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: 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 temperature sensor arrangement in an integrated circuit (IC) includes a sensor array configured to determine a temperature of the IC. The sensor array includes a first transistor having a first terminal, a second terminal and a gate. The temperature sensor array further includes a guard ring region between the sensor array and another circuit of the IC. The guard ring region includes a transistor structure having a first terminal, a second terminal and a gate. The temperature sensor arrangement further includes a thermally conductive element connected to the transistor structure and a first terminal of the first transistor. The thermally conductive element is configured to provide a thermally conductive path from the transistor structure to the first terminal of the first transistor.

Abstract: A semiconductor device includes an edge active cell, an inner active cell and a middle active cell. The edge active cell is located near an edge of the semiconductor device. The edge active cell includes a plurality of fingers. The inner active cell is adjacent to the edge active cell toward a central portion of the semiconductor device. The inner active cell includes a plurality of fingers and at least one of the plurality of fingers of the edge active cell is electrically connected to at least one of the plurality of fingers of the inner active cell. The middle active cell is located near the central portion of the semiconductor device. The middle active cell includes a plurality of fingers and each of the fingers of the middle active cell is electrically connected to each other.

Abstract: A method of forming a semiconductor device includes implanting dopants in a first region of the semiconductor device to form a source region. The method further includes forming a guard ring in a second region of the semiconductor device, the guard ring being separated from the source region by a first spacing. The method further includes depositing a first heat conductive layer over the source region, wherein the first heat conductive layer is directly coupled to the source region and directly coupled to the guard ring. The first heat conductive layer is configured to dissipate heat generated by the semiconductor device from the source region to the guard ring.

Abstract: A semiconductor device includes an edge active cell, an inner active cell and a middle active cell. The edge active cell is located near an edge of the semiconductor device. The edge active cell includes a plurality of fingers. The inner active cell is adjacent to the edge active cell toward a central portion of the semiconductor device. The inner active cell includes a plurality of fingers and at least one of the plurality of fingers of the edge active cell is electrically connected to at least one of the plurality of fingers of the inner active cell. The middle active cell is located near the central portion of the semiconductor device. The middle active cell includes a plurality of fingers and each of the fingers of the middle active cell is electrically connected to each other.

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 current mirror circuit includes a first current mirror leg and a second current mirror leg. The first current mirror leg is configured with N stages of first transistors coupled in series and with their respective gates tied together. The second current mirror leg is configured with N stages of second transistors coupled in series and with their respective gates tied together. The first transistors and the second transistors are implemented within a transistor array, the first transistors and the second transistors are coupled between a first reference terminal and a second reference terminal, the first transistors and the second transistors at 1st to Kth stages adjacent to the first reference terminal are implemented at corner regions of the transistor array, N and K are positive integers and K<N. The first transistors have the same channel length, and the second transistors have the same channel length.

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: In some embodiments, a circuit includes a first transistor, a second transistor, a resistive device and an amplifier. The first transistor includes a first drain and a first gate. The second transistor includes a second drain and a second gate. The resistive device is coupled between the first gate and the second gate. The amplifier includes a first input coupled to the first drain and a second input coupled to the second drain. The amplifier is configured to keep a voltage level at the first drain and that at the second drain equal to each other.

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 is disclosed that includes a first differential input pair and a second differential input pair. The first differential input pair is activated according to an output of the second differential input pair, and receives a first temperature-dependent voltage and an output signal. The second differential input pair is activated according to an output of the first differential input pair, and receives a second temperature-dependent voltage and the output signal. The switching circuit couples a capacitive element to a first voltage supply according to the output of the first differential input pair, and the capacitive element to a second voltage supply according to the output of the second differential input pair, to generate the output signal.

Abstract: Some embodiments of the present disclosure provide a method including turning on a noise-measuring system for a device under test (DUT) with the DUT turned off; measuring a first phase noise caused by the noise-measuring system; turning on the DUT; measuring a second phase noise caused by the noise-measuring system and the DUT; and subtracting the first phase noise from the second phase noise to obtain a third phase noise caused by the DUT.

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 voltage reference circuit is provided that includes a first circuit, a second circuit and a third circuit. The first circuit has a first MOS transistor pair and the second circuit has a second MOS transistor pair. The first circuit is configured to provide a first voltage component that changes at a first rate having a first slope as a temperature to which the voltage reference circuit is subjected changes. The second circuit is configured to provide a second voltage component that changes at a second rate having a second slope as the temperature changes. The third circuit is configured to use the first voltage component and the second voltage component to generate the reference voltage component that changes at a fifth rate having a fifth slope as the temperature changes. The fifth slope is substantially equal to zero to promote insensitivity of the reference voltage component to temperature changes.

Abstract: A circuit includes a comparator unit and a switching network. The comparator unit is configured to receive a first voltage value, a second voltage value and a third voltage value of a voltage node, and to provide a control signal. The switching network includes the voltage node and is configured to operate in a first condition or in a second condition based on the control signal. Based on the first condition, the voltage node is configured to have a voltage value increase to the first voltage value. Based on a second condition, the voltage node is configured to have a voltage decrease to the second voltage.

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 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 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: In some embodiments, an integrated circuit includes a central array region having a first layout feature density. A background region surrounds the central array region and has a second layout feature density, which is different from the first density. A peripheral array region surrounds the central array region and separates the central array region from the background region. The peripheral array region has a third layout feature density between the first and second layout feature densities.