Abstract: A control system may be selectively operated in open loop mode, for example, during data bursts. In a power control system, the transmitted power may be selectively held at a constant level, for example, at the end of a ramp period. The forward path gain of a control system may be varied in an inverse-function manner ahead of an integrator. The slope of a measurement signal from a detector may be made to have a complementary polarity.

Abstract: A variable gain amplifier includes an attenuator having a plurality of pairs of tap points, and a plurality of pairs of gm cells, wherein each pair of gm cells is coupled to a corresponding pair of the tap points, and each pair of gm cells is constructed and arranged to operate as a multi-tanh cell.

Abstract: An input stage receives a differential input signal at first and second input nodes and provides a differential output current at first and second output nodes. The differential output current includes a component taken from the input nodes through first and second impedances, and an additional component generated in response to a sample of the voltage of the differential input signal. A transconductance cell having cross-coupled inputs may generate the additional component of the output current.

Abstract: A circuit includes a multi-tanh cell having a common-emitter node to receive a bias current, and an extra transistor coupled to the common-emitter node to dynamically divert a portion of the bias current from the multi-tanh cell. The circuit may be arranged as a multiplier with an input network arranged to apply two or more input signals to the multi-tanh cell. A second multi-tanh cell with an extra transistor may be arranged in a feedback loop where the outputs of the first and second multi-tanh cells are coupled together at an integrating node. A buffer drives the final output and feedback cell to cancel nonlinearities in the multiplier cells.

Abstract: A gain-phase detector differentially processes the outputs from two logarithmic amplifiers to provide ratiometric gain measurement, thereby eliminating intercept as a parameter. Hard-limited outputs from the dual amplifiers are multiplied in a logarithmic scalable phase detector core to provide a calibrated phase measurement output. In the preferred embodiment, two logarithmic amplifiers and other circuitry are co-integrated on a single substrate to provide a high degree of matching between the amplifiers, thereby canceling errors in the individual frequency responses of the individual amplifiers, extending the usable frequency response, and improving effective noise figure. Other numbers of logarithmic amplifiers can be used, and their various outputs can be added, subtracted, multiplied and combined in other manners to produce continuous products, continuous quotients, mixtures of products and quotients, etc., all of RF demodulated signals.

Abstract: A logarithmically-responding circuit includes a differential-input amplifier that drives the control terminal of a three-terminal device that exhibits an exponential response in its output current. This arrangement allows the third terminal to be grounded. In a preferred embodiment the three-terminal device is a bipolar junction transistor (BJT). This, and other supporting circuit features described, enable single-supply, wide-range, fully temperature-compensated operation. A compensation technique significantly reduces errors caused by the finite ohmic emitter resistance of a BJT. To support use in logarithmically compressing the current generated by a photodiode, an adaptive bias signal can provided which maintains an essentially constant bias on the photodiode's internal junction.

Abstract: Variable attenuation systems having continuous input steering may be used to implement vector or quadrature modulators and vector multipliers. Discrete implementations of attenuators with continuous input steering may have two outputs which may be cross-connected to provide four-quadrant operation. A symmetrically driven center tap may provide improved zero-point accuracy.

Abstract: A variable attenuation system includes a steering core that continuously steers a signal to an attenuator having multiple inputs. An embodiment having an attenuator constructed from discrete components continuously interpolates a signal between the individual inputs of the attenuator. Continuous interpolation between discrete inputs can also be used with attenuators having continuous structures. A fully integrated embodiment achieves continuous input steering by moving a carrier domain along a continuous attenuator. A separate output stage utilizes adaptive biasing to reduce unnecessary current consumption.

Abstract: An interpolator utilizes two ranks of transistors to generate a plurality of interpolator currents within the confines of a low power supply voltage. The first rank of transistors are underdriven, thereby generating a plurality of partially switched currents having shallow Gaussian-shaped functions. The partially switched currents are then spatially amplified by the second rank of transistors to reduce the overlap of the currents from adjacent transistors. The first rank of transistors are driven ratiometrically by the difference of two control currents, thereby eliminating errors caused by inaccurate resistors and current sources. A biasing op-amp senses the interpolator currents and servos the first rank of transistors, thereby regulating the interpolator currents to a value determined by a reference voltage which is temperature compensated. Thus, the biasing op-amp automatically compensates for temperature variations and manufacturing uncertainties in devices throughout the entire interpolator.

Abstract: A squaring cell combines first and second exponential currents to approximate square law behavior. The exponential currents can be generated by current stacks having pairs of series-connected junctions. The exponential currents can be altered to change the shape of the exponential currents to better approximation true square law behavior. A multiplier combines four exponential currents to approximate a multiplication function. The exponential currents in the multiplier can be generated by current stacks that are cross-connected so as to generate two output currents, the difference of which represents the multiplication of two input signals.

