Abstract: A micro-electro-mechanical systems (MEMS) package includes a MEMS microphone device. The MEMS microphone device has a first substrate and at least a sensing element on the first substrate wherein a first chamber in the MEMS microphone device is connected to the sensing element. A second substrate is disposed over the MEMS microphone device to provide a second chamber in the second substrate over the sensing element opposite to the first chamber.

Abstract: The present invention provides a MEMS device, be implemented on many MEMS device, such as MEMS microphone, MEMS speaker, MEMS accelerometer, MEMS gyroscope. The MEMS device includes a substrate. A dielectric structural layer is disposed over the substrate, wherein the dielectric structural layer has an opening to expose the substrate. A diaphragm layer is disposed over the dielectric structural layer, wherein the diaphragm layer covers the opening of the dielectric structural layer to form a chamber. A conductive electrode structure is adapted in the diaphragm layer and the substrate to store nonvolatile charges.

Abstract: A micro-electro-mechanical systems (MEMS) device includes a back-plate substrate, having an intended region formed with a plurality of perforating holes. A first structural dielectric layer, disposed on the back-plate substrate, wherein the dielectric layer having an opening above the intended region. An etching stop layer, disposed over the first structural dielectric layer. A second structural dielectric layer, formed over the back-plate substrate. The etching stop layer and the second structural dielectric layer form at least a part of a micro-machine diaphragm, and cover over the opening of the first structural dielectric layer to form a chamber between the micro-machine diaphragm and the back-plate substrate.

Abstract: A method for fabricating non-volatile memory on a substrate includes forming a plurality of doped lines in the substrate along a first direction, wherein the doped lines serve as a plurality of bit lines, and portions of each of the doped lines serves as source/drain regions for a plurality of memory cells. A charge storage stacked layer is formed over the substrate, wherein the charge storage stacked layer includes a charge trapping layer. A conductive layer is formed over the charge storage layer. The conductive layer and the charge storage stacked layer are patterned to form a plurality of word lines along a second direction, intersecting with the first directing. The remaining portion of the charge trapping layer is just under the word lines, not covering the isolation region between the word lines.

Abstract: A nonvolatile memory device includes composite gate structures formed on a substrate in series along a bit line direction. The composite gate structure has a first storage gate structure, a second storage gate structure, and a selection gate between the two storage gate structures. Each of the composite gate structures is respectively coupled to two world line connection terminals at the two storage gate structures and a selection terminal at the selection gate. Each of the storage gate structures corresponds to a memory bit cell. Multiple doped regions are in the substrate between the composite gate structures. A first selection doped region are formed in the substrate and coupled between a BL connection terminal and a first edge one of the composite gate structure. A second selection doped region is formed in the substrate and coupled between a second edge one of the composite gate structures and a voltage terminal.

Abstract: A nonvolatile memory device, including composite gate structures formed on a substrate in series along a bit line (BL) direction. Each of the composite gate structures has a first storage gate, a second storage gate, and a selection gate between the two storage gates. Each of the composite gate structures is respectively coupled to two world line (WL) connection terminals at the two storage gates and a selection terminal at the selection gate. Each of the storage gates corresponds to a memory bit cell. Multiple doped regions are in the substrate between the composite gate structures. A first selection doped region are formed in the substrate and coupled between a BL connection terminal and a first edge one of the composite gate structure. A second selection doped region is formed in the substrate and coupled between a second edge one of the composite gate structures and a voltage terminal.

Abstract: The present invention discloses a power-efficient encoder architecture for address stream on bus and a power-efficient encoding method for address stream on bus. In the design of the encoder architecture, a encoder is installed on the path along which the address stream flows from the central processing unit to a bus, and another encoder is installed on the path along which the address stream flows from the bus to a memory, and the aforementioned encoders all have the encode/decode function.

Abstract: A structure of non-volatile memory has a plurality of buried bit lines in a substrate, extending along a first direction. Selection gate structure lines are located between the buried bit lines. A plurality of stack dielectric films on the both sides of the selection gate structure lines serving as a charge storage region, does not extend to the bit lines and a dielectric layer contacting a surface of substrate adjacent to stacked dielectric films. Word lines are over the substrate, wherein stacked dielectric films and a dielectric layer are interposed between WL and substrate on the region excluding the selection gate structure line, extending along a second direction different from the first direction. Since the charge storage layer does not completely cover between the selection gate structure lines and the bit lines, an additional control gate is formed.

Abstract: A structure of non-volatile memory has a plurality of buried bit lines in a substrate, extending along a first direction. Selection gate structure lines are located between the buried bit lines. A plurality of stack dielectric films on the both sides of the selection gate structure lines serving as a charge storage region, does not extend to the bit lines and a dielectric layer contacting a surface of substrate adjacent to stacked dielectric films. Word lines are over the substrate, wherein stacked dielectric films and a dielectric layer are interposed between WL and substrate on the region excluding the selection gate structure line, extending along a second direction different from the first direction. Since the charge storage layer does not completely cover between the selection gate structure lines and the bit lines, an additional control gate is formed.

Abstract: A structure of non-volatile memory has a plurality of buried bit lines in a substrate, extending along a first direction. Selection gate structure lines are located between the buried bit lines. A plurality of stack dielectric films on the both sides of the selection gate structure lines serving as a charge storage region, does not extend to the bit lines and a dielectric layer contacting a surface of substrate adjacent to stacked dielectric films. Word lines are over the substrate, wherein stacked dielectric films and a dielectric layer are interposed between WL and substrate on the region excluding the selection gate structure line, extending along a second direction different from the first direction. Since the charge storage layer does not completely cover between the selection gate structure lines and the bit lines, an additional control gate is formed.

Abstract: A structure of non-volatile memory has a plurality of buried bit lines in a substrate, extending along a first direction. Selection gate structure lines are located between the buried bit lines. A plurality of stack dielectric films on the both sides of the selection gate structure lines serving as a charge storage region, does not extend to the bit lines and a dielectric layer contacting a surface of substrate adjacent to stacked dielectric films. Word lines are over the substrate, wherein stacked dielectric films and a dielectric layer are interposed between WL and substrate on the region excluding the selection gate structure line, extending along a second direction different from the first direction. Since the charge storage layer does not completely cover between the selection gate structure lines and the bit lines, an additional control gate is formed.

Abstract: A heat dissipator includes a base and a plurality of connecting portions formed thereon. The base is further combined with a fan provided with a plurality of air outlets. The connecting portions are adapted to mount a heat-generating member and a heat-conducting module. The heat-conducting module includes a heat-conducting plate attached to a surface of the heat-generating member, and a heat-conducting tube mounted thereon. The heat-conducting tube is bent to form two extensions having an appropriated included angle therebetween. Each of the extensions of the heat-conducting tube is connected with a plurality of fins, which are positioned and thus aligned with the air outlets of the fan.

Abstract: A heat dissipator includes a base and a plurality of connecting portions formed thereon. The base is further combined with a fan provided with a plurality of air outlets. The connecting portions are adapted to mount a heat-generating member and a heat-conducting module. The heat-conducting module includes a heat-conducting plate attached to a surface of the heat-generating member, and a heat-conducting tube mounted thereon. The heat-conducting tube is bent to form two extensions having an appropriated included angle therebetween. Each of the extensions of the heat-conducting tube is connected with a plurality of fins, which are positioned and thus aligned with the air outlets of the fan.