Abstract: A median filter device is provided with a reordered circuit, a comparison circuit and a data refresh circuit on the basis of the conventional data buffer circuit and data register circuit. The reorder circuit re-sorts the signal data stored in the data buffer circuit in a preceding clock cycle according to their numerical values. The comparison circuit compares the new signal datum entered in the current clock cycle with the signal data already stored to generate a median. The data refresh circuit updates the signal codes stored in the data register circuit with the signal codes corresponding to the new signal data, for calculation of the median in a following clock cycle. The length of the data buffer circuit and data register circuit can be reduced from N signal data to N-1 signal data, which achieves less data storage capacity, smaller circuit area, easier data processing and higher operation efficiency.

Abstract: A MEMS microphone structure, comprising a semiconductor substrate having a cavity, a first dielectric layer having a through-hole communicating with the cavity, a lower diaphragm electrode formed above the through-hole and at least partially attached to the upper surface of the first dielectric layer, and an upper electrode structure with an insulating layer. The upper electrode structure comprises an annular supporter, a back plate having multiple holes, and an upper electrode connection. At least a part of the annular supporter extends downwardly to the lower diaphragm electrode while the rest of the annular supporter extends downwardly to the substrate. The back plate is suspended above the lower diaphragm electrode by the annular supporter, forming an air gap therebetween. An upper electrode is embedded in the insulating layer at the back plate and is lead out by the upper electrode connection.

Abstract: A method for processing an electroplated copper film in copper interconnect process is disclosed by the present invention. Firstly, in the copper back-end-of-line interconnect process, the first annealing process for the electroplated copper film is performed at or below 180° C.; then, after the copper back-end-of-line interconnect process, another annealing process with higher temperature (equal or above 240° C.) to the electroplated copper film is performed to make the copper recrystallize, so as to decrease the resistivity of the electroplated copper film and form an interface state having lower resistivity at the interface of the vias bottom, which decrease the contact resistance between the vias and the underlying copper interconnects and further reduce the RC time delay in the vias. The present invention can be applied in the Cu/Low-k back-end-of-line interconnect process and compatible with the standard Cu/Low-k back-end-of-line process integration.

Abstract: A line-end cutting method for fin structures of FinFETs formed by double patterning technology firstly utilizes the SiN hard mask lines to form fin structures and then performs lithography and etching processes to form line-end cuts. Since the depth of the line-end cuts is large, there is enough time and space to regulate the etching recipe so as to balance the etching rate of multiple layers including the spin-on-carbon layer, the SiN layer, the SiO2 layer and the silicon substrate, thereby forming the fin structures with line-end cuts having flatter bottom topography, preventing the formation of silicon protrusions or silicon cones during the etching process and improving the device electrical performance.

Abstract: A method is provided for designing an IC chip. The method includes receiving data from a pre-layout design process for the IC chip, routing a plurality of interconnecting wires to connect various devices of the IC chip, and extracting various circuit parameters. The method also includes simulating the IC chip using the extracted various circuit parameters to detect logic or timing error in the IC chip. The extracting the various circuit parameters includes establishing a statistical interconnect technology profile (ITP) file containing at least interconnect parasitic parameters based on correlations of interconnect layer geometric parameter variations.

Abstract: A manufacturing method is provided for fabricating a vertical channel gate-all-around MOSFET by epitaxy processes. The method includes growing a first epitaxial layer on a top semiconducting layer of a substrate; etching the first epitaxial layer and the top layer to form a first source/drain pattern in the top layer; etching the first epitaxial layer to form a vertical channel structure; then forming a gate dielectric layer on the vertical channel structure surface; forming a sandwich structure composed of a bottom spacer layer, a gate electrode layer and a top spacer layer; etching the top spacer layer and the gate electrode layer to form a gate pattern followed by forming a top spacer structure thereon; growing a second epitaxial layer and etching to form a second source/drain pattern.

Abstract: A method is provided for manufacturing a semiconductor device with a metal film resistor structure. The method includes providing an insulation layer on the semiconductor device. A lower copper interconnect is formed in the insulation layer. The method also includes forming a cap layer on the insulation layer and the lower copper interconnect and etching the cap layer based on a single photolithography mask to form a window exposing portion of the lower copper interconnect and portion of the insulation layer. Further, the method includes forming a metal film layer on the cap layer and inside the window such that exposed portion of the lower copper interconnect is connected with part of the metal film layer within the window. The method also includes performing a chemical mechanical polishing (CMP) process to form a metal film resistor based on the metal film layer. The metal film resistor is connected with the portion of the lower copper interconnect.

