Abstract: A thermal sensor for use in an IC device is formed of a plurality of metal resistor units connected in series where each of the plurality of metal resistor units are formed on different wiring layers of the IC device connected by via segments and the metal resistor units are in a superimposed alignment with each other forming a stack.

Abstract: Diodes and bipolar junction transistors (BJTs) are formed in IC devices that include fin field-effect transistors (FinFETs) by utilizing various process steps in the FinFET formation process. The diode or BJT includes an isolated fin area and fin array area having n-wells having different depths and a p-well in a portion of the fin array area that surrounds the n-well in the isolated fin area. The n-wells and p-well for the diodes and BJTs are implanted together with the FinFET n-wells and p-wells.

Abstract: A band gap reference circuit includes an error-amplifier-based current mirror coupled between a first supply node and a pair of intermediate voltage nodes, and a matched diode pair for providing a proportional-to-absolute temperature (PTAT) current. The matched diode pair includes a first diode connected between a first intermediate voltage node from the pair of intermediate voltage nodes and a second supply node, and a second diode connected in series with a resistor between a second intermediate voltage node from the pair of intermediate voltage nodes and the second supply node. Each diode has a P-N diode junction that is a homojunction.

Abstract: Diodes and bipolar junction transistors (BJTs) are formed in IC devices that include fin field-effect transistors (FinFETs) by utilizing various process steps in the FinFET formation process. The diode or BJT includes an isolated fin area and fin array area having n-wells having different depths and a p-well in a portion of the fin array area that surrounds the n-well in the isolated fin area. The n-wells and p-well for the diodes and BJTs are implanted together with the FinFET n-wells and p-wells.

Abstract: A bandgap reference circuit including two sets of bipolar junction transistors (BJTs). A first set of two or more BJTs configured to electrically connect in a parallel arrangement. The first set of BJTs is configured to produce a first proportional to absolute temperature (PTAT) signal. A second set of two or more BJTs configured to electrically connect in a parallel arrangement. The second set of BJTs is configured to produce a second PTAT signal. A circuitry configured to electrically connect to the first set of BJTs and the second set of BJTs. The circuitry is configured to combine the first PTAT signal and the second PTAT signal to produce a reference voltage.

Abstract: Through silicon via (TSV) isolation structures are provided and suppress electrical noise such as may be propagated through a semiconductor substrate when caused by a signal carrying active TSV such as used in 3D integrated circuit packaging. The isolation TSV structures are surrounded by an oxide liner and surrounding dopant impurity regions. The surrounding dopant impurity regions may be P-type dopant impurity regions that are coupled to ground or N-type dopant impurity regions that may advantageously be coupled to VDD. The TSV isolation structure is advantageously disposed between an active, signal carrying TSV and active semiconductor devices and the TSV isolation structures may be formed in an array that isolates an active, signal carrying TSV structure from active semiconductor devices.

Abstract: A method for verifying that acceptable device feature gradients and device feature disparities are present in a semiconductor device layout, is provided. The method provides for dividing a device layout into a plurality of windows and measuring or otherwise determining the device feature density within each window. The device layout includes various device regions and the method provides for comparing an average device feature density within one region to surrounding areas or other regions and also for determining gradients of device feature densities. The gradients may be monitored from within a particular device region to surrounding regions. Instructions for carrying out the method may be stored on a computer readable storage medium and executed by a processor.

Abstract: A semiconductor device including field-effect transistors (finFETs) formed on a silicon substrate. The device includes a number of active areas each having a number of equally-spaced fins separated into regular fins and at least one edge fin, a gate structure over the regular fins, and a drain region as well as a source region electrically connected to the regular fins and disconnected to the at least one edge fin. The edge fins may be floating, connected to a potential source, or serve as a part of a decoupling capacitor.

Abstract: A device comprises a semiconductor substrate having first and second implant regions of a first dopant type. A gate insulating layer and a gate electrode are provided above a resistor region between the first and second implant regions. A first dielectric layer is on the first implant region. A contact structure is provided, including a first contact portion conductively contacting the gate electrode, at least part of the first contact portion directly on the gate electrode. A second contact portion directly contacts the first contact portion and is formed directly on the first dielectric layer. A third contact portion is formed on the second implant region.

Abstract: A semiconductor device including field-effect transistors (finFETs) and fin capacitors are formed on a silicon substrate. The fin capacitors include silicon fins, one or more electrical conductors between the silicon fins, and insulating material between the silicon fins and the one or more electrical conductors. The fin capacitors may also include insulating material between the one or more electrical conductors and underlying semiconductor material.

Abstract: A method for verifying that acceptable device feature gradients and device feature disparities are present in a semiconductor device layout, is provided. The method provides for dividing a device layout into a plurality of windows and measuring or otherwise determining the device feature density within each window. The device layout includes various device regions and the method provides for comparing an average device feature density within one region to surrounding areas or other regions and also for determining gradients of device feature densities. The gradients may be monitored from within a particular device region to surrounding regions. Instructions for carrying out the method may be stored on a computer readable storage medium and executed by a processor.

