Abstract: A wireless power transmission device includes a transmission device and a control device. The control device generates a driving signal to the transmission device in a first soft-start period, so as to drive the transmission device. The control device measures an energy message generated by the transmission device to generate a measurement result in a measurement period, and calculates a signal parameter according to the measurement result. The control device accordingly generates a carrier signal according to the signal parameter obtained by the measurement period in a second soft-start period. In a transmission period, the carrier signal is transmitted to the wireless power-receiving device through the transmission device. The energy message is generated by the transmission device in response to a distance between the transmission device and the wireless power-receiving device.

Abstract: An inspection machine capable of inspecting optical property and electrical property of a light emitting device is provided. The inspection machine includes a substrate table, a probe mechanism, a heating apparatus, a cooling apparatus, an image-sensing apparatus, a temperature-sensing apparatus and a moving mechanism. The probe mechanism is capable of moving toward the light emitting device to contact therewith. The heating apparatus is capable of heating the light emitting device within a first temperature range. The cooling apparatus is capable of cooling the light emitting device within a second temperature range. The image-sensing apparatus senses a light emitting image provided from the light emitting device. The temperature-sensing apparatus senses the present temperature of the light emitting device. The image-sensing apparatus is disposed on the moving mechanism. The moving mechanism is capable of moving the image-sensing apparatus.

Abstract: An inspection machine capable of inspecting optical property and electrical property of a light emitting device is provided. The inspection machine includes a substrate table, a probe mechanism, a heating apparatus, a cooling apparatus, an image-sensing apparatus, a temperature-sensing apparatus and a moving mechanism. The probe mechanism is capable of moving toward the light emitting device to contact therewith. The heating apparatus is capable of heating the light emitting device within a first temperature range. The cooling apparatus is capable of cooling the light emitting device within a second temperature range. The image-sensing apparatus senses a light emitting image provided from the light emitting device. The temperature-sensing apparatus senses the present temperature of the light emitting device. The image-sensing apparatus is disposed on the moving mechanism. The moving mechanism is capable of moving the image-sensing apparatus.

Abstract: A fault detection system comprises a data server configured to collect parameters incoming from at least one apparatus, at least one fault-sensing module configured to generate an alarm signal if the parameter exceeds a predetermined specification, a monitoring module configured to restart the fault-sensing module if the fault-sensing module operates abnormally, and a remote controller configured to control the data server, the fault-sensing module, and the monitoring module.

Abstract: An IC chip/substrate assembly bonded together by a non-conductive adhesive and a method for forming the assembly. The assembly consists of an IC chip that has bumps formed on an active surface, a substrate that has bond pads formed on a top surface, wherein at least one of the IC chip and the substrate has dummy bumps formed in-between the bumps or the bond pads, and a non-conductive adhesive disposed in between and bonding the IC chip and the substrate together in a face-to-face relationship with the bumps in electrical communication with the bond pads.

Abstract: An IC chip/substrate assembly bonded together by a non-conductive adhesive and a method for forming the assembly. The assembly consists of an IC chip that has bumps formed on an active surface, a substrate that has bond pads formed on a top surface, wherein at least one of the IC chip and the substrate has dummy bumps formed in-between the bumps or the bond pads, and a non-conductive adhesive disposed in between and bonding the IC chip and the substrate together in a face-to-face relationship with the bumps in electrical communication with the bond pads.

Abstract: An IC chip/substrate assembly bonded together by a non-conductive adhesive and a method for forming the assembly. The assembly consists of an IC chip that has bumps formed on an active surface, a substrate that has bond pads formed on a top surface, wherein at least one of the IC chip and the substrate has dummy bumps formed in-between the bumps or the bond pads, and a non-conductive adhesive disposed in between and bonding the IC chip and the substrate together in a face-to-face relationship with the bumps in electrical communication with the bond pads.

Abstract: A vertical nanotube transistor and a process for fabricating the same. First, a source layer and a catalyst layer are successively formed on a substrate. A dielectric layer is formed on the catalyst layer and the substrate. Next, the dielectric layer is selectively removed to form a first dielectric mesa, a gate dielectric layer spaced apart from the first dielectric mesa by a first opening, and a second dielectric mesa spaced apart from the gate dielectric layer by a second opening. Next, a nanotube layer is formed in the first opening. Finally, a drain layer is formed on the nanotube layer and the first dielectric mesa, and a gate layer is formed in the second opening. The formation position of the nanotubes can be precisely controlled.

Abstract: An IC chip/substrate assembly bonded together by a non-conductive adhesive and a method for forming the assembly. The assembly consists of an IC chip that has bumps formed on an active surface, a substrate that has bond pads formed on a top surface, wherein at least one of the IC chip and the substrate has dummy bumps formed in-between the bumps or the bond pads, and a non-conductive adhesive disposed in between and bonding the IC chip and the substrate together in a face-to-face relationship with the bumps in electrical communication with the bond pads.

Abstract: A vertical nanotube transistor and a process for fabricating the same. First, a source layer and a catalyst layer are successively formed on a substrate. A dielectric layer is formed on the catalyst layer and the substrate. Next, the dielectric layer is selectively removed to form a first dielectric mesa, a gate dielectric layer spaced apart from the first dielectric mesa by a first opening, and a second dielectric mesa spaced apart from the gate dielectric layer by a second opening. Next, a nanotube layer is formed in the first opening. Finally, a drain layer is formed on the nanotube layer and the first dielectric mesa, and a gate layer is formed in the second opening. The formation position of the nanotubes can be precisely controlled.

Abstract: A method for bonding an IC chip by a non-conductive adhesive that contains between about 5 weight % and about 25 weight % of a non-conductive filler is described. The filler particles in the filler material must have a hardness that is higher, and preferably at least two times higher, than the metal material forming the bump. Moreover, the filler particles must be non-electrically conductive such that electrical shorts between a plurality of bumps on the IC chip do not occur. The concentration of the filler in the adhesive must be high enough so as to reduce the CTE of the adhesive to match that of the IC chip and the substrate, and low enough so as not to impede the electrical communication between the bumps on the IC chip and the bond pads on the substrate.