SHANGHAI HUA HONG NEC ELECTRONICS CO., LTD. Patent applications |
Patent application number | Title | Published |
20140124838 | HIGH SPEED SIGE HBT AND MANUFACTURING METHOD THEREOF - A high-speed SiGe HBT is disclosed, which includes: a substrate; STIs formed in the substrate; a collector region formed beneath the substrate surface and located between the STIs; an epitaxial dielectric layer including two portions, one being located on the collector region, the other being located on one of the STIs; a base region formed both in a region between and on surfaces of the two portions of the epitaxial dielectric layer; an emitter dielectric layer including two portions, both portions being formed on the base region; an emitter region formed both in a region between and on surfaces of the two portions of the emitter dielectric layer; a contact hole formed on a surface of each of the base region, the emitter region and the collector region. A method of manufacturing high-speed SiGe HBT is also disclosed. | 05-08-2014 |
20140093218 | SILICON-BASED OPTICAL FIBER CLAMP AND METHODS OF FABRICATING THE SAME - An optical fiber clamp and fabrication method thereof are disclosed. The optical fiber clamp includes one or more clamp units. Each clamp unit includes a clamp body formed of silicon, a guide hole formed under a top surface of the clamp body, the guide hole having an upper diameter greater than a lower diameter of the guide hole and having an inclined sidewall; and a locating hole connected to and extends downward from a bottom of the guide hole through the clamp body, the locating hole having an upper diameter equal to a lower diameter of the locating hole and smaller than the lower diameter of the guide hole. | 04-03-2014 |
20140061783 | SUPER-JUNCTION DEVICE AND METHOD OF FORMING THE SAME - A super-junction device including a unit region is disclosed. The unit region includes a heavily doped substrate; a first epitaxial layer over the heavily doped substrate; a second epitaxial layer over the first epitaxial layer; a plurality of first trenches in the second epitaxial layer; an oxide film in each of the plurality of first trenches; and a pair of first films on both sides of each of the plurality of first trenches, thereby forming a sandwich structure between every two adjacent ones of the plurality of first trenches, the sandwich structure including two first films and a second film sandwiched therebetween, the second film being formed of a portion of the second epitaxial layer between the two first films of a sandwich structure. A method of forming a super-junction device is also disclosed. | 03-06-2014 |
20140057405 | METHOD OF FABRICATING P-TYPE SURFACE-CHANNEL LDMOS DEVICE WITH IMPROVED IN-PLANE UNIFORMITY - A method of fabricating a P-type surface-channel laterally diffused metal oxide semiconductor device includes forming a gate structure with polysilicon and metal silicide, and the processes of channel implantation, long-time high-temperature drive-in, formation of a heavily doped N-type polysilicon sinker and boron doping of a polysilicon gate, are performed in this order, thereby ensuring the gate not to be doped with boron during its formation. The high-temperature drive-in process is allowed to be carried out to form a channel with a desired width, and a short channel effect which may cause penetration or electric leakage of the resulting device is prevented. As the polysilicon gate is not processed by any high-temperature drive-in process after it is doped with boron, the penetration of boron through a gate oxide layer and the diffusion of N-type impurity contained in the heavily doped polysilicon sinker into the channel or other regions are prevented. | 02-27-2014 |
20140051224 | METHOD OF BACK-SIDE PATTERNING - A method of back-side patterning of a silicon wafer is disclosed, which includes: depositing a protective layer on a front side of a silicon wafer; forming one or more deep trenches through the protective layer and extending into the silicon wafer by a depth greater than a target thickness of the silicon wafer; flipping over the silicon wafer and bonding the front side of the silicon wafer with a carrier wafer; polishing a back side of the silicon wafer; performing alignment by using the one or more deep trench alignment marks and performing back-side patterning process on the back side of the silicon wafer; and de-bonding the silicon wafer with the carrier wafer. | 02-20-2014 |
20140048879 | LDMOS DEVICE WITH STEP-LIKE DRIFT REGION AND FABRICATION METHOD THEREOF - An LDMOS device is disclosed. The LDMOS device includes: a substrate having a first type of conductivity; a drift region having a second type of conductivity and a doped region having the first type of conductivity both formed in the substrate; a drain region having the second type of conductivity and being formed in the drift region, the drain region being located at an end of the drift region farther from the doped region; and a buried layer having the first type of conductivity and being formed in the drift region, the buried layer being in close proximity to the drain region and having a step-like bottom surface, and wherein a depth of the buried layer decreases progressively in a direction from the drain region to the doped region. A method of fabricating LDMOS device is also disclosed. | 02-20-2014 |
