Abstract: An air-conditioning apparatus includes a drain pan that receives water, and a detector including an ultrasonic sensor that emits and receives ultrasonic waves. The detector analyzes a response signal from the ultrasonic sensor to detect a contaminant generated in the drain pan. A bottom flat surface portion that forms a bottom of the drain pan is located parallel to a flat surface portion that forms a receiving surface of the ultrasonic sensor.

Abstract: An apparatus includes a boost converter. The boost converter includes a switch and a boost loop filter coupled to the switch. The boost converter also includes a peak current adjustment circuit coupled to the boost loop filter, wherein the peak current adjustment circuit comprises a comparator and a gain control circuit coupled to differential inputs of the comparator. The boost loop filter is configured to provide a control signal to the switch based on an output voltage of the boost converter and a peak current adjustment provided by the peak current adjustment circuit.

Abstract: This invention provides a control circuit for burst switching of a power converter comprising: an adaptive circuit generating an adaptive threshold in response to a feedback signal correlated to an output load of the power converter; and a switching circuit generating a switching signal to switch a transformer of the power converter in accordance with the adaptive threshold and the feedback signal for regulating an output of the power converter.

Abstract: A sample rate converter receives an input signal with an input sample rate, and generates an output signal with an output sample rate. The sample rate converter includes: a rate estimator, a polynomial interpolation calculation circuit, an up sampling filter, and a down sampling filter. The rate estimator includes: a subtractor, which generates an error signal according to an input clock signal and a second order rate signal; a first order integrator, which generates a first order rate signal according to the error signal; and a second order integrator, which generates the second order rate signal according to the first order rate signal.

Abstract: A method for compensating for a dielectric absorption effect in a measurement configuration during measurements by an instrument having measurement terminals includes providing a feedback loop in the instrument, the loop having a gain adjustment and a simulation impedance and being adapted to provide a signal counter to the dielectric absorption at the measurement terminals; applying a transient calibration signal to the test terminals for at least two values of the gain adjustment; measuring a response to the calibration signal for each of the at least two values; and determining an operating value of the gain adjustment based on the measured responses. The operating value is used for subsequent measurements by the instrument, the simulation impedance modeling the dielectric absorption characteristics of the measurement configuration.

Abstract: Circuits and methods for fast detection of a low voltage in the range of few ?Volts have been achieved. In a preferred embodiment the low voltage represents a current via a shunt resistor and the circuit is used to generate a digital wake-up signal. In regard of the wake-up application the circuit invented is activated periodically and in case of a certain level of the voltage drop, e.g. 50 ?V, at the shunt resistor. The time required for a measurement of the voltage drop is inclusive calibration and integration time far below 1 ms. It is obvious that the circuit invented can be used for any measurements of very small voltages.

Abstract: Embodiments of the present invention may include an apparatus and method to reduce an output swing in each stage of a multi-stage loop filter while also maintaining a desired signal transfer function for each respective stage. A given stage of the loop filter may include an integrator, a feedback path, a first cancellation path, and a second cancellation path. The first cancellation path may be coupled to the output of the integrator. The second cancellation path may be coupled to a feedback path provided about the input and output of the integrator. A first cancellation signal may be injected into the first cancellation path to reduce the output swing of the integrator. A second cancellation signal may be injected into the second cancellation path to minimize a change in the integrator's signal transfer function caused by the first cancellation signal.

Abstract: A mixed signal correlator utilizes coherent detection within a capacitance measurement application. In some applications, the mixed signal correlator is used to measure capacitance of a touch screen display. An external capacitor whose capacitance is measured is kept small for improved sensitivity and can be used for a variety of applications having varied integration periods for measurement. The external capacitor is kept small and can be used for varied applications by adjusting the output voltage within a range that is less than the supply voltage, and maintaining a count of the adjustments to later reconstruct an actual output voltage for the integration period. An output is a weighted sum of an analog integrator output and a digital counter output.

