Abstract: An LDO regulator (10) produces an output voltage (Vout) by applying the output voltage to a feedback input (6) of a differential input stage (10A) and applying an output (3) of the differential input stage to a gate of a first follower transistor (MP4) having a source coupled to an input (8) of a class AB output stage (10C) which generates the output voltage. Demanded load current is supplied by the output voltage during a dip in its value to a gate of a second follower transistor (MP5) having a gate coupled to the output of the input stage to decrease current in a current mirror (MN5,6) having an output coupled to a current source (I1) and a gate of an amplifying transistor (MN7). This causes the current source to rapidly turn on the amplifying transistor to cause it to rapidly turn on a cascode transistor (MN3), causing it to turn on a pass transistor (MP3) of the output stage.

Abstract: Charge pump circuitry (30) compares bottom plate voltages of first (C1) and second (C2) flying capacitors in a current mode charge pump (1B) to a reference value (VDD?V28) by means of a comparator (20) which drives a flip-flop (22) that generates first (F1) and second (F2) complementary phase signals. The first and second phase signals control switching of the flying capacitors to determine a flying capacitor swapping frequency just low enough to prevent saturation of a discharge current source (10) that discharges the flying capacitors into an output conductor (3).

Abstract: Charge pump circuitry (30) compares bottom plate voltages of first (C1) and second (C2) flying capacitors in a current mode charge pump (1B) to a reference value (VDD?V28) by means of a comparator (20) which drives a flip-flop (22) that generates first (F1) and second (F2) complementary phase signals. The first and second phase signals control switching of the flying capacitors to determine a flying capacitor swapping frequency just low enough to prevent saturation of a discharge current source (I0) that discharges the flying capacitors into an output conductor (3).

Abstract: An LDO regulator (10) produces an output voltage (Vout) by applying the output voltage to a feedback input (6) of a differential input stage (10A) and applying an output (3) of the differential input stage to a gate of a first follower transistor (MP4) having a source coupled to an input (8) of a class AB output stage (10C) which generates the output voltage. Demanded load current is supplied by the output voltage during a dip in its value to a gate of a second follower transistor (MP5) having a gate coupled to the output of the input stage to decrease current in a current mirror (MN5,6) having an output coupled to a current source (I1) and a gate of an amplifying transistor (MN7). This causes the current source to rapidly turn on the amplifying transistor to cause it to rapidly turn on a cascode transistor (MN3), causing it to turn on a pass transistor (MP3) of the output stage.

Abstract: An electronic device has an LDO regulator for varying loads. The LDO regulator includes a primary supply node coupled to a primary voltage supply. An output node provides a secondary supply voltage and a load current. A bias current source generates a bias current. A gain stage coupled to the bias current source increases the maximum available load current. The gain stage includes a first MOS transistor biased in weak inversion coupled to a current mirror which mirrors the drain current through the first MOS transistor to the output node. The gate-source voltage of the first MOS transistor increases in response to a decreasing secondary supply voltage level at the output node to increase the available load current.

Abstract: A class AB output stage includes first (MP) and a second (MN) output transistors having sources coupled to first (VDD) and second reference voltages, respectively, drains coupled to an output (13), and gates coupled to first (11A) and second (12A) conductors, respectively. Portions of first (IIN1) and a second (IIN2) input currents are sourced via a first input conductor (11) and a second input conductor (12), respectively, into and from sources of first (M2) and second (M4) transistors, respectively. Gates of the first (M2) and second (M4) transistors are coupled to the first and second conductors, respectively. First (VrefP) and second (VrefN) bias voltages are applied to gates of third (M1) and fourth (M3) transistors respectively, having sources coupled to the first and second input conductors, respectively, and drains coupled to the second conductor.

Abstract: A class AB output stage includes first (MP) and a second (MN) output transistors having sources coupled to first (VDD) and second reference voltages, respectively, drains coupled to an output (13), and gates coupled to first (11A) and second (12A) conductors, respectively. Portions of first (IIN1) and a second (IIN2) input currents are sourced via a first input conductor (11) and a second input conductor (12), respectively, into and from sources of first (M2) and second (M4) transistors, respectively. Gates of the first (M2) and second (M4) transistors are coupled to the first and second conductors, respectively. First (VrefP) and second (VrefN) bias voltages are applied to gates of third (M1) and fourth (M3) transistors respectively, having sources coupled to the first and second input conductors, respectively, and drains coupled to the second conductor.