20140048878 | SEMICONDUCTOR DEVICE AND METHOD FOR FABRICATING THE SAME - A semiconductor device includes: a P+ substrate; a P− epitaxial layer over the P+ substrate; a P-well and an N− drift region in the P− epitaxial layer and laterally adjacent to each other; an N+ source region in the P-well and connected to a front-side metal via a first contact electrode; an N+ drain region in the N− drift region and connected to the front-side metal via a second contact electrode; a gate structure on the P− epitaxial layer and connected to the front-side metal via a third contact electrode; and a metal plug through the P− epitaxial layer and having one end in contact with the P+ substrate and the other end connected to the front-side metal, the metal plug being adjacent to one side of the N+ source region that is farther from the N− drift region. A method for fabricating the semiconductor device is also disclosed. | 02-20-2014 |
20140027850 | LDMOS DEVICE WITH STEP-LIKE DRIFT REGION AND FABRICATION METHOD THEREOF - An LDMOS device is disclosed. The LDMOS device includes: a substrate having a first type of conductivity; a drift region having a second type of conductivity and being formed in the substrate; a doped region having the first type of conductivity and being formed in the substrate, the doped region being located at a first end of the drift region and laterally adjacent to the drift region; and a heavily doped drain region having the second type of conductivity and being formed in the substrate, the heavily doped drain region being located at a second end of the drift region, wherein the drift region has a step-like top surface with at least two step portions, and wherein a height of the at least two step portions decreases progressively in a direction from the doped region to the drain region. A method of fabricating LDMOS device is also disclosed. | 01-30-2014 |
20130328047 | STRUCTURE FOR PICKING UP A COLLECTOR AND METHOD OF MANUFACTURING THE SAME - A structure for picking up a collector region including a pair of polysilicon stacks formed in the isolation regions and extending below the collector region; and a pair of collector electrodes contacting on the polysilicon stacks, wherein the pair of polysilicon stacks includes: an undoped polysilicon layer and a doped polysilicon layer located on the undoped polysilicon layer, wherein a depth of the doped polysilicon layer is greater than a depth of the collector region; the depth of the collector region is greater than a depth of the isolation regions. | 12-12-2013 |
20130313677 | STRUCTURE FOR PICKING UP A COLLECTOR AND MANUFACTURING METHOD THEREOF - A structure for picking up a collector region is disclosed. The structure includes a pair of polysilicon stacks formed in the isolation regions and extending below the collector region; and a pair of collector electrodes contacting on the polysilicon stacks, wherein the pair of polysilicon stacks includes: a first polysilicon layer located below the isolation regions, and a second polysilicon layer located on and in contact with the first polysilicon layer, the first polysilicon layer being doped with a dopant having a higher diffusivity or higher concentration than a dopant of the second polysilicon layer, wherein a depth of the polysilicon stacks is greater than a depth of the collector region; the depth of the collector region is greater than a depth of the second polysilicon layer; and the depth of the second polysilicon layer is greater than a depth of the isolation regions. | 11-28-2013 |
20130299896 | SUPERJUNCTION DEVICE - A superjunction device in which corner portions of each annular-shaped second trench are composed of a plurality of alternately arranged first sides and second sides. The first sides are parallel to a plurality of parallel arranged first trenches in a current-flowing area, while the second sides are perpendicular to the first sides and the first trenches. Such design ensures that Miller indices of sidewalls and bottom face of any portion of each second trench belong to the same family of crystal planes. Moreover, with this design, the corner portions of the second trenches can be filled with a silicon epitaxial material at the same rate with the rest portions thereof, which ensures for the second trenches to be uniformly and completely filled without any defects in the corner portions and hence improve the performance of the superjunction device. | 11-14-2013 |
20130299879 | SIGE HBT DEVICE AND MANUFACTURING METHOD OF THE SAME - A silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) device that includes a substrate; a buried oxide layer near a bottom of the substrate; a collector region above and in contact with the buried oxide layer; a field oxide region on each side of the collector region; a pseudo buried layer under each field oxide region and in contact with the collector region; and a through region under and in contact with the buried oxide layer. A method for manufacturing a SiGe HBT device is also disclosed. The SiGe HBT device can isolate noise from the bottom portion of the substrate and hence can improve the intrinsic noise performance of the device at high frequencies. | 11-14-2013 |
