Abstract: Circuits and methods for reducing and cancelling out kickback noise are disclosed. In one example, a circuit for a comparator is disclosed. The circuit includes: a first transistor group, a second transistor group, and a first switch. The first transistor group comprises a first transistor having a drain coupled to a first node, and a second transistor having a source coupled to the first node. Gates of the first transistor and the second transistor are coupled together to a first input of the comparator. The second transistor group comprises a third transistor having a drain coupled to a second node, and a fourth transistor having a source coupled to the second node. Gates of the third transistor and the fourth transistor are coupled together to a second input of the comparator. The first switch is connected to and between the first node and the second node.

Abstract: A thermal sensor in some embodiments comprises two temperature-sensitive branches, each including a thermal-sensing device, such as one or more bipolar-junction transistors, and a current source for generating a current density in the thermal-sensing device to generate a temperature-dependent signal. The thermal sensor further includes a signal processor configured to multiply the temperature-dependent signal from the branches by respective and different gain factors, and combine the resultant signals to generate an output signal that is substantially proportional to the absolute temperature the thermal sensor is disposed at.

Abstract: A bandgap reference (BGR) circuit is provided. The BGR circuit includes a first node, a second node, and a third node. A first resistive element is connected between the second node and the third node. The BGR circuit is operative to provide a reference voltage as an output. The BGR circuit further includes a current shunt path connected between the first node and the third node, the current shunt path being operable to regulate a voltage drop across the first resistive element.

Abstract: A trimmable resistor circuit and a method for operating the trimmable resistor circuit are provided. The trimmable resistor circuit includes first sources/drains and first gate structures alternatively arranged in a first row, second sources/drains and second gate structures alternatively arranged in a second row, third sources/drains and third gate structures alternatively arranged in a third row, first resistors disposed between the first row and the second row, and second resistors disposed between the second row and the third row. In the method for operating the trimmable resistor circuit, the first gate structures in the first row and the third gate structures in the third row are turned on. Then, the second gate structures in the second row are turned on/off according to a predetermined resistance value.

Abstract: A bandgap reference (BGR) circuit is provided. The BGR circuit includes a first node, a second node, and a third node. A first resistive element is connected between the second node and the third node. The BGR circuit is operative to provide a reference voltage as an output. The BGR circuit further includes a current shunt path connected between the first node and the third node, the current shunt path being operable to regulate a voltage drop across the first resistive element.

Abstract: A circuit is disclosed that includes a first differential input pair, a second differential input pair, and a capacitive element. The first differential input pair is configured to be activated according to an output of the second differential input pair, and the second differential input pair is configured to be activated according to an output of the first differential input pair. The first differential input pair and the second differential input pair each comprises an input configured to receive an output signal. The capacitive element configured to be charged according to the output of the first differential input pair, and configured to be discharged according to the output of the second differential input pair, in order to generate the output signal.

Abstract: A metal-oxide-semiconductor (MOS) capacitor is disclosed. The MOS capacitor includes a front-end-of-the-line (FEOL) field effect transistor (FET), and a plurality of middle-end-of-the-line (MEOL) conductive structures. The FEOL FET includes a source region and a drain region positioned in a semiconductor substrate, and a gate over the semiconductor substrate. The plurality of MEOL conductive structures is disposed on a top surface of the gate. At least one of the MEOL conductive structures is electrically disconnected from a back-end-of-the-line (BEOL) metal layer. A semiconductor fabrication method and a MOS capacitor circuit are also disclosed.

Abstract: A circuit includes a first current source that provides a current and a resistive branch in series with the first current source that provides a first voltage value and a second voltage value. A capacitive device is coupled with a voltage node having a voltage value, and a switching network alternates between charging the capacitive device to have the voltage value increase to the first voltage value, and discharging the capacitive device to have the voltage value decrease to the second voltage value.

Abstract: A three-dimensional integrated circuit includes a first layer including at least one sensing element configured to output at least one temperature-dependent voltage; and a second layer disposed vertically with respect to the first layer and coupled to the first layer by at least one via. The second layer includes: a compare circuit configured to generate at least one intermediate voltage in response to comparing the at least one temperature-dependent voltage to a feedback voltage; a control circuit configured to generate at least one control signal in response to the intermediate voltage; and a switching circuit configured to couple a capacitor coupled to a feedback node to one of a first voltage supply and a second voltage supply in response to the at least one control signal to generate an output signal that is based on a temperature sensed by the sensing element.

Abstract: A bandgap reference (BGR) circuit is provided. The BGR circuit includes a first node, a second node, and a third node. A first resistive element is connected between the second node and the third node. The BGR circuit is operative to provide a reference voltage as an output. The BGR circuit further includes a current shunt path connected between the first node and the third node, the current shunt path being operable to regulate a voltage drop across the first resistive element.