Abstract: A charge pump for generating an input voltage for an operational amplifier includes a storage capacitor for storing a charge pump voltage and a flying capacitor configured to be charged during a first phase of operation and discharged during a second phase of operation. Discharging the flying capacitor charges the storage capacitor. A current source supplies the flying capacitor and a switching means switches current from the current source through the flying capacitor in a first direction during the first phase and in a second opposite direction during the second phase.

Abstract: An amplifier includes first and second pairs of differentially coupled input transistors. The first current mirror generates a reference current which is mirrored by a second current mirror to produce a mirrored reference current. Current steering circuitry steers the mirrored reference current as a first tail current through the first pair when a common mode voltage associated with a differential input voltage exceeds a first reference voltage. A first portion of the mirrored reference current flows from the first current steering circuitry when the common mode voltage is greater than the first reference voltage to produce a second tail current for the second pair. A second portion of the mirrored reference current is fed back to an output of the first current mirror and summed with the reference current so as to reduce the second portion when the common mode voltage is greater than the first reference voltage.

Abstract: An amplifier includes first and second pairs of differentially coupled input transistors. The first current mirror generates a reference current which is mirrored by a second current mirror to produce a mirrored reference current. Current steering circuitry steers the mirrored reference current as a first tail current through the first pair when a common mode voltage associated with a differential input voltage exceeds a first reference voltage. A first portion of the mirrored reference current flows from the first current steering circuitry when the common mode voltage is greater than the first reference voltage to produce a second tail current for the second pair. A second portion of the mirrored reference current is fed back to an output of the first current mirror and summed with the reference current so as to reduce the second portion when the common mode voltage is greater than the first reference voltage.

Abstract: An operational amplifier includes an input stage for producing a voltage signal in response to an input signal. An output stage includes an output transistor having a source coupled to a supply voltage and a gate coupled to receive the voltage signal. An output cascode transistor has a source coupled to a drain of the output transistor and a drain coupled to an output conductor. A gate control amplifier includes an input stage including a first input transistor having a control electrode coupled to the source of the output cascode transistor and an active load transistor, the input transistor and the active load transistor being coupled to a gate of the output cascode transistor. The gate control amplifier also includes a feedback amplifier having an input coupled to the source of the output cascode transistor and an output coupled to a control electrode of the active load transistor.

Abstract: A class-AB output stage circuit is configured with controllable reference voltages for providing stable quiescent current. An exemplary output stage circuit comprises one or more control circuits, such as feedback loops, configured to control and/or adjust the reference voltages within the class-AB circuit based on the output voltage and/or supply rail voltage levels. In addition, an exemplary output stage circuit can also comprise one or more clamp circuits configured to facilitate operation of the output stage circuit when the output supply is proximate to or exceeds a positive or a negative supply rail.

Abstract: A class AB output circuit includes a P-channel pullup transistor (M13) having a source coupled to a supply voltage, a drain coupled to an output(10), a gate coupled to respond to an input signal on an input(9), an N-channel pulldown transistor (M1) having a drain coupled to the output, a source coupled to ground, and a gate coupled to respond to the input signal. A first N-channel transistor (M2) has a drain coupled to a gate of the output transistor and the supply voltage by means of a current source (8) and a source coupled to ground by means of a second current source (13). A first diode-connected N-channel transistor (M3), a second diode-connected N-channel transistor (M4), and a first level shifting circuit (17) are coupled in series between ground and a gate of the N-channel transistor, and a current source (7) is coupled between the first supply voltage and the gate of the first N-channel transistor.