20130257635 | DIGITAL CORRECTION CIRCUIT FOR A PIPELINED ANALOG-TO-DIGITAL CONVERTER - A digital correction circuit for a pipelined analog-to-digital converter (ADC) is disclosed. Compared to the conventional digital correction circuit which uses adders to perform operations in ADC digital correction part and hence needs a rather long operation time, the digital correction circuit of this invention can reduce the time needed in operations in the finial digital correction circuits and thus can optimize operation time, by allocating the operations to a plurality of pipeline stages of second sub-circuits configured to synchronize digital codes, each of which can perform part of the operations only with NAND gates, NOR gates, phase inverters and D-type flip-flops, without needing to use adders. | 10-03-2013 |
20130234201 | FIELD STOP STRUCTURE, REVERSE CONDUCTING IGBT SEMICONDUCTOR DEVICE AND METHODS FOR MANUFACTURING THE SAME - A field stop structure is disclosed. The field stop structure is divided into a three-dimensional structure by a plurality of trenches formed on a back side of a silicon substrate and hence obtains a greater formation depth in the substrate and can achieve a higher ion activation efficiency. Moreover, a first electrode region of a fast recovered diode (FRD) is formed in the trenches, thereby enabling the integration of a FRD with an insulated gate bipolar transistor (IGBT) device. Methods for forming field stop structure and reverse conducting IGBT semiconductor device are also disclosed. | 09-12-2013 |
20130196491 | METHOD OF PREVENTING DOPANT FROM DIFFUSING INTO ATMOSPHERE IN A BICMOS PROCESS - A method of preventing dopant from diffusing into atmosphere in a BiCMOS process is disclosed. The BiCMOS process includes the steps of: depositing a first silicon oxide layer and a silicon nitride layer over surface of a silicon substrate; etching the silicon substrate to form a plurality of shallow trenches therein; depositing a second silicon oxide layer over surface of the silicon substrate and forming silicon oxide sidewalls over inner side faces of each of the plurality of shallow trenches; forming a heavily doped pseudo buried layer under a bottom of one of the plurality of shallow trenches by implanting a dopant with a high concentration; performing an annealing process to promote diffusion of the dopant contained in the pseudo buried layer, wherein the method includes growing, by thermal oxidation, a silicon oxide layer over a bottom of each of the plurality of shallow trenches during the annealing process. | 08-01-2013 |
20130175581 | ZENER DIODE IN A SIGE BICMOS PROCESS AND METHOD OF FABRICATING THE SAME - A zener diode in a SiGe BiCMOS process is disclosed. An N-type region of the zener diode is formed in an active region and surrounded by an N-deep well. A pseudo buried layer is formed under each of the shallow trench field oxide regions on a corresponding side of the active region, and the N-type region is connected to the pseudo buried layers via the N-deep well. The N-type region has its electrode picked up by deep hole contacts. A P-type region of the zener diode is formed of a P-type ion implanted region in the active region. The P-type region is situated above and in contact with the N-type region, and has a doping concentration greater than that of the N-type region. The P-type region has its electrode picked up by metal contact. A method of fabricating zener diode in a SiGe BiCMOS process is also disclosed. | 07-11-2013 |
20130149836 | METHOD OF DOUBLE-SIDED PATTERNING - A method of double-sided patterning including positioning a first silicon wafer with its back side facing upwards and forming one or more deep trenches serving as alignment marks on the back side of the first silicon wafer; performing alignment with respect to the alignment marks and forming a back-side pattern on the first silicon wafer; depositing a polishing stop layer on the back side of the first silicon wafer; flipping over the first silicon wafer and bonding its back side with the front side of a second silicon wafer; polishing the front side of the first silicon wafer to expose the alignment marks from the front side; performing alignment with respect to the alignment marks and forming a front-side pattern on the first silicon wafer; removing the second silicon wafer and the polishing stop layer to obtain a double-sided patterned structure on the first silicon wafer. | 06-13-2013 |
20130140604 | SILICON-GERMANIUM HETEROJUNCTION BIPOLAR TRANSISTOR AND MANUFACTURING METHOD THEREOF - A silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) is disclosed, including: a substrate; two field oxide regions formed in the substrate; two pseudo buried layers, each being formed under a corresponding one of the field oxide regions; a collector region formed between the field oxide regions, the collector region laterally extending under a corresponding one of the field oxide regions and each side of the collector region being connected with a corresponding one of the pseudo buried layers; a matching layer formed under both the pseudo buried layers and the collector region; and two deep hole electrodes, each being formed in a corresponding one of the field oxide regions, the deep hole electrodes being connected to the corresponding ones of the pseudo buried layers for picking up the collector region. A manufacturing method of the SiGe HBT is also disclosed. | 06-06-2013 |