Abstract: The present invention provides a circuit for concurrent integration of multiple differential signals. The circuit comprises a plurality of Stage 1 integration circuits arranged in an array and a plurality of Stage 2 integration circuits arranged in an array. Each of the Stage 1 integration circuits is configured to concurrently integrate an input signal, and to send out a Stage 1 positive signal and a Stage 1 negative signal that is reverse to the Stage 1 positive signal. Each of the Stage 2 integration circuits is configured to integrate a differential signal from a Stage 1 positive signal sent from a corresponding Stage 1 integration circuit and a Stage 1 negative signal sent from another Stage 1 integration circuit next to the corresponding Stage 1 integration circuit to output a Stage 2 signal.

Abstract: A transceiver comprises a transmitter that converts a plurality of data components into serial data in response to a first clock signal and transmits the serial data, and a receiver that receives the serial data and converts the serial data into the plurality of data components in response to a second clock signal generated from the serial data. The transmitter adds at least one dummy bit to the serial data at predetermined intervals. The at least one dummy bit includes information regarding a data type of the plurality of data components.

Abstract: System and method for integrating an input signal to generate an output signal. The system includes a first integrator configured to receive the input signal and generate an integrated signal based on at least information associated with the input signal, a second integrator configured to receive the integrated signal and generate the output signal based on at least information associated with the integrated signal, and a compensation capacitor coupled to the first integrator and the second integrator. The first integrator includes a first integration capacitor and a first operational amplifier including a first input terminal and a first output terminal, the first integration capacitor being coupled between the first input terminal and the first output terminal. The second integrator includes a second integration capacitor and a second operational amplifier including a second input terminal and a second output terminal.

Abstract: A structure for performing cross-chip communication with mesochronous clocks. The structure includes: a data delay line; a remote clock delay line; a structure that captures at least one value of a state of a delayed remote clock signal on the remote clock delay line; and a control that influences a delay associated with the data delay line and the remote clock delay line.

Abstract: Circuits, methods, and systems are disclosed in which a current is provided to compensate for spurious current while receiving signals through a line. For example, the spurious current can be sensed and the compensating current can be approximately equal to the sensed spurious current. The spurious current could include photocurrent from a bright light, and the compensating current can prevent bright light effects.

Abstract: A voltage controlled variable capacitor, formed of a larger number of fixed capacitor segments and a corresponding number of switching elements, uses translinear amplifiers to control each switching element. Each translinear amplifier linearly switches from the fully off to the fully on state; a minimum number of switching stages (ideally only one) is in the mode-of-change at any one time with a minimum overlap. The arrangement achieves a nearly linear change of capacitance at linear tuning voltage change, while resulting in high Q-factor due to the low RDSon and high RDSoff of the fully switched stages. The invention eliminates temperature and voltage dependencies of other solutions like varactor diodes.

Abstract: A frequency compensation circuit internal to an integrated circuit which comprises a transconductance amplifier having a first input configured to receive a reference voltage, a second input configured to receive an input voltage and an input current, a first output configured to output a first output current and a second output configured to output a second output current; and a compensation circuit connected to said second output of said transconductance amplifier, wherein said first output is connected to said second input.

Abstract: A sensor signal conditioning circuit and sensor system incorporating the same. In one embodiment, the signal conditioning circuit includes a DC-coupled detector that converts a sensor signal into a discrete level signal. An AC-coupled detector having a dynamic DC threshold input also converts the sensor signal into a discrete level signal and has a startup delay associated with the dynamic DC threshold input. The signal conditioning circuit further includes a device that inhibits the DC-coupled detector responsive to the dynamic DC threshold input reaching a specified threshold voltage level such that the AC-coupled detector provides the detected output during steady-state sensor operation.

Abstract: An apparatus and method for receiving high-speed signals having a wide common-mode range with low input-to-output latency. In one embodiment, the receiver includes an integrator to accumulate charge in accordance with an input signal during an integration time interval to produce an output voltage. A sense amplifier samples and converts the output voltage of the integrator to a logic signal; and a latch stores the logic signal. In an alternate embodiment, a preamplifier conditions the input signal prior to being integrated. In another embodiment using multiple receivers, circuitry is added to the receiver to compensate for timing errors associated with the distribution of the timing signals. In yet another embodiment, the integrator is coupled to an equalization circuit that compensates for intersymbol interference. In another embodiment, another circuit compensates for accumulated voltage offset errors in the integrator.