Abstract: A method and circuit is provided for improving the control of the trimming procedure for various devices without the need for additional dedicated control pins. Instead, the trimming procedure is controlled through sensing of changes in current and/or voltage applied through the existing available pins or bondpads of the devices to determine whether a command for trim programming has occurred. As a result, package-level trimming of the devices can be conducted in standard device packages having low pin count configurations, such as operational amplifiers, instrumentation amplifiers, difference amplifiers, low drop-out regulators, voltage references and other similar types of devices. A device to be trimmed is configured with internal circuitry configured to sense changes in current and/or voltage in the output or supply voltage of the device, and a test system for applying changes in the current and/or voltage through the existing available pins or bondpads of the devices.

Abstract: A CMOS circuit including a P-channel pull-up transistor (MP) and an N-channel pull-down transistor (MN) includes a first feedback circuit (6) producing a first delayed signal (V7) on the gate of the pull-down transistor (MN) to turn on the pull-down transistor (MN) a first predetermined amount of time after the pull-up transistor (MP) is turned completely off so as to prevent any shoot-through current from flowing through the pull-up transistor (MP) and the pull-down transistor (MN) and a second feedback circuit (4) producing a second delayed signal (V5) on the gate of the pull-up transistor (MP) to turn on the pull-up transistor (MP) a second predetermined amount of time after the pull-down transistor (MN) is turned completely off so as to prevent any shoot-through current from flowing through the pull-up transistor (MP) and the pull-down transistor (MN).

Abstract: A method and circuit is provided for improving the control of the trimming procedure for various devices without the need for additional dedicated control pins. Instead, the trimming procedure is controlled through sensing of changes in current and/or voltage applied through the existing available pins or bondpads of the devices to determine whether a command for trim programming has occurred. As a result, package-level trimming of the devices can be conducted in standard device packages having low pin count configurations, such as operational amplifiers, instrumentation amplifiers, difference amplifiers, low drop-out regulators, voltage references and other similar types of devices. A device to be trimmed is configured with internal circuitry configured to sense changes in current and/or voltage in the output or supply voltage of the device, and a test system for applying changes in the current and/or voltage through the existing available pins or bondpads of the devices.

Abstract: A gain boost circuit is provided in a differential amplifier including differentially connected first and second input transistors the drains of which are coupled to sources of first and second cascode transistors. A third cascode transistor has a source coupled to a drain of the first cascode transistor and a drain coupled to a bias current source. A gain boost amplifier has an output coupled to the gate of the third cascode transistor, a first input coupled to the drain of the first cascode transistor, and a second input coupled to the drain of the second cascode transistor.

Abstract: A gain boost circuit is provided in a differential amplifier including differentially connected first and second input transistors the drains of which are coupled to sources of first and second cascode transistors. A third cascode transistor has a source coupled to a drain of the first cascode transistor and a drain coupled to a bias current source. A gain boost amplifier has an output coupled to the gate of the third cascode transistor, a first input coupled to the drain of the first cascode transistor, and a second input coupled to the drain of the second cascode transistor.

Abstract: A CMOS circuit including a P-channel pull-up transistor (MP) and an N-channel pull-down transistor (MN) includes a first feedback circuit (6) producing a first delayed signal, (V7) on the gate of the pull-down transistor (MN) to turn on the pull-down transistor (MN) a first predetermined amount of time after the pull-up transistor (MP) is turned completely off so as to prevent any shoot-through current from flowing through the pull-up transistor (MP) and the pull-down transistor (MN) and a second feedback circuit (4) producing a second delayed signal (V5) on the gate of the pull-up transistor (MP) to turn on the pull-up transistor (MP) a second predetermined amount of time after the pull-down transistor (MN) is turned completely off so as to prevent any shoot-through current from flowing through the pull-up transistor (MP) and the pull-down transistor (MN).

Abstract: Over-current protection is accomplished in an output transistor (MP) of an electronic circuit wherein an input signal (Vgatedrive) Is Applying to a first conductor (19) coupled to a gate of the output transistor to cause an output current (Iout) to flow through the output transistor and an output terminal (11) of the electronic circuit. A limit voltage (VLIMIT) who is applied to an input (21) of a voltage clamping circuit (18) to cause a clamping current to flow in the first conductor (19) as needed to prevent the magnitude of the input signal (Vgatedrive) from being less than the magnitude of the limit voltage (VLIMIT) so that the output current (Iout) is limited to a maximum current limit determined by the limit voltage (VLIMIT).