20130130504 | METHOD OF MANUFACTURING NON-PHOTOSENSITIVE POLYIMIDE PASSIVATION LAYER - A method of manufacturing non-photosensitive polyimide passivation layer is disclosed. The method includes: spin-coating a non-photosensitive polyimide layer over a wafer and baking it; depositing a silicon dioxide thin film thereon; spin-coating a photoresist layer over the silicon dioxide thin film and baking it; exposing and developing the photoresist layer to form a photoresist pattern; etching the silicon dioxide thin film by using the photoresist pattern as a mask; removing the patterned photoresist layer; dry etching the non-photosensitive polyimide layer by using the patterned silicon dioxide thin film as a mask; removing the patterned silicon dioxide thin film; and curing to form a imidized polyimide passivation layer. The method addresses issues of the traditional non-photosensitive polyimide process, including aluminum corrosion by developer, tapered profile of non-photosensitive polyimide layer and generation of photoresist residues. | 05-23-2013 |
20130130486 | METHOD OF FORMING SILICIDE LAYERS - A method of forming silicide layers is disclosed, the method including: providing a silicon substrate which includes at least one first region and at least one second region; depositing a dielectric layer over the silicon substrate; forming at least one opening having a great width/depth ratio in the dielectric layer above the at least one first region, and forming at least one opening having a small width/depth ratio in the dielectric layer above the at least one second region; depositing a metal and performing a high-temperature annealing to form a thick silicide layer in each of the at least one opening above each of the at least one first region and to form a thin silicide layer in each of the at least one opening above each of the at least one second region; removing the remaining metal not formed into the silicide layers. | 05-23-2013 |
20130126945 | ULTRA HIGH VOLTAGE SIGE HBT AND MANUFACTURING METHOD THEREOF - An ultra high voltage silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) is disclosed, in which, a collector region is formed between two isolation structures; a pseudo buried layer is formed under each isolation structure and each side of the collector region is connected with a corresponding pseudo buried layer; a SiGe field plate is formed on each of the isolation structures; each pseudo buried layer is picked up by a first contact hole electrode and each SiGe field plate is picked up by a second contact hole electrode; and each first contact hole electrode is connected to its adjacent second contact hole electrode and the two contact hole electrodes jointly serve as an emitter. A manufacturing method of the ultra high voltage SiGe HBT is also disclosed. | 05-23-2013 |
20130113104 | STRUCTURE FOR PICKING UP A BURIED LAYER AND METHOD THEREOF - A structure for picking up a buried layer is disclosed. The buried layer is formed in a substrate and has an epitaxial layer formed thereon. One or more isolation regions are formed in the epitaxial layer. The structure for picking up the buried layer includes a contact-hole electrode formed in each of the isolation regions. A bottom of the contact-hole electrode is in contact with the buried layer. As the structure of the present invention is formed in the isolation region without occupying any portion of the active region, its size is much smaller than that of a sinker region of the prior art. Therefore, device area is tremendously reduced. Moreover, as the contact-hole electrode picks up the buried layer by a metal contact, the series resistance of the device can be greatly reduced. A method of forming the above structure is also disclosed. | 05-09-2013 |
20130113078 | POLYSILICON-INSULATOR-SILICON CAPACITOR IN A SIGE HBT PROCESS AND MANUFACTURING METHOD THEREOF - A PIS capacitor in a SiGe HBT process is disclosed, wherein the PIS capacitor includes: a silicon substrate; a P-well and shallow trench isolations formed in the silicon substrate; a P-type heavily doped region formed in an upper portion of the P-well; an oxide layer and a SiGe epitaxial layer formed above the P-type heavily doped region; spacers formed on sidewalls of the oxide layer and the SiGe epitaxial layer; and contact holes for picking up the P-well and the SiGe epitaxial layer and connecting each of the P-well and the SiGe epitaxial layer to a metal wire. A method of manufacturing the PIS capacitor is also disclosed. The PIS capacitor of the present invention is manufactured by using SiGe HBT process, thus providing one more device option for the SiGe HBT process. | 05-09-2013 |