Abstract: A compensation apparatus maintains an effective resistance of one or more resistors in a circuit by associating an adjustable resistor circuit to each resistor. The compensation apparatus compares the resistance of a resistor in the circuit with the resistance of a reference resistor. When the resistance of the resistor in the circuit falls outside of a desired range, the compensation apparatus adjusts the resistance of the adjustable resistor to adjust the effective resistance of the resistor and adjustable resistor combination.

Abstract: A system for receiving signals (e.g., optical signals) includes an input device, an amplification device, and a feedback device. The amplification device receives a signal from the input device and includes a transimpedance portion. The transimpedance portion includes a first section having a plurality of elements (e.g., resistors and transistors) and a second section having a plurality of elements (e.g., resistors and transistors). One or more of the elements (e.g. transistors or resistors) in the first and second sections are mismatched to introduce a systematic offset in the transimpedance stage, to make the net input referred offset of the amplification device unidirectional. The feedback device (e.g. an integrator) is coupled to an output of the amplification device and an input of the transimpedance portion to provide a unidirectional offset correction to the amplification device for reduced noise enhancement.

Abstract: An apparatus and method for receiving high-speed signals having a wide common-mode range with low input-to-output latency. In one embodiment, the receiver includes an integrator to accumulate charge in accordance with an input signal during an integration time interval to produce an output voltage. A sense amplifier samples and converts the output voltage of the integrator to a logic signal; and a latch stores the logic signal. In an alternate embodiment, a preamplifier conditions the input signal prior to being integrated. In another embodiment using multiple receivers, circuitry is added to the receiver to compensate for timing errors associated with the distribution of the timing signals. In yet another embodiment, the integrator is coupled to an equalization circuit that compensates for intersymbol interference. In another embodiment, another circuit compensates for accumulated voltage offset errors in the integrator.

Abstract: A system for receiving signals (e.g., optical signals) includes an input device, an amplification device, and a feedback device. The amplification device receives a signal from the input device and includes a transimpedance portion. The transimpedance portion includes a first section having a plurality of elements (e.g., resistors and transistors) and a second section having a plurality of elements (e.g., resistors and transistors). One or more of the elements (e.g. transistors or resistors) in the first and second sections are mismatched to introduce a systematic offset in the transimpedance stage, to make the net input referred offset of the amplification device unidirectional. The feedback device (e.g. an integrator) is coupled to an output of the amplification device and an input of the transimpedance portion to provide a unidirectional offset correction to the amplification device for reduced noise enhancement.

Abstract: A method for synchronizing a plurality of programmable timing verniers with a reference pulse signal, each of the vernier being programmable to one of a plurality of timing steps within a delay range and the delay range being determined by a control signal applied to a bias input, the method comprising the steps of selecting a first and second control vernier from the plurality of verniers; programming the first control vernier to a first delay; programming the second control vernier to a second delay; triggering the first and second control verniers together to generate respective first and second delay signals; generating a difference pulse signal having a duty cycle corresponding to a difference between the generated first delay signal and second delay signal; comparing the duty cycle of the pulse signal to a duty cycle of the reference pulse signal to generate a difference signal pulse, the difference signal being coupled to the bias input of the verniers to adjust the delay range such that the duty cycle

Abstract: Two variations of a continuous-time instantaneous companding filter are integrated in a 25 GHz bipolar process. Their −3 dB frequencies are tunable in the ranges of 1-30 MHz and 30-100 MHz. The dc gains are controllable up to 10 dB. The measured dynamic ranges for a 1% total harmonic distorsion are 62.5 dB and 50 dB, for the 30 MHz and 100 MHz filters respectively. At maximum cutoff frequencies, the filters dissipate 6.5 mW from a 1.2 V supply. The filters are simple, common-mode interference-resistant, class AB log-domain integrators, suitable for implementation in low-cost bipolar processes. They are suitable for realizing low-voltage filters with reasonable linearity and signal-to-noise ratio. ALL-NPN low distortion input and output interface stages can be added to the integrators. The filters can be used to realized high-frequency programmable filters.

