Abstract: A current-mode switching regulator that maintains a substantially constant maximum current limit over a virtually full range of duty cycles is provided. The regulator has a control circuit that includes a buffer circuit, an adjustable voltage clamp circuit, and a slope compensation circuit. The buffer circuit isolates a control signal from capacitive loading associated with control circuit. The threshold level of the adjustable voltage clamp circuit varies with respect to the amount of slope compensation provided to the voltage regulator. This allows a control voltage to increase as slope compensation increases so that a substantially constant maximum current limit is maintained.

Abstract: Power measuring receiver (PMR) methods and apparatus for measuring power of signals are provided in which a high frequency measuring circuit (HFMC), a conversion measuring circuit (CMC), and an intermediate frequency measuring circuit (IFMC) work in conjunction with each other to measure a wide power range of signals. The HFMC may measure relatively high power signals at high frequency. The CMC may convert the high frequency signal into an intermediate frequency signal so that both the CMC and the IFMC can accurately measure low power signals. The CMC may also set the minimum noise bandwidth associated with gain stages in the IFMC. The intermediate frequency may provide the IFMC with the ability to perform low power measurements at a reduced DC power consumption.

Abstract: Circuits and methods for controlling load sharing by multiple power supplies are provided. In preferred embodiments, load share controllers utilize multiple voltage control loops to monitor the output voltages that are being provided by multiple power supplies connected to a load. These voltage control loops each generate a voltage control voltage that is proportional to the difference between the actual output voltage of the corresponding power supply and the desired output voltage. The voltage control loop with the highest voltage control voltage then controls a current control voltage generated in a current control loop for each power supply via a share bus. These current control loops then regulate the current provided by the corresponding power supplies so that those currents are all proportional to the voltage on the share bus.

Abstract: The invention provides apparatus and methods for generating the coefficients of a finite impulse response digital filter used in signal sample rate conversion. Sequence generation circuitry provides a discrete-time sequence x(n) that is coupled to a plurality of cascaded discrete-time integrators that generate the filter coefficients h(n). Bit serial and interleaved bit serial implementations are described that provide efficient coefficient generators. The described apparatus and methods also may be used to efficiently implement a finite impulse response digital filter for an oversampling analog-to-digital converter.

Abstract: A multi-phase multi-channel voltage regulator having high efficiency at light loads is provided. The regulator increases efficiency at light loads by shutting down a select channel of the regulator. In addition, the regulator may place remaining channels in Burst Mode.

Abstract: A high voltage MOS transistor is provided that is compatible with low-voltage, sub-micron CMOS and BiCMOS processes. The high voltage transistor of the present invention has dopants that are implanted into the substrate prior to formation of the epitaxial layer. The implanted dopants diffuse into the epitaxial layer from the substrate during the formation of the epitaxial layer and subsequent heating steps. The implanted dopants increase the doping concentration in a lower portion of the epitaxial layer. The implanted dopants may diffuse father into the epitaxial layer than dopants in the buried layer forming an up-retro well that prevents vertical punch-through at high operating voltages for thin epitaxial layers. In addition, the doping concentration below the gate may be light so that the threshold voltage of the transistor is low.

Abstract: The present invention relates to analog computation circuits that use a synchronous demodulator topology which can be configured to perform arithmetic computation, power measurements, and/or energy measurement of various analog signals. The computation circuits have circuitry that generates an output signal based on the values of a first input signal, a second input signal, and a reference signal. This invention provides accurate computation of two signals by using modulation circuitry (e.g., &Dgr;-&Sgr; modulation circuitry), demodulation circuitry (e.g., multiplying digital-to-analog converters), delay circuitry, and output circuitry.

Abstract: A circuit and method for controlling a switching voltage regulator having (1) a switch including one or more switching transistors and (2) an output adapted to supply current at a regulated voltage to a load including an output capacitor. The circuit and method generates a control signal to turn said one or more switching transistors OFF under operating conditions when the voltage at the output is capable of being maintained substantially at the regulated voltage by the charge on the output capacitor. Such a circuit and method increases the efficiency of the regulator circuit particularly at low average current levels.

Abstract: Methods and circuits implementing a constant-current/constant-voltage circuit architecture are provided. The methods and circuits preferably provide a charging system that provides current to a load using a fixed current until the load is charged. When the load is charged, the methods and circuits preferably provide a variable current to the load in order to maintain the voltage level across the load. This variable current varies according to the voltage across the load. In one embodiment of the invention, a constant power current may also be used as one of the load charging currents. The constant power current may act as a limit on the charging circuit's power output.

Abstract: A circuit that provides the root-mean-square (RMS) value of an input signal and that detects and independently recovers from an output fault condition is provided. The circuit includes reconfigurable circuitry that changes from normal operating mode to fault recovery mode when an output fault is detected. During fault recovery mode, the circuit provides a modified output signal that allows independent recovery from an output fault condition. Once recovery is complete, the circuit returns to normal operating mode and provides a DC output signal proportional to the RMS value of an AC input signal.

