unit in parallel, and the second photovoltaic unit is stacked on the first photovoltaic unit. The first photovoltaic unit is disposed on a second transparent electrode layer, and a first transparent conductive layer is disposed on a top of the first photovoltaic unit and electrically connected to a first transparent electrode layer, and the second photovoltaic unit is disposed on the first transparent conductive layer. A second transparent conductive layer is disposed on the second photovoltaic unit and is electrically connected to the second transparent electrode layer.

Abstract: A manufacturing method of a composite photovoltaic structure including a step of forming a transparent electrode material, a step of forming a first photovoltaic unit, a step of forming a first insulation layer, a step of forming a first transparent conductive layer, a step of forming a second photovoltaic unit, a step of forming a second insulation layer, a step of forming a second transparent conductive layer and a step of splitting a product. Thus, the manufacturing method of the composite photovoltaic structure has a photoelectric reaction area of a significantly improved omnidirectional concentration gain, an efficiently induced current and a low manufacturing cost, without affecting the whole structure thickness.

Abstract: A packaging structure with groove includes a substrate, a lower conductive layer, an optical element, a sealing layer and a barrier layer. The lower conductive layer is arranged on one face of the substrate. The optical element is arranged on one face of the lower conductive layer. The upper conductive layer is arranged on one face of the optical element. The packaging structure further comprises a groove defined on an inactive area of the optical element. The sealing layer is arranged on one face of the optical element and on one face of the upper conductive layer. The barrier layer is arranged on one face of the sealing layer. Because the groove is formed on inactive area of the optical element to enhance lateral sealing tightness, extended interface is provided between sealing layer/barrier layer and the substrate, thus enhance the water-resistant and gas-resistant property for package.

Abstract: A manufacturing method of a composite photovoltaic structure including a step of forming a transparent electrode material, a step of forming a first photovoltaic unit, a step of forming a first insulation layer, a step of forming a first transparent conductive layer, a step of forming a second photovoltaic unit, a step of forming a second insulation layer, a step of forming a second transparent conductive layer and a step of splitting a product. Thus, the manufacturing method of the composite photovoltaic structure has a photoelectric reaction area of a significantly improved omnidirectional concentration gain, an efficiently induced current and a low manufacturing cost, without affecting the whole structure thickness.

Abstract: A composite photovoltaic structure having the following components is illustrated. A first photovoltaic unit is disposed on a transparent substrate, and electrically connected to a second photovoltaic unit in parallel, and the second photovoltaic unit is stacked on the first photovoltaic unit. The first photovoltaic unit is disposed on a second transparent electrode layer, and a first transparent conductive layer is disposed on a top of the first photovoltaic unit and electrically connected to a first transparent electrode layer, and the second photovoltaic unit is disposed on the first transparent conductive layer. A second transparent conductive layer is disposed on the second photovoltaic unit and is electrically connected to the second transparent electrode layer.

Abstract: A packaging structure with groove includes a substrate, a lower conductive layer, an optical element, a sealing layer and a barrier layer. The lower conductive layer is arranged on one face of the substrate. The optical element is arranged on one face of the lower conductive layer. The upper conductive layer is arranged on one face of the optical element. The packaging structure further comprises a groove defined on an inactive area of the optical element. The sealing layer is arranged on one face of the optical element and on one face of the upper conductive layer. The barrier layer is arranged on one face of the sealing layer. Because the groove is formed on inactive area of the optical element to enhance lateral sealing tightness, extended interface is provided between sealing layer/barrier layer and the substrate, thus enhance the water-resistant and gas-resistant property for package.

Abstract: An active RFID tag includes a first substrate, an electrically conductive layer disposed on the first substrate and etched or printed to form an antenna and a circuit, a thin film photovoltaic cell installed on the electrically conductive layer and electrically coupled to the electrically conductive layer, a thin film energy storage device installed on the electrically conductive layer and electrically coupled to the circuit of the electrically conductive layer, and an RFID chip installed on the electrically conductive layer and electrically coupled to the electrically conductive layer.

Abstract: An RFID device includes: at least one solar cell including a substrate, a first conductive layer, an electron supplying layer, an electron receiving layer and a second conductive layer sequentially stacked thereon; and a RFID tag coupled to the solar cell through a telecommunication connection structure, and including a first antenna, a second antenna and a RFID chip, and the RFID chip includes a first RFID module, a second RFID module and a radio frequency determination module. The first antenna and the first RFID module are capable of passively receiving a driving signal of an external device and returning tag data, and the radio frequency determination module is capable of automatically determining the external driving signal, and the second RFID module and the second antenna actively transmit the tag data to the external device according to the electric power supplied by the solar CELL.

Abstract: An RFID device includes: at least one solar cell including a substrate, a first conductive layer, an electron supplying layer, an electron receiving layer and a second conductive layer sequentially stacked thereon; and a RFID tag coupled to the solar cell through a telecommunication connection structure, and including a first antenna, a second antenna and a RFID chip, and the RFID chip includes a first RFID module, a second RFID module and a radio frequency determination module. The first antenna and the first RFID module are capable of passively receiving a driving signal of an external device and returning tag data, and the radio frequency determination module is capable of automatically determining the external driving signal, and the second RFID module and the second antenna actively transmit the tag data to the external device according to the electric power supplied by the solar CELL.

Abstract: An active RFID device includes at least one solar cell, and the solar cell includes: a substrate; a first conductive layer, disposed on the substrate; an electron supplying layer, disposed on the first conductive layer; an electron receiving layer, disposed on the electron supplying layer; and a second conductive layer, disposed on the electron receiving layer; and a RFID tag, including a RFID chip and an antenna, and installed on the substrate, and coupled to the solar cell through a telecommunication connection structure.

Abstract: The present invention discloses an improved temperature measuring apparatus, which at least comprises a temperature measurement device and a mobile electronic part. The temperature measurement device is provided with a temperature sensing unit, a signal processing unit and a first transmission unit. The signal processing unit is connected with the temperature sensing unit and the first transmission unit, respectively. The mobile electronic part is provided with a second transmission unit, a control unit, a display unit and a power supply. The control unit is connected with the second transmission unit, the display unit and the power supply, respectively, and the second transmission unit is connected with the first transmission unit so as to receive a measurement result from the temperature measurement device, and the display unit displays the measurement result. Therefore, the present invention has such effects as easy operation, plug-and-play, and timely measuring.

Abstract: A wireless endoscope apparatus mainly comprises an endoscope main body, a receiving host, a supporting stand and a power connecting wire. The receiving host is electrically connected to the endoscope main body through the power connecting wire. The receiving host can be supported and positioned on an application surface through the supporting stand. Moreover, a captured image is wirelessly transmitted by the signal transmitter of the endoscope main body to the receiving host. The image captured by the image pickup lens then is displayed by a display of the receiving host to avoid the restriction of transmission wires so that fields and explorations, such as medical care, house remodeling, transportation and maintenance, mechanical maintaining and research observation and so on, applied by the invention can be fast and convenient.