Abstract: A method and apparatus for minimizing errors in a sensor device due to signal amplitude variation are disclosed herein. A signal output from the sensor device is amplified and, thereafter, AC-coupled to a comparator such that the amplification and AC-coupling of the signal minimize offset shift-related errors associated with the sensor device. The signal can be coupled to eliminate offset shifts due to component mismatches, calibration, aging and/or temperature associated with the sensor device. An AC-coupled sensor signal conditioning circuit is utilized to amplify the signal through an amplifier and then AC-couple the signal to a comparator.

Abstract: Methods and systems for tuning an RC continuous-time filter are disclosed. In this regard a representative system for tuning an RC continuous-time filter includes a coarse-tuned resistive element coupled to an input of the filter for varying the cut-off frequency of the filter based upon process variations. The system also includes a MOSFET transistor coupled to the resistive element. The MOSFET transistor provides a resistance dependent upon a voltage offset provided to the gate of the transistor, wherein the resistance of the transistor offsets an adjustment in the resistance of the resistive element caused by temperature variations. The system also includes a voltage offset generator configured to provide the voltage offset to the transistor.

Abstract: A gain controller using switched capacitors is provided. The gain controller is operable in a sampling mode or an amplifying mode and controls the gain of an analog input signal. The gain controller includes an operational amplifier, input capacitors, a feedback capacitor, and switches. The operational amplifier controls the gain of the analog input signal and generates an output signal having the controlled gain. The input capacitors are connected to the input side of the operational amplifier in parallel. The feedback capacitor is connected between the input side and the output side of the operational amplifier. The switches connect at least one of the input capacitors to the input signal or a reference voltage, in response to the kinds of operation modes and a predetermined externally applied digital gain control signal.

Abstract: A system and method for temperature-compensated small signal peak detection. A small amplitude signal peak detector includes an exponential operator for generating a modulated signal through the application of an exponential function to the input signal. The peak detector also includes an averaging circuit for obtaining the average value of the modulated signal and an inverting offset stage for inverting the signal and removing an offset component. The resulting signal is directly proportional to the peak value of the input signal. The peak detector further includes a temperature compensation circuit for canceling the temperature-dependent effects introduced by the exponential operator and averaging means. The temperature compensation circuit is a thermistor with temperature-dependent characteristics matched to the temperature-dependent characteristics of the circuit when operated without a temperature compensation circuit.

Abstract: A perfect integrator emulator includes a first multiplier multiplying an input with a first constant, KNEW, and generating a scaled input, a summer summing the scaled input with a previously generated scaled output and generating an accumulated output, a delay adding a predetermined amount of delay to the accumulated output and generating a delayed output, a second multiplier multiplying the delayed output with a second constant, KOLD, and generating the scaled output. The constants KNEW and KOLD are chosen such that the accumulated output emulates a perfect integrator's relative weighting, and saturation protection is guaranteed.

Abstract: An electronically trimable capacitor (10) having a plurality of branch circuits (30) each including a capacitor (32) which may be selectively controlled by a switch (34) to contribute or not to the net capacitance exhibited by the trimable capacitor (10). Operation of the switches (34) is under direction of an interface (36), which can receive a program signal containing digital instruction for programming via a program terminal (22). An optional memory (38) permits storing a program of states for the switches (34), so that the interface (36) maybe instructed to reset the switches (34) and thus cause the trimable capacitor (10) again provide a previously programmed net capacitance, say, in the event of power on or a power loss. An optional enable terminal (24) provides protection against inadvertent programming.