20130113022 | SIGE HBT AND MANUFACTURING METHOD THEREOF - A silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) is disclosed, which includes: two isolation structures each being formed in a trench; a set of three or more pseudo buried layers formed under each trench with every adjacent two pseudo buried layers of the set being vertically contacted with each other; and a collector region. In this design, the lowermost pseudo buried layers of the two sets are laterally in contact with each other, and the collector region is surrounded by the two isolation structures and the two sets of pseudo buried layers. As the breakdown voltage of a SiGe HBT according to the present invention is determined by the distance between an uppermost pseudo buried layer and the edge of an active region, SiGe HBTs having different breakdown voltages can be achieved. A manufacturing method of the SiGe HBT is also disclosed. | 05-09-2013 |
20130113021 | SIGE HBT HAVING DEEP PSEUDO BURIED LAYER AND MANUFACTURING METHOD THEREOF - A silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) having a deep pseudo buried layer is disclosed. The SiGe HBT includes isolation structures formed in trenches, first pseudo buried layers and second pseudo buried layers, and a collector region. The first pseudo buried layers are formed under the respective trenches and the second pseudo buried layers are formed under the first pseudo buried layers, with each first pseudo buried layer vertically contacting with a second pseudo buried layer. The second pseudo buried layers are laterally connected to each other, and the collector region is surrounded by the trenches, the first pseudo buried layers and the second pseudo buried layers. The cross section of each of the trenches has a regular trapezoidal shape, namely, each trench's width of its top is smaller than that of its bottom. A manufacturing method of the SiGe HBT is also disclosed. | 05-09-2013 |
20130113020 | SIGE HBT AND METHOD OF MANUFACTURING THE SAME - A SiGe HBT is disclosed, which includes: a silicon substrate; shallow trench field oxides formed in the silicon substrate; a pseudo buried layer formed at bottom of each shallow trench field oxide; a collector region formed beneath the surface of the silicon substrate, the collector region being sandwiched between the shallow trench field oxides and between the pseudo buried layers; a polysilicon gate formed above each shallow trench field oxide having a thickness of greater than 150 nm; a base region on the polysilicon gates and the collector region; emitter region isolation oxides on the base region; and an emitter region on the emitter region isolation oxides and a part of the base region. The polysilicon gate is formed by gate polysilicon process of a MOSFET in a CMOS process. A method of manufacturing the SiGe HBT is also disclosed. | 05-09-2013 |
20130099351 | BIPOLAR TRANSISTOR AND METHOD OF MANUFACTURING THE SAME - A bipolar transistor is disclosed, which includes a collector region, a base region, an emitter region and field plates. Each field plate is present in a structure of a flat sidewall covering one side face of the active region so that it also covers the collector region from one side. The field plate has its surface parallel to the side face of the active region and is isolated from the side face of the active region by a pad oxide layer. The field plate has its top lower than the surface of the active region. The bipolar transistor is capable of improving the breakdown voltage of the device without increasing the collector resistance or deteriorating the frequency characteristic. A method of manufacturing bipolar transistor is also disclosed. | 04-25-2013 |
20130099288 | SiGe HBT and Manufacturing Method Thereof - A silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) is disclosed, in which a shallow trench is formed of a first shallow trench and a second shallow trench vertically joined together in the active region, the second shallow trench being located directly under the first shallow trench and having a width less than that of the first shallow trench; a pseudo buried layer is formed surrounding the bottom and side walls of the second shallow trench and is in contact with the collector region to serve as a connection layer of a collector; a deep hole contact is formed in the shallow trench and is in contact with the pseudo buried layer to pick up the collector. A SiGe HBT manufacturing method is also disclosed. The present invention is capable of improving the cut-off frequency of a SiGe HBT. | 04-25-2013 |
20130097570 | METHOD OF INSERTING DUMMY PATTERNS - A method of inserting dummy patterns is provided. The method includes: determining an applicable area in which dummy patterns shall be inserted and an inapplicable area in which dummy patterns shall not be inserted on a chip; and inserting dummy patterns starting from one side of the inapplicable area and arranging the inserted dummy patterns into circles. The method of the present invention ensures that dummy patters are preferentially inserted around the device that requires protection by dummy patterns, so that good uniformity of chip pattern densities is guaranteed and within-wafer uniformity is improved, thus improving the yield and performance of semiconductor devices. | 04-18-2013 |