Abstract: A device comprises a semiconductor substrate having first and second implant regions and an electrode above and between the first and second implant regions of a first dopant type. A contact structure is in direct contact with the first and second implant regions and the electrode. A third implant region has a second dopant type different from the first dopant type. A bulk contact is provided on the third implant.

Abstract: A method of generating an optimized layout of semiconductor components in conformance with a set of design rules includes generating, for a unit cell including one or more semiconductor components, a plurality of configurations each of which satisfies some, but not all, of the design rules. For each configuration, it is checked whether a layout, which is a repeating pattern of the unit cell, satisfies the remaining design rules. Among the configurations which satisfy all of the design rules, the configuration providing an optimal value of a property is selected for generating the optimized layout of the semiconductor components.

Abstract: A semiconductor substrate has at least two active regions, each having at least one active device that includes a gate electrode layer, and a shallow trench isolation (STI) region between the active regions. A decoupling capacitor comprises first and second dummy conductive patterns formed in the same gate electrode layer over the STI region. The first and second dummy conductive regions are unconnected to any of the at least one active device. The first dummy conductive pattern is connected to a source of a first potential. The second dummy conductive pattern is connected to a source of a second potential. A dielectric material is provided between the first and second dummy conductive patterns.

Abstract: A level shifting circuit includes a first circuit, a second circuit and an output voltage controlling circuit. The first circuit is coupled to an input node, an output node and a first supply voltage node and configured to pull an output voltage at the output node toward the first supply voltage in accordance with an input voltage applied to the input node. The second circuit is coupled to the first circuit, the output node and the second supply voltage node and configured to pull the output voltage toward the second supply voltage in accordance with the input voltage from the first circuit. The output voltage controlling circuit is coupled to the output node and configured to control the output voltage within a range narrower than a range from the first voltage to the second voltage.

Abstract: Through silicon via (TSV) isolation structures are provided and suppress electrical noise such as may be propagated through a semiconductor substrate when caused by a signal carrying active TSV such as used in 3D integrated circuit packaging. The isolation TSV structures are surrounded by an oxide liner and surrounding dopant impurity regions. The surrounding dopant impurity regions may be P-type dopant impurity regions that are coupled to ground or N-type dopant impurity regions that may advantageously be coupled to VDD. The TSV isolation structure is advantageously disposed between an active, signal carrying TSV and active semiconductor devices and the TSV isolation structures may be formed in an array that isolates an active, signal carrying TSV structure from active semiconductor devices.

Abstract: Methods and apparatus for polysilicon MOS capacitors in a replacement gate process. A method includes disposing a gate dielectric layer over a semiconductor substrate; disposing a polysilicon gate layer over the dielectric layer; patterning the gate dielectric layer and the polysilicon gate layer to form a plurality of polysilicon gates spaced by at least a minimum polysilicon to polysilicon pitch; defining a polysilicon resistor region containing at least one of the polysilicon gates and not containing at least one other of the polysilicon gates, which form dummy gates; depositing a mask layer over an inter-level dielectric layer; patterning the mask layer to expose the dummy gates; removing the dummy gates and the gate dielectric layer underneath the dummy gates to leave trenches in the inter-level dielectric layer; and forming high-k metal gate devices in the trenches in the inter-level dielectric layer. An apparatus produced by the method is disclosed.

Abstract: An integrated circuit includes a first pass gate and a first receiver electrically coupled with the first pass gate. The first receiver includes a first N-type transistor. A first gate of the first N-type transistor is electrically coupled with the first pass gate. A first P-type bulk of the first N-type transistor is surrounded by a first N-type doped region. The first N-type doped region is surrounded by a first N-type well. The first N-type doped region has a dopant concentration higher than that of the first N-type well.

Abstract: A TSV interface circuit for a TSV provided in an interposer substrate that forms a connection between a first die and a second die includes a driving circuit provided in the first die and a receiver circuit provided in the second die where the driving circuit is coupled to a first supply voltage and a second supply voltage that are both lower than the interposer substrate voltage that substantially reduces the parasitic capacitance of the TSV. The receiver circuit is also coupled to the first supply voltage and the second supply voltage that are both lower than the interposer substrate voltage.

Abstract: A system and method for reducing density mismatch is disclosed. An embodiment comprises determining a conductor density and an active area density in a high density area and a low density area of a semiconductor device. Dummy material may be added to the low density area in order to raise the conductor density and the active area density, thereby reducing the internal density mismatches between the high density area and the low density area. Additionally, a similar process may be used to reduce external mismatches between different regions on the semiconductor substrate. Once these mismatches have been reduced, empty regions surrounding the different regions may additionally be filled in order to reduce the conductor density mismatch and the active area density mismatches.