Abstract: A circuit for generating a ramped voltage having controlled maximum amplitude (e.g., for use in a switching controller), and a method for generating such a ramped voltage without use of a comparator. The ramped voltage is a voltage developed across a periodically charged and discharged capacitor, or optionally a level-shifted version of such voltage. Preferably, a ring oscillator generates a clock signal (without use of a comparator) for use in controlling the periodic charging and discharging of the capacitor, and a feedback loop generates a supplemental charging current for the capacitor in response to feedback indicative of the ramped output voltage.

Abstract: In accordance with a specific embodiment of the present invention, a system is disclosed having an analog to digital converter and control module. The analog-to-digital converter includes an analog input, digital output, and control input. The control input of the analog-to-digital converter is connected to a pulse width modulated output of the control module which provides an offset pulse width modulated signal. During a first portion of the offset pulse width modulated signal a sampling capacitor is charged. During a second portion of the offset pulse width modulated signal an integration capacitor is charged.

Abstract: An offset integrator and method are provided to induce integrator leakage while simultaneously latching and canceling its own offset. The method includes combining a first and second input signals with a part of the output signal of a different polarity to produce a charge signal. An accumulation of the charge signal on a plurality of storage components is used to reduce the offset component of the output signal and simultaneously inducing an integrator leak. A positive and negative components of the input signals are combined with a negative and positive offset components of the part of the output signal, respectively. The method liner includes modifying a positive and negative components of an in-phase and a quadrature signal. A reset signal may be provided to erase a plurality of memory locations. A gating scheme may be used to provide a predetermined signal to produce a two-phase, non-overlapping signal.

Abstract: A system and method, wherein the dielectric absorption of a capacitor is cancelled by a compensating circuit. One embodiment uses a compensation circuit comprising a compensating capacitor with substantially identical characteristics as the capacitor to be compensated in an integrator circuit. The effects of the dielectric absorption of the capacitor in the integrator circuit are reduced or eliminated because the dielectric absorption of the compensating capacitor cancels the dielectric absorption of the capacitor in the integrator circuit. Another embodiment uses compensation circuitry to reduce or eliminate the effects of dielectric absorption in any particular capacitor. The compensation capacitor in the compensation circuitry has a higher rate of dielectric absorption and a lower capacitance value than the capacitor whose dielectric absorption effects are to be reduced or eliminated.

Abstract: There is provided a comparator circuit which does not output any erroneous comparison result even if the resistance value of a resistance component that exists in the input circuit for a voltage comparator is large.

Abstract: The invention relates to an elementary biquadratic cell for programmable time-continuous analog filters. The biquadratic cell is coupled between a first voltage reference and a second voltage reference and has at least one pair of input terminals and first and second pairs of output terminals. The cell includes a pair of half-cells, which half-cells are structurally identical with each other. Each half-cell comprises at least a first transistor coupled between the first and the second voltage reference and having a base terminal connected to a respective one of the input terminals. Each half-cell further comprises second and third transistors coupled between the first and second voltage references. The second transistor has a base terminal connected to the first output terminal of the first pair of output terminals and a collector terminal connected to the first output terminal of the second pair of output terminals.

Abstract: Capacitor voltage coefficient errors are reduced in a lossy integrator by providing oppositely oriented first and second feedback capacitors in a switched capacitor feedback circuit coupled between the output and a summing conductor connected to an inverting input of an operational amplifier. During a first clock signal, terminals of the first feedback capacitor are coupled to a reference voltage by closing first and second reset switches and the second feedback capacitor is coupled between the inverting input and the output conductor by closing first and second sampling switches. Then, during a second clock signal the terminals of the second feedback capacitor are coupled to the first reference voltage by closing third and fourth reset switches, and the second feedback capacitor is coupled between the inverting input and the output by closing third and fourth sampling switches.

Abstract: To achieve a constant control range in an integrator-filter circuit for filtering a push-pull signal, having at least two integrator elements (1) this second control current being having resistors (11, 12) arranged at its inputs, a subsequent current multiplier (13) having two signal inputs (14, 15) and preceding a push-pull amplifier (18) with an inverting input (20) and a non-inverting input (19), having inverting output (21) fed back to the non-inverting input (19) and a non-inverting output (23) fed back to the inverting input (20) via capacitances (22, 24), the current multiplier (13) receiving, at two control inputs (37, 38), a first and a second control current (I.sub.1, I.sub.2) for adjusting the integration time constant of the integrator element (1) is adjustable and from which the second control current (I.sub.2) flows in substantially two halves through the signal inputs (14, 15) of the current multiplier (13), an associated third control current (I.sub.