20130092981 | SIGE HBT HAVING A POSITION CONTROLLED EMITTER-BASE JUNCTION - A SiGe HBT having a position controlled emitter-base junction is disclosed. The SiGe HBT includes: a collector region formed of an N-doped active region; a base region formed on the collector region and including a base epitaxial layer, the base epitaxial layer including a SiGe layer and a capping layer formed thereon, the SiGe layer being formed of a SiGe epitaxial layer doped with a P-type impurity, the capping layer being doped with an N-type impurity; and an emitter region formed on the base region, the emitter region being formed of polysilicon. By optimizing the distribution of impurities doped in the base region, a controllable position of the emitter-base junction and adjustability of the reverse withstanding voltage thereof can be achieved, and thereby increasing the stability of the process and improving the uniformity within wafer. | 04-18-2013 |
20130082323 | SUPERJUNCTION STRUCTURE, SUPERJUNCTION MOS TRANSISTOR AND MANUFACTURING METHOD THEREOF - A superjunction structure with unevenly doped P-type pillars ( | 04-04-2013 |
20130075931 | BOND PAD STRUCTURE - A bond pad structure for an integrated circuit chip package is disclosed. The bond pad structure includes a top metal layer, a patterned metal layer and an interconnection structure. The patterned metal layer is formed below the top metal layer and includes an annular metal layer and a plurality of metal blocks evenly arranged at a central area of the annular metal layer; the patterned metal layer is connected to the top metal layer through both the annular metal layer and the metal blocks. The interconnection structure is formed below the patterned metal layer and is connected to patterned metal layer only through the annular metal layer. By using the above structure, active or passive devices can be disposed under the bond pad structure and will not be damaged by package stress. An integrated circuit employing the above bond pad structure is also disclosed. | 03-28-2013 |
20130075730 | VERTICAL PNP DEVICE IN A SILICON-GERMANIUM BICMOS PROCESS AND MANUFACTURING METHOD THEREOF - A vertical PNP device in a silicon-germanium (SiGe) BiCMOS process is disclosed. The device is formed in a deep N-well and includes a collector region, a base region and an emitter region. The collector region has a two-dimensional L-shaped structure composed of a lightly doped first P-type ion implantation region and a heavily doped second P-type ion implantation region. The collector region is picked up by P-type pseudo buried layers formed at bottom of the shallow trench field oxide regions. A manufacturing method of vertical PNP device in a SiGe BiCMOS process is also disclosed. The method is compatible with the manufacturing processes of a SiGe heterojunction bipolar transistor in the SiGe BiCMOS process. | 03-28-2013 |
20120326226 | SUPERJUNCTION DEVICE AND METHOD FOR MANUFACTURING THE SAME - A superjunction device is disclosed, wherein P-type regions in an active region are not in contact with the N+ substrate, and the distance between the surface of the N+ substrate and the bottom of the P-type regions in the active region is greater than the thickness of a transition region in the N-type epitaxial layer. Methods for manufacturing the superjunction device are also disclosed. The present invention is capable of improving the uniformity of reverse breakdown voltage and overshoot current handling capability in a superjunction device. | 12-27-2012 |
20110147793 | SiGe HETEROJUNCTION BIPOLAR TRANSISTOR MULTI-FINGER STRUCTURE - The present invention provides a multi-finger structure of a SiGe heterojunction bipolar transistor (HBT). It is consisted of plural SiGe HBT single cells. The multi-finger structure is in a form of C/BEBC/BEBC/.../C, wherein, C, B, E respectively stands for collector, base and emitter; CBEBC stands for a SiGe HBT single cell. The collector region is consisted of an n type ion implanted layer inside the active region. The bottom of the implanted layer is connected to two n type pseudo buried layers. The two pseudo buried layers are formed through implantation to the bottom of the shallow trenches that surround the collector active region. Two collectors are picked up by deep trench contact through the field oxide above the two pseudo buried layers. The present invention can reduce junction capacitance, decrease collector electrode output resistance, and improve device frequency characteristics. | 06-23-2011 |
20110133879 | STACKED INDUCTOR - A stacked inductor with combined metal layers is represented in this invention. The stacked inductor includes: a top layer metal coil, and at least two lower layer metal coils, the metal coils being aligned with each other; adjacent metal coils being connected at the corresponding ends through a via; wherein, each of the lower layer metal coils is consisted of plural layers of metal lines which are interconnected. With the same chip area, the stacked inductor of the present invention can achieve higher inductance and Q factor because of the mutual inductance generated from the plural layers of metal lines and the reduced parasitic resistance. | 06-09-2011 |