Abstract: The present invention provides a capacitor charging circuit that efficiently charges capacitive loads. In particular, circuits and techniques are preferably provided for using current from both the primary and secondary windings of a transformer to control ON-time and OFF-time of a switch. This arrangement preferably yields an adaptable ON-time and adaptable OFF-time switch that is capable of rapidly charging capacitor loads ranging from as low as zero volts to several hundred volts. The output voltage is preferably measured indirectly to prevent unnecessary power consumption. In addition, control circuitry can be provided to conserve power by ceasing the delivery of power to the capacitor load once the desired output voltage is reached. Control circuitry preferably operates an interrogation timer that periodically activates the power delivery cycle to maintain the capacitor output load in a constant state of readiness.

Abstract: Circuits and methods for extending the input common mode voltage range of a JFET op-amp are provided. The circuits and methods consist of modifying the input stage of a JFET op-amp to include a BJT pair as the input differential pair and use a JFET pair as followers. Using the BJTs as the input differential pair enables the JFET followers to operate in the linear region of operation when the op-amp's input is approaching ground, thereby increasing the negative common mode voltage range. The positive common mode voltage range is increased by reducing the source current in the JFET pair and using a transistor pair as clamping transistors.

Abstract: The present invention relates to analog computation circuits that use a synchronous demodulator topology which can be configured to perform arithmetic computation, power measurements, and/or energy measurement of various analog signals. The computation circuits have circuitry that generates an output signal based on the values of a first input signal, a second input signal, and a reference signal. This invention provides accurate computation of two signals by using modulation circuitry (e.g., &Dgr;-&Sgr;modulation circuitry), demodulation circuitry (e.g., multiplying digital-to-analog converters), delay circuitry, and output circuitry.

Abstract: A voltage reference circuit capable of operating at reduced quiescent currents is described. The voltage reference circuit comprises an output circuit, a timer circuit and a control circuit. When in standby mode, in order to decrease power consumed by the output circuit, current through the output circuit is decreased, allowing the voltage at the output node to fall outside of a desired range. To determine when this event has occurred, the control circuit includes a test circuit that generates a test signal characterized by having a voltage that is correlated with the voltage at the output terminal.

Abstract: Power measuring receiver (PMR) methods and apparatus for measuring power of signals are provided in which a high frequency measuring circuit (HFMC), a conversion measuring circuit (CMC), and an intermediate frequency measuring circuit (IFMC) work in conjunction with each other to measure a wide power range of signals. The HFMC may measure relatively high power signals at high frequency. The CMC may convert the high frequency signal into an intermediate frequency signal so that both the CMC and the IFMC can accurately measure low power signals. The CMC may also set the minimum noise bandwidth associated with gain stages in the IFMC. The intermediate frequency may provide the IFMC with the ability to perform low power measurements at a reduced DC power consumption.

Abstract: A high-speed, current-driven latch is provided. The latch conducts a current and includes an output, a SET circuit and a RESET circuit. The output is variable between a first state and a second state. The SET circuit conducts the current present in the latch at the first state such that the SET circuit is maintained close to a level required to change the output of the transistor from the first to the second level, and the RESET circuit conducts the current at the second level such that the RESET circuit is close to a level required to change the output of the transistor from the second level to the first level.

Abstract: Techniques and circuits for high speed switching of transistors are provided. These techniques and circuits switch an output device while varying the drive current to the output device in proportion to the output current through the output device. In addition, these techniques and circuits provide a switching circuit with substantially no quiescent currents. This is accomplished by sampling the output current conducted by the output device and using the sample as a signal to drive either the output device fully ON or to switch the output device fully OFF.

Abstract: A high voltage MOS transistor is provided that is compatible with low-voltage, sub-micron CMOS and BiCMOS processes. The high voltage transistor of the present invention has dopants that are implanted into the substrate prior to formation of the epitaxial layer. The implanted dopants diffuse into the epitaxial layer from the substrate during the formation of the epitaxial layer and subsequent heating steps. The implanted dopants increase the doping concentration in a lower portion of the epitaxial layer. The implanted dopants may diffuse father into the epitaxial layer than dopants in the buried layer forming an up-retro well that prevents vertical punch-through at high operating voltages for thin epitaxial layers. In addition, the doping concentration below the gate may be light so that the threshold voltage of the transistor is low.

Abstract: A high voltage MOS transistor with a gate extension that has a reduced electric field in the drain region near the gate is provided. The high voltage MOS transistor includes a first and second gate layers, and a dielectric layer between the gate layers. The first and second gate layers are electrically coupled together and form the gate of the transistor. The second gate layer extends over the drain of the transistor above the dielectric and gate oxide layers to form the gate extension. The gate extension reduces the peak electric field in the drain by providing a wide area for the voltage to drop between the drain and the gate of the transistor. The dielectric layer also reduces the peak electric field in the drain near the gate by providing insulation between the gate and the drain. A lower electric field in the drain reduces the impact generation rate of carriers.

Abstract: Methods and circuits implementing a constant-current/constant-voltage circuit architecture are provided. The methods and circuits preferably provide a charging system that provides current to a load using a fixed current until the load is charged. When the load is charged, the methods and circuits preferably provide a variable current to the load in order to maintain the voltage level across the load. This variable current varies according to the voltage across the load. In one embodiment of the invention, a constant power current may also be used as one of the load charging currents. The constant power current may act as a limit on the charging circuit's power output.