Abstract: A silicon nanowire bio-chip structure and a manufacturing method thereof. The structure comprises a semiconductor substrate (1), a SiO2 insulating layer (2) formed on the semiconductor substrate, a polysilicon layer (3) formed on the SiO2 insulating layer (2) and a structural layer formed on the polysilicon layer (3); wherein, the polysilicon layer (3) comprises a patterned silicon nanowire array (4); the structural layer includes a SiON layer, a TaN and/or Ta2O5 layer (6) from bottom to top, the TaN and/or Ta2O5 layer only covers surface of each silicon nanowire in the silicon nanowire array. The silicon nanowire array is prevented from being polluted during preservation and use, and the pollutants of Na ions, K ions, Fe ions, Cu ions and Ca ions as well as the effects of chemical factors including the PH value are blocked during biological detection, thereby achieving the high stability of detection.

Abstract: A method for repairing damages to sidewalls of an ultra-low dielectric constant film is disclosed by the present invention comprises the following steps: depositing an ultra-low dielectric constant film on an semiconductor substrate; dry-etching the ultra-low dielectric constant film to form a sidewall structure thereof; performing wet cleaning by using a chemical agent containing an unsaturated hydrocarbon having —O—C(Re)x; and performing ultraviolet curing. The present invention can restore pores size and porosity of the ultra-low dielectric constant film, and to keep effective dielectric constant to a minimum.

Abstract: The present invention relates to an interconnection structure and a method for fabricating the same. According to the present invention, cavities are formed between the interconnection dielectric by using a sacrificial layer, carbon nanotubes are used as the interconnection material for local interconnection between via holes, graphene nanoribbons are used as the interconnection material for metal lines, and cavities are included in the interconnection dielectric. In addition, the conventional CMOS BEOL Cu interconnection technique is applied to the intermediate interconnection level and the global interconnection level. In this way, the high parasitic resistance and parasitic capacitance in the Cu interconnection technique, which may occur when the local interconnection is relatively small in size, can be effectively overcome.

Abstract: A pixel structure of a CMOS image sensor pixel structure and a manufacturing method thereof. The structure comprises a photosensitive element (37) and a multi-layer structure of a standard CMOS device arranged on the silicon substrate (31). A deep groove (38) having a light-transmitting space therein is formed above the photosensitive element, a side wall of the deep groove is surrounded by a light reflection shielding layer (39) continuously arranged in a longitudinal direction to reflect the light incident on the light reflection shielding layer. The side wall of the deep groove is surrounded by metal interconnects, vias, contact holes and polysilicon in annular configurations, thus the incident light on the deep grove is substantially completely reflected, which avoids the optical crosstalk and effectively improves the optical resolution and sensitivity of the pixel and the performance and reliability of the chip.

Abstract: A method is disclosed for manufacturing a semiconductor device with a copper interconnect structure. The method includes providing a substrate, forming a first interconnect dielectric layer on the substrate, and forming a second interconnect dielectric layer on a surface of the first interconnect dielectric layer. The method also includes forming a plurality of conduits extending through the first interconnect dielectric layer and the second interconnect dielectric layer, and depositing copper in the plurality of conduits to form a copper interconnect layer of the copper interconnect structure. Further, the first interconnect dielectric layer, between neighboring conduits, contains cavities such that dielectric constant of the first interconnect dielectric layer is reduced. The second interconnect dielectric layer seals the top of the cavities, the substrate is the bottom of the cavities, and a width of the top of the cavities is less than a width of the bottom of the cavities.

Abstract: The present invention provides a guarding ring structure of a semiconductor high voltage device and the manufacturing method thereof. The guarding ring structure comprises a first N type monocrystalline silicon substrate (3), a second N type monocrystalline silicon substrate (8), a discontinuous oxide layer (2), a metal field plate (1), a device region (9), multiple P+ type diffusion rings (5) and an equipotential ring (4). The second N type monocrystalline silicon substrate (8) is a single N type crystalline layer epitaxially formed on the first N type monocrystalline silicon substrate (3) and has lower doping concentration than the first N type monocrystalline silicon substrate (3). N type diffusion rings (6) are embedded in the inner side of the P+ type diffusion rings (5) and are fully depleted at zero bias voltage. The guarding ring structure can achieve the same withstand voltage with less area and design time.

