Abstract: System-on-chip (SOC) products using high frequency, wideband, highly linear, CMOS and BiCMOS processes will be the next evolution of wireless and wireline communications integrated circuits. Aspects described herein can provide enhanced overall performance over existing prior art single-ended, wideband RF amplifier topologies. A single-ended third order intermodulation distortion nulling circuit can extend the dynamic range for wideband amplifiers up to an order-of-magnitude, without a DC power or noise figure (NF) penalty. The application of distortion nulling can be extended to all the building blocks used in CMOS/BiCMOS RF transceivers to improve performance. The application of this concept to all of the building blocks in an RF transceiver will allow the dynamic range of the transceiver to be increased without suffering a DC power dissipation increase or a significant noise increase.

Abstract: System-on-chip (SOC) products using high frequency, wideband, highly linear, CMOS and BiCMOS processes will be the next evolution of wireless and wireline communications integrated circuits. Aspects described herein can provide enhanced overall performance over existing prior art single-ended, wideband RF amplifier topologies. A single-ended third order intermodulation distortion nulling circuit can extend the dynamic range for wideband amplifiers up to an order-of-magnitude, without a DC power or noise figure (NF) penalty. The application of distortion nulling can be extended to all the building blocks used in CMOS/BiCMOS RF transceivers to improve performance. The application of this concept to all of the building blocks in an RF transceiver will allow the dynamic range of the transceiver to be increased without suffering a DC power dissipation increase or a significant noise increase.

Abstract: A latch circuit providing isolated input current paths includes a pair of input transistors that receive a differential input signal. A plurality of steering transistors receive a portion of a differential clock signal. The latch circuit includes a positive output node and a negative output node. A first bypass input current path is associated with the first input transistor and is electrically isolated from the positive output node and the negative output node. A second bypass input current path associated with the second input transistor is also electrically isolated from the positive output node and the negative output node. In a latched state, the clock signal is operative to selectively bias the plurality of steering transistors such that current is steered to one of the first input current path or the second input current path, thereby being isolated from the output nodes.

Abstract: System-on-chip (SOC) products using high frequency, wideband, highly linear, CMOS and BiCMOS processes will be the next evolution of wireless and wireline communications integrated circuits. Aspects described herein can provide enhanced overall performance over existing prior art single-ended, wideband RF amplifier topologies. A single-ended third order intermodulation distortion nulling circuit can extend the dynamic range for wideband amplifiers up to an order-of-magnitude, without a DC power or noise figure (NF) penalty. The application of distortion nulling can be extended to all the building blocks used in CMOS/BiCMOS RF transceivers to improve performance. The application of this concept to all of the building blocks in an RF transceiver will allow the dynamic range of the transceiver to be increased without suffering a DC power dissipation increase or a significant noise increase.

Abstract: A reconfigurable wideband analog-to-digital converter (ADC) system comprising a first converter stage including a first sample and hold circuit for sampling an input signal, a first ADC configured to generate a digital representation of the sampled input signal from the first sample and hold circuit, and a first digital-to-analog converter (DAC) responsive to the output of the first ADC and configured to generate an analog representation of the digital representation of the sampled input signal. A control processor is provided and configured to generate a digital control signal. A current control circuit is responsive to the digital control signal for generating an analog current control signal for selectively altering a characteristic of at least one of the first ADC and the first DAC.

Abstract: A flash analog to digital converter (ADC) provides a temperature compensated trim current by applying a first temperature compensated reference current across a replica resistor ladder. The reference current is mirrored to a trim digital to analog converter, which outputs a fractional portion of the temperature compensated reference current. The proportional trim current is then fed back to the reference current to provide a trimmed temperature compensated reference current. The trimmed reference current is mirrored across the output resistor ladder providing a trimmed current in which the trim varies along with temperature changes due to the trim current being a proportion of the temperature compensated reference current. A proportional trim current which varies with temperature changes is applied to the gain current trim and mismatch current trim in a DAC of a quantizing stage of a sub-ranging ADC.

Abstract: A single camera capable of capturing high speed laser return pulses for a target, as well as provide imaging information on the background of the target. This capability is enabled by having a read-out integrated circuit (ROIC) capable of extracting both types of information from a pixel of a focal plane array (FPA). Further, an ROIC topology that allows for the ability to distinguish between high frequency and low frequency signal paths, and provide supporting circuitry to process the two paths separately. One path may integrate the low frequency background scene to provide a high fidelity image of the scene. The second path may process high frequency noise and multiple laser pulse returns within a frame. These two paths may be combined to provide a background image with a superimposed laser return.

Abstract: Embodiments of the invention describe solutions directed towards having a single camera capable of capturing high speed laser return pulses for a target, as well as provide imaging information on the background of the target. This capability is enabled by having a read-out integrated circuit (ROIC) capable of extracting both types of information from a pixel of a focal plane array (FPA). Embodiments of the invention describe an ROIC topology that allows for the ability to distinguish between high frequency and low frequency signal paths, and provide supporting circuitry to process the two paths separately. One path may integrate the low frequency background scene to provide a high fidelity image of the scene. The second path may process high frequency noise and multiple laser pulse returns within a frame. These two paths may be combined to provide a background image with a superimposed laser return.