Abstract: A bandgap reference circuit includes a first bipolar junction transistor (BJT) in series with a first current generator, the first BJT and the first current generator configured to produce a first proportional to absolute temperature (PTAT) signal. The circuit also includes a second BJT in series with a second current generator, the second BJT and the second current generator configured to produce a second PTAT signal. The bandgap reference circuit maintains a current through at least one of the first BJT or the second BJT within a constant ideality factor region of the at least one of the first BJT or the second BJT.

Abstract: A continuous time delta sigma modulator is disclosed. In one example, the continuous time delta sigma modulator includes: a quantizer, a buffer module, a randomizer, and a reference module. The quantizer includes a comparator that generates a digital output based on a comparison of a reference potential with an input generated based on a sample of an analog signal. The buffer module stores the digital output for a predetermined delay period and outputs the digital output after the predetermined delay period as a delayed digital output. The randomizer randomizes the delayed digital output to generate a randomized digital output. The reference module modifies the reference potential based on the randomized digital output.

Abstract: A method comprises constructing thermal block representations of one or more circuit components or one or more sub-components of the one or more circuit components in an integrated circuit based, at least in part, on defined component parameters. The component parameters describe the one or more sub-components of the one or more circuit components. The thermal block representations have at least one simulation node. The method also comprises supplying a current using at least one current source or voltage controlled current source in a performance simulation. The current is supplied to a thermal path between a first simulation node and a second simulation node. The method further comprises determining a temperature distribution between the first simulation node and the second simulation node based on the current, a first determined voltage at the first simulation node, and a second determined voltage at the second simulation node.

Abstract: The present disclosure relates generally to integrated circuits, and more particularly to low-bias voltage reference circuits. The voltage reference circuits are capable of providing highly-accurate and temperature-insensitive outputs. Specifically, the present disclosure provides complementary-to-absolute-temperature circuits with low process variation and tunable temperature coefficient.

Abstract: A three-dimensional integrated circuit includes a first layer including at least one sensing element configured to output at least one temperature-dependent voltage; and a second layer disposed vertically with respect to the first layer and coupled to the first layer by at least one via. The second layer includes: a compare circuit configured to generate at least one intermediate voltage in response to comparing the at least one temperature-dependent voltage to a feedback voltage; a control circuit configured to generate at least one control signal in response to the intermediate voltage; and a switching circuit configured to couple a capacitor coupled to a feedback node to one of a first voltage supply and a second voltage supply in response to the at least one control signal to generate an output signal that is based on a temperature sensed by the sensing element.

Abstract: In some embodiments, an integrated circuit device includes a semiconductor substrate. An active area is disposed in the semiconductor substrate. A first guard ring is disposed in the semiconductor substrate and entirely surrounds the active area. The first guard ring has a first conductivity type. A via penetrates through the semiconductor substrate and is spaced apart from the active area such that the via is disposed outside of the first guard ring. A second guard ring is disposed in the semiconductor substrate and entirely surrounds the via and the first guard ring. The second guard ring has the first conductivity type and is disjoint from the first guard ring.

Abstract: A voltage reference circuit is provided. In some embodiments, the voltage reference circuit includes a MOS stack that includes two or more MOS transistors having a substantially same voltage threshold. The voltage reference circuit is configured to generate, via the MOS stack, a first voltage waveform having a first temperature co-efficient and a second voltage waveform having a second temperature co-efficient. In some embodiments, the first temperature co-efficient has a polarity that is opposite a polarity of the second temperature co-efficient. In some embodiments, the first voltage waveform and the second voltage waveform are used to generate a reference voltage waveform, where the reference voltage waveform is substantially temperature independent due to the opposite polarities of the first temperature co-efficient and the second temperature co-efficient.

Abstract: A method of making a temperature sensor arrangement includes forming a sensor array. The sensor array includes a first transistor of a first device and a plurality of second transistors of a second device different from the first device. The method further includes forming a guard ring region between the sensor array and another circuit of an integrated circuit. The guard ring region includes a transistor structure. The method further includes forming a thermally conductive element between the sensor array and the guard ring region. The thermally conductive element is connected to the transistor structure, the first transistor and each of the plurality of second transistors.

Abstract: A semiconductor structure is disclosed that includes a p-channel metal-oxide semiconductor (PMOS) array having a first set of oxide diffusion layer (OD) structures, an n-channel metal-oxide semiconductor (NMOS) array having a second set of OD structures, and a dummy buffer zone surrounding the PMOS and NMOS arrays. The semiconductor structure has a uniform spacing between OD structures in the first and second sets of OD structures and between the PMOS and NMOS array, such that no dummy buffer zone is included between the PMOS array and the NMOS array.

Abstract: A semiconductor structure is disclosed that includes a p-channel metal-oxide semiconductor (PMOS) array having a first set of oxide diffusion layer (OD) structures, an n-channel metal-oxide semiconductor (NMOS) array having a second set of OD structures, and a dummy buffer zone surrounding the PMOS and NMOS arrays. The semiconductor structure has a uniform spacing between OD structures in the first and second sets of OD structures and between the PMOS and NMOS array, such that no dummy buffer zone is included between the PMOS array and the NMOS array.