Abstract: A voltage regulator includes an amplifier to generate a difference voltage responsive to a comparison of a reference voltage and a feedback voltage. An output driver is coupled to the amplifier and drives a regulated output voltage responsive to the difference voltage. An impedance circuit is coupled between the output driver and a low power source and establishes the feedback voltage responsive to a current through the impedance circuit. A variation detector is operably coupled between the regulated output voltage and the difference voltage and is configured to modify the difference voltage. In some embodiments, the difference voltage is modified responsive to a rapid change of the regulated output voltage capacitively coupled to the variation detector. In other embodiments, the difference voltage is modified responsive to a rapid change of the feedback voltage capacitively coupled to the variation detector.

Abstract: A power transistor and a power converter are disclosed that may improve the on-resistance and corresponding silicon area of a power transistor. The power transistor may comprise a drain, a source, and a channel therebetween divided into a plurality of transistor stripes, the plurality of transistor stripes being grouped in a plurality of different groups. The power transistor may further comprise a first top metal associated with one of the drain and the source, and a second top metal associated with the other of the drain and the source. The second top metal includes at least one portion that is coupled to different groups of transistor stripes. A related method for determining a layout topology of a power transistor is also disclosed.

Abstract: Energy sharing circuits and related methods are disclosed herein. A high voltage can be selectively coupled to a first source line and a low voltage can be selectively coupled to a second source line during a first time period. During a subsequent time period, a first coupling switch is activated to inductively couple the first source line to the second source line and diode block the second source line from the first source line. During a subsequent time period, the low voltage is selectively coupled to the first source line and the high voltage is selectively coupled to the second source line. During a subsequent time period, a second coupling switch is activated to inductively couple the second source line to the first source line and diode block the first source line from the second source line.

Abstract: A semiconductor switch comprises a PNPN structure arranged to provide an SCR-like functionality, and a MOS gate structure, preferably integrated on a common substrate. The switch includes ohmic contacts for the MOS gate, and for the cathode and gate regions of the PNPN structure; the anode contact is intrinsic. A fixed voltage is typically applied to an external node. The MOS gate structure allows current to be conducted between the external node and the intrinsic anode when on, and the PNPN structure conducts the current from the anode to the cathode when an appropriate voltage is applied to the gate contact. Regenerative feedback keeps the switch on once it begins to conduct. The MOS gate inhibits the flow of current between the external node and anode—and thereby turns off the switch—when off. When on, the MOS gate's channel resistance serves as a ballast resistor.

Abstract: A voltage regulator includes an amplifier to generate a difference voltage responsive to a comparison of a reference voltage and a feedback voltage. An output driver is coupled to the amplifier and drives a regulated output voltage responsive to the difference voltage. An impedance circuit is coupled between the output driver and a low power source and establishes the feedback voltage responsive to a current through the impedance circuit. A variation detector is operably coupled between the regulated output voltage and the difference voltage and is configured to modify the difference voltage. In some embodiments, the difference voltage is modified responsive to a rapid change of the regulated output voltage capacitively coupled to the variation detector. In other embodiments, the difference voltage is modified responsive to a rapid change of the feedback voltage capacitively coupled to the variation detector.

Abstract: A semiconductor switch comprises a PNPN structure arranged to provide an SCR-like functionality, and a MOS gate structure, preferably integrated on a common substrate. The switch includes ohmic contacts for the MOS gate, and for the cathode and gate regions of the PNPN structure; the anode contact is intrinsic. A fixed voltage is typically applied to an external node. The MOS gate structure allows current to be conducted between the external node and the intrinsic anode when on, and the PNPN structure conducts the current from the anode to the cathode when an appropriate voltage is applied to the gate contact. Regenerative feedback keeps the switch on once it begins to conduct. The MOS gate inhibits the flow of current between the external node and anode—and thereby turns off the switch—when off. When on, the MOS gate's channel resistance serves as a ballast resistor.