Abstract: The present invention provides an IR-UWB data transmission encoding/decoding method and module. The encoding method comprises: in each unit time period lasting T seconds, receiving an N-bit of binary data of an M-bit binary data stream and generating UWB impulse radio signal having a specific frequency fi, determining and generating an amplitude value Ax of the UWB impulse radio signal having the specific frequency fi according to the remaining M-N bits binary data, and finally transmitting the UWB impulse radio signal having the specific frequency fi and the amplitude value. The decoding method corresponds to the encoding method. According to the present invention, the data transmission rate can be increased by four times compared with the conventional data transmission rate without increasing the circuit complexity, which is useful and attractive to the IR-UWB system.

Abstract: A radio frequency identification (RFID) device is disclosed. The RFID device includes a silicon substrate having a top side and a bottom side. The RFID device also includes a plurality of circuitry layers formed on the top side of the substrate, and the plurality of circuitry layers include at least a core circuitry and an on-chip antenna. Further, the RFID device includes a plurality of deep openings formed in the substrate on the bottom side under the plurality of circuitry layers. The plurality of deep openings are arranged in an array and through a substantial portion of the substrate, and a remaining portion of the substrate unreached by the plurality of deep openings separates the plurality of deep openings and the plurality of circuitry layers.

Abstract: The present invention provides a multi-system multi-band RFID antenna, which comprises an on-chip antenna and at least one external antenna, wherein the on-chip antenna is arranged on RFID chip; the external antennas are arranged outside the RFID chip; and the RFID chip is provided with connection pads on the outer surface, wherein both the on-chip antenna and the external antennas are connected with the RFID chip through the connection pads. According to the multi-system multi-band RFID antenna of the present invention, the RFID chip can provide appropriate antennas for applications in different systems with different frequency bands, and can satisfactorily meet the need for RFID multi-system integration applications in the future.

Abstract: A method is provided for manufacturing a semiconductor device with a metal film resistor structure. The method includes providing an insulation layer on the semiconductor device. A lower copper interconnect is formed in the insulation layer. The method also includes forming a cap layer on the insulation layer and the lower copper interconnect and etching the cap layer based on a single photolithography mask to form a window exposing portion of the lower copper interconnect and portion of the insulation layer. Further, the method includes forming a metal film layer on the cap layer and inside the window such that exposed portion of the lower copper interconnect is connected with part of the metal film layer within the window. The method also includes performing a chemical mechanical polishing (CMP) process to form a metal film resistor based on the metal film layer. The metal film resistor is connected with the portion of the lower copper interconnect.

Abstract: A radio frequency identification (RFID) device is disclosed. The RFID device includes a silicon substrate having a top side and a bottom side. The RFID device also includes a plurality of circuitry layers formed on the top side of the substrate, and the plurality of circuitry layers include at least a core circuitry and an on-chip antenna. Further, the RFID device includes a plurality of deep openings formed in the substrate on the bottom side under the plurality of circuitry layers. The plurality of deep openings are arranged in an array and through a substantial portion of the substrate, and a remaining portion of the substrate unreached by the plurality of deep openings separates the plurality of deep openings and the plurality of circuitry layers.

Abstract: A method is disclosed for manufacturing a semiconductor device with a copper interconnect structure. The method includes providing a substrate, forming a first interconnect dielectric layer on the substrate, and forming a second interconnect dielectric layer on a surface of the first interconnect dielectric layer. The method also includes forming a plurality of conduits extending through the first interconnect dielectric layer and the second interconnect dielectric layer, and depositing copper in the plurality of conduits to form a copper interconnect layer of the copper interconnect structure. Further, the first interconnect dielectric layer, between neighboring conduits, contains cavities such that dielectric constant of the first interconnect dielectric layer is reduced. The second interconnect dielectric layer seals the top of the cavities, the substrate is the bottom of the cavities, and a width of the top of the cavities is less than a width of the bottom of the cavities.

Abstract: The present invention relates to an interconnection structure and a method for fabricating the same. According to the present invention, cavities are formed between the interconnection dielectric by using a sacrificial layer, carbon nanotubes are used as the interconnection material for local interconnection between via holes, graphene nanoribbons are used as the interconnection material for metal lines, and cavities are included in the interconnection dielectric. In addition, the conventional CMOS BEOL Cu interconnection technique is applied to the intermediate interconnection level and the global interconnection level. In this way, the high parasitic resistance and parasitic capacitance in the Cu interconnection technique, which may occur when the local interconnection is relatively small in size, can be effectively overcome.