Abstract: A sub-bandgap reference circuit yielding a reference voltage smaller than the bandgap voltage of silicon. The circuit generates a negative temperature coefficient signal V.sub.be and an oppositely tracking (positive temperature coefficient) .DELTA.V.sub.be, and takes the average of two signals related to .DELTA.V.sub.be -V.sub.be to yield a temperature-compensated voltage of one-half the bandgap voltage of silicon. The circuit features an unequal area current mirror feeding the diodes and resistors used to generate the .DELTA.V.sub.be -V.sub.be signals using low supply voltages (less than 1.5 volts). A standard CMOS implementation provides low power consumption at a supply voltage of only 1 volt with a good temperature coefficient. The averaging circuit may be implemented by a continuous time divider or by using switched capacitor techniques. The loop amplifier used in the .DELTA.V.sub.be -V.sub.

Abstract: A level detector detects an input signal level. A rectifier (210) receives the input signal and provides a rectified signal. A prefilter (220) receives the rectified signal and attenuates high frequency components at frequencies near multiples of a decimation sample rate. The prefiltered signal is decimated (230) and low pass filtered by a lowpass filter (240) having a passband below the input frequency of the input signal. The level detector can be provided to control a variable gain stage circuit (935, 1010) which applies a gain to the input signal based on the level to form a dynamic range compressor or expander.

Abstract: An integrating circuit includes an operational amplifier and an integrating capacitor which is decoupled from the output of the operational amplifier and precharged to a positive reference voltage before each integration cycle. During each integration cycle the operational amplifier output decreases from the reference voltage toward but not below ground. This allows the operational amplifier to be included as a front-end integrator to a delta-sigma analog-to-digital converter that is powered only by a single power supply. In the described embodiment, the output is coupled to an input of an auto-zeroing stage which provides negative feedback to stabilize the operational amplifier when the integrating capacitor is disconnected during precharging and a bandwidth control input which couples a larger compensation capacitance to reduce the bandwidth during integration to reduce RMS noise.

Abstract: A signal integrator stabilization circuit comprises an operational amplifier functioning as a comparator. The circuit further comprises an attenuator in the amplifier's feedback, thereby generating a feedback signal which is sampled to produce a sampling signal. The integrator is driven with a preselected ratio of the feedback signal and the sampling signal to produce a stabilized output signal approaching a zero value which has a good DC stability without compromising the ability to accurately integrate high frequency signals.

Abstract: An integrator-multiplier-integrator circuit scheme usable in transverse fers, a transverse filter employing such a circuit, and a method for using each. The multiplier-integrator-multiplier has a capacitatively loaded integrating amplifier fed by a transistor. The current through the transistor, and hence the time it takes to charge the integrating capacitor, depends largely on the bias of the transistor, not the size of the capacitor, permitting one to set and control integration time by setting the transistor's parameters, and controlling its bias, effectively controlling integration time by us of only one semiconductor device. An additional circuit for auto-zeroing (i.e. canceling quiescent offset) increases adaptivity of the circuit. Preferably the phase of inputs to the first multiplier is made selectably variable to minimize phase difference at the multiplier, thus increasing circuit stability.

Abstract: A simple, low-cost circuit and method for line zing parasitic capacitances of transistor junctions, independent of the process technology employed, are provided. In the preferred embodiment, the parasitic capacitance of a transistor in a track and hold circuit is linearized by providing a pair of diodes that act inversely to the parasitic diodes formed within the integrated circuit during normal tracking operations. Without the diodes of the present invention, the varying input signals cause the parasitic capacitance to vary, thereby causing harmonic distortion in the track and hold circuit. An alternate embodiment of the present invention is also provided in which a second complementary transistor is provided. The inclusion of the complementary transistor results in a second set of parasitic capacitances that are substantially opposite the parasitic capacitances of the track and hold transistor.