Abstract: Level shifting circuits and related methods are disclosed herein. The level shifting circuit includes a cross-coupled pull-up circuit coupled to a higher supply voltage, an output signal, and an inverted output signal. An input signal transitions between a ground and a lower supply voltage and an inverted input signal transitions in a direction opposite from the input signal between the ground and the lower supply voltage. A first n-channel transistor has a gate coupled to the lower supply voltage, a drain coupled to the output signal, and a source coupled to the inverted input signal. A second n-channel transistor has a gate coupled to the lower supply voltage, a drain coupled to the inverted output signal, and a source coupled to the input signal. The level shifting circuit may be included in an IC with core logic in a first voltage domain and input/output logic in a second voltage domain.

Abstract: Successive approximation Analog-to-digital converters (ADCs) and related methods are disclosed. A successive approximation ADC includes a comparator with a comparator output and inputs coupled to a common model signal and a compare input. Control logic generates one or more control signals responsive to the comparator output. A capacitor array includes first sides of capacitors operably coupled to an array output. The capacitor arrays selectively couples each of second sides of the capacitors to an analog input signal and one or more input reference signals responsive to the one or more control signals. A voltage limiter is operably coupled between the array output and the compare input of the comparator and limits a voltage on the compare input to within a predefined range relative to the array output. The successive approximation ADC may also be configured differentially with a second comparator and a second voltage limiter.

Abstract: Level shifting circuits and a related method are disclosed herein. An embodiment of the present invention includes a voltage level shifter, comprising a first pull up transistor coupled to a high voltage signal and a first pull down transistor coupled between the first pull up transistor and a low voltage signal and controlled by an input signal. The voltage level shifter further includes a first bias transistor serially coupled between the first pull up transistor and the first bias transistor. A gate of the first bias transistor is coupled with a bias voltage signal. The voltage level shifter further includes a first additional pull up path coupled with the high voltage signal and a first node between the first pull up transistor and the first pull down transistor, and an output signal associated with the first node. The output signal is a level shifted voltage responsive to the input signal.

Abstract: A switch circuit is provided. The switch circuit may include a first transistor having a source terminal to accept an input signal, a drain terminal to provide an output signal, and a gate; a power supply providing a gate voltage. The switch circuit may also include a circuit to couple a switch signal to the gate, wherein the circuit turns the first transistor ‘off’ for all values of the input signal when the switch signal is ‘low.’ A programmable gain amplifier (PGA) is also provided. The PGA may include an input stage having an input node to couple an input signal, and an output node to provide a gate signal, at least a first gain stage including a resistor and a switch circuit as above. A differential gain amplifier may be included to provide an output signal from the gain signal.

Abstract: A power transistor and a power converter are disclosed that may improve the on-resistance and corresponding silicon area of a power transistor. The power transistor may comprise a drain, a source, and a channel therebetween divided into a plurality of transistor stripes, the plurality of transistor stripes being grouped in a plurality of different groups. The power transistor may further comprise a first top metal associated with one of the drain and the source, and a second top metal associated with the other of the drain and the source. The second top metal includes at least one portion that is coupled to different groups of transistor stripes. A related method for determining a layout topology of a power transistor is also disclosed.

Abstract: Successive approximation Analog-to-digital converters (ADCs) and related methods are disclosed. A successive approximation ADC includes a comparator with a comparator output and inputs coupled to a common model signal and a compare input. Control logic generates one or more control signals responsive to the comparator output. A capacitor array includes first sides of capacitors operably coupled to an array output. The capacitor arrays selectively couples each of second sides of the capacitors to an analog input signal and one or more input reference signals responsive to the one or more control signals. A voltage limiter is operably coupled between the array output and the compare input of the comparator and limits a voltage on the compare input to within a predefined range relative to the array output. The successive approximation ADC may also be configured differentially with a second comparator and a second voltage limiter.

Abstract: Energy sharing circuits and related methods are disclosed herein. A high voltage can be selectively coupled to a first source line and a low voltage can be selectively coupled to a second source line during a first time period. During a subsequent time period, a first coupling switch is activated to inductively couple the first source line to the second source line and diode block the second source line from the first source line. During a subsequent time period, the low voltage is selectively coupled to the first source line and the high voltage is selectively coupled to the second source line. During a subsequent time period, a second coupling switch is activated to inductively couple the second source line to the first source line and diode block the first source line from the second source line.