Abstract: Variable attenuation systems having continuous input steering may be used to implement vector or quadrature modulators and vector multipliers. Discrete implementations of attenuators with continuous input steering may have two outputs which may be cross-connected to provide four-quadrant operation. A symmetrically driven center tap may provide improved zero-point accuracy.

Abstract: A variable gain amplifier includes an attenuator having a plurality of pairs of tap points, and a plurality of pairs of gm cells, wherein each pair of gm cells is coupled to a corresponding pair of the tap points, and each pair of gm cells is constructed and arranged to operate as a multi-tan h cell.

Abstract: A logarithmically-responding circuit includes a differential-input amplifier that drives the control terminal of a three-terminal device that exhibits an exponential response in its output current. This arrangement allows the third terminal to be grounded. In a preferred embodiment the three-terminal device is a bipolar junction transistor (BJT). This, and other supporting circuit features described, enable single-supply, wide-range, fully temperature-compensated operation. A compensation technique significantly reduces errors caused by the finite ohmic emitter resistance of a BJT. To support use in logarithmically compressing the current generated by a photodiode, an adaptive bias signal can provided which maintains an essentially constant bias on the photodiode's internal junction.

Abstract: A translinear amplifier is disclosed. A loop amplifier drives the bases of the input and output transistor pairs from the differential collector voltage of the input pair. The loop amplifier contains a third differential pair (a gain pair). The tail current of the gain pair is inversely related to the tail current of the input pair, such that loop amplifier gain remains stable when the transconductance of the input pair changes (due, e.g., to input gain changes). In one embodiment, a linear-in-dB interface is provided that adjusts input pair tail current exponentially (and gain pair tail current exponentially and inversely) to linear voltage changes at a gain input.

Abstract: An amplifier has an input terminal to receive an input signal. The amplifier includes a first gain stage comprising a pair of input transistors and a second gain stage to drive an output stage. The output stage provides inverting and non-inverting differential output signals on inverting and non-inverting output nodes. The amplifier may also include a feedback signal electrically connected between the inverting and non-inverting output nodes to emitters of the input transistors through a resistor network.

Abstract: Variable attenuation systems having continuous input steering may be used to implement vector or quadrature modulators and vector multipliers. Discrete implementations of attenuators with continuous input steering may have two outputs which may be cross-connected to provide four-quadrant operation. A symmetrically driven center tap may provide improved zero-point accuracy.

Abstract: A gain-phase detector differentially processes the outputs from two logarithmic amplifiers to provide ratiometric gain measurement, thereby eliminating intercept as a parameter. Hard-limited outputs from the dual amplifiers are multiplied in a logarithmic scalable phase detector core to provide a calibrated phase measurement output. In the preferred embodiment, two logarithmic amplifiers and other circuitry are co-integrated on a single substrate to provide a high degree of matching between the amplifiers, thereby canceling errors in the individual frequency responses of the individual amplifiers, extending the usable frequency response, and improving effective noise figure. Other numbers of logarithmic amplifiers can be used, and their various outputs can be added, subtracted, multiplied and combined in other manners to produce continuous products, continuous quotients, mixtures of products and quotients, etc., all of RF demodulated signals.

Abstract: A gain-phase detector differentially processes the outputs from two logarithmic amplifiers to provide ratiometric gain measurement, thereby eliminating intercept as a parameter. Hard-limited outputs from the dual amplifiers are multiplied in a logarithmic scalable phase detector core to provide a calibrated phase measurement output. In the preferred embodiment, two logarithmic amplifiers and other circuitry are co-integrated on a single substrate to provide a high degree of matching between the amplifiers, thereby canceling errors in the individual frequency responses of the individual amplifiers, extending the usable frequency response, and improving effective noise figure. Other numbers of logarithmic amplifiers can be used, and their various outputs can be added, subtracted, multiplied and combined in other manners to produce continuous products, continuous quotients, mixtures of products and quotients, etc., all of RF demodulated signals.

Abstract: An amplifier has an input terminal to receive an input signal. The amplifier includes a first gain stage comprising a pair of input transistors and a second gain stage to drive an output stage. The output stage provides inverting and non-inverting differential output signals on inverting and non-inverting output nodes. The amplifier may also include a feedback signal electrically connected between the inverting and non-inverting output nodes to emitters of the input transistors through a resistor network.

Abstract: An RMS-to-DC converter implements the difference of squares function using two squaring cells operating in opposition to attain a balance. Each of the squaring cells is implemented as a grounded-base transistor and a two-transistor current mirror. The emitter of the grounded-base transistor is coupled to the input terminal of the current mirror at a node which receives the input signal. The collector of the grounded-base transistor and the output of current mirror are coupled together to generate an output current having a square-law relationship to the input signal. One of the squaring cells receives the input signal and operates at high frequencies (HF), while the other receives a feedback signal and operates in a quasi-DC mode. In a measurement node, a nulling circuit closes a feedback loop around the DC squaring cell to null the output currents from the squaring cells.