Abstract: A non-linear integrator of a closed loop integration system selectively modifies the gain of the closed loop integration system in order to avoid system saturation while still experiencing high gain in a desired linear portion of the system. A non-linear integrator structure and method allow the gain of the closed loop integration system to be selectively modified in order to avoid saturation while experiencing high gain. The non-linear integrator includes an amplifier, a current source element which generates a bias input signal, a bias circuit which provides the bias input signal to the amplifier and allows the bias input signal to be selectively modified, a storage element coupled to the amplifier, and a gain element, coupled to the storage element, which produces an output signal determined by voltage on the storage element. A voltage input signal and a bias input signal are supplied to the amplifier which generates an amplifier output signal.

Abstract: A transconductance filter (200) comprises multiple stages of a transconductor (110,120,130) having an input and an output, and a switch (260,265,270) coupled between the output and the voltage source. The switch is operatively responsive to the control signal for coupling and decoupling the voltage source directly to the output of the transconductor at least prior to the time the filter is required to filter the input voltage signal. The voltage source is within a predetermined input voltage range of the transconductor defined by a region in which a transconductance of the transconductor is substantially constant and positive.

Abstract: The invention is an autozero compensator for use in processing low level signals, the compensator comprising an input integrating operational amplifier providing at its output in one mode an error signal responsively to offset voltage across the differential input terminals of the amplifier. A second amplifier is provided in a feedback loop for generating from the error signal a charge at a compensating voltage equal and opposite to the offset voltage. That charge is capacitively stored and applied to the input amplifier to cancel the offset voltage.

Abstract: An integrator is disclosed that is capable of outputting the same integration result with respect to the same bit pattern even if there are fluctuations in the integrating period, semiconductor device process, or the power supply voltage. The disclosed integrator includes: (1) a first integrator having a first amplifier, for integrating a reference voltage during an integrating period, (2) a second integrator having a second amplifier, for integrating an input signal during the integrating period, and (3) control means for outputting a signal regulating a gain of the first amplifier to the first amplifier so that an output of the first integrator varies in correspondence with the integrating period, and for regulating a gain of the second amplifier by means of the signal.

Abstract: A sampled data filter (400) provides on-chip blocking of DC signals. The addition of a very long time constant (VLTC) integrator (412) into the negative feedback path (414) of a first sampled data integrator (402) provides a lower corner frequency (502) with a zero at DC. The lower corner frequency (502) is adjustable while the desired frequency response is maintained.

Abstract: A switched capacitor differential circuit switches first and second differential input signals (Vinp1, Vinp2) to respective inputs (A, B) of an operational amplifier (12) via respective first and second signal paths. Each signal path includes a coupling capacitor (13, 14) and two switching devices (2, 3 and 4, 5) to switch the input signals to charge the capacitors at a first phase of a clock signal and to discharge the capacitors onto the inputs of the amplifier at a second phase of the clock signal. In order to remove common mode spikes from transferring to the amplifier, a pair of comon mode capacitors (16, 17) are coupled between the inputs and a common node (15), which is coupled via a pair of switches (6, 7) to the first and second signal paths between the capacitors and the second of the switching devices so that the coupling capacitors are discharged relative to the common node.

Abstract: A sign bit integrator and method for generating a signal to correct an offset in a signal processing system that can distort the output from the system. A charge pulse is generated when the sign of a input signal is sampled in order to provide an offset correction signal with a polarity opposite that of offsets in the system. The charge pulse is provided to a pair of transistors whose size ratio sets the magnitude of the charge pulse. The polarity of the charge pulse is set responsive to a sign bit in the input signal. An integrator capacitor provides the offset correction signal to the signal processing system. A third transistor may be switchably substituted for one of the pair of transistors to change the ratio of sizes and thus change the magnitude of the charge pulse to thereby change the speed with which the offset correction is made. The sign bit integrator and method may be used to correct distortion in a voice signal in a telephone system.