Abstract: A SCR-based based electrostatic discharge protection device with a shunt path is provided. The shunt path operates at a low resistance when an enabling signal of the shunt path is asserted and a high resistance when the enabling signal is negated. The shunt path connects the cathode and the gate of the silicon-controlled rectifier, and provides a conductive path for displacement current from a parasitic capacitance when the shunt path is enabled, such as when power is provided to the device, and further allows the SCR to enter a low-resistance state when the shunt path is not enabled, such as when power is not provided to the device. A threshold trigger circuit is operably coupled between the anode and the cathode of the silicon-controlled rectifier and is configured to provide a current path when the anode voltage reaches a predetermined value lower than a breakdown voltage of the silicon-controlled rectifier.

Abstract: Level shifting circuits and related methods are disclosed herein. The level shifting circuit includes a cross-coupled pull-up circuit coupled to a higher supply voltage, an output signal, and an inverted output signal. An input signal transitions between a ground and a lower supply voltage and an inverted input signal transitions in a direction opposite from the input signal between the ground and the lower supply voltage. A first n-channel transistor has a gate coupled to the lower supply voltage, a drain coupled to the output signal, and a source coupled to the inverted input signal. A second n-channel transistor has a gate coupled to the lower supply voltage, a drain coupled to the inverted output signal, and a source coupled to the input signal. The level shifting circuit may be included in an IC with core logic in a first voltage domain and input/output logic in a second voltage domain.

Abstract: Physical layouts of integrated circuits are provided, which may include an analog-to-digital converter including a plurality of comparators. Individual transistors of each comparator of the plurality are arranged in a one-dimensional row in a first direction. Neighboring comparators of the plurality of comparators are positioned relative to each other in an abutting configuration in a second direction orthogonal to the first direction. The plurality of comparators may include multiple, inter-coupled outputs. Such an ADC may be called a Benorion Analog-to-Digital Converter. A method for fabricating an integrated circuit is also provided.

Abstract: A switch circuit is provided. The switch circuit may include a first transistor having a source terminal to accept an input signal, a drain terminal to provide an output signal, and a gate; a power supply providing a gate voltage. The switch circuit may also include a circuit to couple a switch signal to the gate, wherein the circuit turns the first transistor ‘off’ for all values of the input signal when the switch signal is ‘low.’ A programmable gain amplifier (PGA) is also provided. The PGA may include an input stage having an input node to couple an input signal, and an output node to provide a gate signal, at least a first gain stage including a resistor and a switch circuit as above. A differential gain amplifier may be included to provide an output signal from the gain signal.

Abstract: Temperature-compensation network embodiments are provided to generate compensation signals which may be useful in improving the performance of a variety of important systems. An embodiment includes a limit current mirror configured to provide a limit current, a current generator to provide a slope current whose magnitude varies with temperature, and an output current mirror positioned to receive the limit current and the slope current and configured to provide a compensation current. In addition, a floating voltage reference is provided for use in various networks which include the temperature-compensation networks. The temperature-compensation networks may be used to improve performance in systems such as a panel driver which provides turn-on and turn-off gate voltages to transistors in liquid crystal displays.

Abstract: Level shifting circuits and a related method are disclosed herein. An embodiment of the present invention includes a voltage level shifter, comprising a first pull up transistor coupled to a high voltage signal and a first pull down transistor coupled between the first pull up transistor and a low voltage signal and controlled by an input signal. The voltage level shifter further includes a first bias transistor serially coupled between the first pull up transistor and the first bias transistor. A gate of the first bias transistor is coupled with a bias voltage signal. The voltage level shifter further includes a first additional pull up path coupled with the high voltage signal and a first node between the first pull up transistor and the first pull down transistor, and an output signal associated with the first node. The output signal is a level shifted voltage responsive to the input signal.

Abstract: An analog-to-digital converter with comparators with multiple, inter-coupled, outputs is provided, which may be also called a Benorion Analog-to-Digital Converter (ADC) or a Benorion Converter. The analog-to-digital converter includes a plurality of comparators operably coupled for receiving an analog input signal and configured for comparing the analog input signal with a plurality of voltage reference signals. Each comparator of the plurality is configured for generating a plurality of comparator outputs comprising a primary comparator output, and at least one additional comparator output selected from the group consisting of positive comparator outputs and negative comparator.