Abstract: An electronic circuit for distributing a clock signal to several clock destinations includes phase adjustment circuits for adjusting phase shifts of the clock at the respective one of the clock destinations responsive to a respective DC voltage feedback signal receive from the respective one of the clock destinations; phase detectors for detecting a phase shift of the clock signal at the respective one of the clock destinations according to a nearest neighbor clock destination; loop filters for generating and transmitting respective DC voltage feedback signals; current sources, each configured to receive the respective DC voltage feedback signal and output a respective current to a respective one of the phase adjustment circuits according to said respective DC voltage feedback signals to adjust the phase shift of the clock signal for the respective one of the clock destinations.

Abstract: An electronic circuit for distributing a clock signal to a plurality of clock destinations includes phase adjustment circuits for adjusting phase shifts of the clock at the respective one of the clock destinations responsive to a respective DC voltage feedback signal receive from the respective one of the clock destinations; phase detectors for detecting a phase shift of the clock signal at the respective one of the clock destinations according to a nearest neighbor clock destination; and loop filters for generating and transmitting respective DC voltage feedback signals. The circuit further includes current sources, each configured to receive the respective DC voltage feedback signal and output a respective current to a respective one of the phase adjustment circuits according to said respective DC voltage feedback signals to adjust the phase shift of the clock signal for the respective one of the clock destinations.

Abstract: A wideband low noise amplifier (LNA) includes a correction circuit added to compensate for third order intermodulations. A version of the third order nonlinearities created in the main LNA is created in an auxiliary, low power scaled version of the LNA, phased appropriately using a current mirror, and subtracted from the main signal path by summing, thus providing a cancellation of the third order intermodulation (IM) terms in the main signal path leaving a signal remaining which is significantly more spectrally pure than the signal produced by the LNA before correction.

Abstract: A low distortion amplifier. The novel amplifier includes a first transistor Q1 having first and second output terminals and an input terminal adapted to receive an input signal, and a second transistor Q2 having first and second output terminals and an input terminal adapted to receive a signal from the first output terminal of Q1, wherein the second output terminal of Q1 is connected to the second output terminal of Q2 in order to eliminate a nonlinear current component in Q2. In an illustrative embodiment, the amplifier also includes a cascode Darlington pair Q3, Q4 for holding the second output terminals of Q1 and Q2 at a desired voltage to further reduce distortion and to maintain a wide bandwidth.

Abstract: Disclosed is a LADAR system and a method for operating same. The LADAR system includes circuitry for generating the electrical signal with an optical signal detector using N discrete samples; a bank of M parallel sample/hold circuit unit cells individual ones of which operate with an associated sample/hold clock, where each sample/hold clock is shifted in time by a fixed or programmable amount ?t relative to a sample/hold clock of an adjacent sample/hold circuit unit cell; and further includes circuitry for sequentially coupling a sampled value of the electrical signal from a first output of individual ones of at least some of the M parallel sample/hold circuit unit cells to an analog to digital converter circuit. Each of the M parallel sample/hold circuit unit cells has a second output for outputting a digital signal for indicating the state (low or high) during a time that the associated sample/hold clock allowing for time of arrival determination.

Abstract: A digitizing analog front end (DAFE) using mixed technology on a single substrate is described. SiGe BiCMOS technology is implemented for the semiconductor components, which include a low noise amplifier and an analog-to-digital converter. Micro Electro Mechanical System (MEMS) switches are used to change the filtering characteristics of several filters, including an anti-aliasing filter and a pre-select and anti-jamming filter.

Abstract: A trimmable comparator. The novel comparator includes a first circuit for comparing first and second input signals and in accordance therewith generating first and second output signals, and a second circuit for adding an adjustable current to the first output signal such that the comparator is in a transition state when the first and/or second input signals are at desired levels. The comparator may also include a third circuit for adding an adjustable current to the second output signal. In the illustrative embodiments, the second and third circuits are implemented using adjustable current sources with trimmable resistors, or using digital to analog converters. The novel comparators may be used in an analog to digital converter to allow the converter thresholds to be adjusted to desired levels.

Abstract: A multi-mode analog to, digital converter (ADC). The novel ADC includes an input terminal for receiving an analog input signal; a plurality of processing stages, each processing stage adapted to generate an output signal from an input to that processing stage; and a mechanism for determining a mode of operation and in accordance therewith connect the processing stages and the input terminal in a predetermined configuration. In an illustrative embodiment, the ADC can be configured as a subranging ADC, and the mechanism for determining, the mode of operation includes a signal processor for automatically selecting the mode of operation based on the frequency components of the input signal.

Abstract: A high speed switch. The novel switch includes an input circuit having a transistor Q1 for receiving an input signal, a first mechanism for providing a path from an output of Q1 to an output terminal, and a second mechanism for receiving a control signal and in accordance therewith reducing the conductivity of the path during a mute mode. The first mechanism includes a first circuit for providing a first path from an output of Q1 to a first node, and a second circuit for providing a second path connecting the first node to the output terminal. The second mechanism is adapted to apply a signal to the first node during the mute mode such that the first and second circuits are off or partially conducting. The switch also includes a circuit for clamping the first node to a first predetermined voltage during the mute mode.

Abstract: An output driver. The novel output driver includes a first circuit for receiving an input signal and in accordance therewith generating an output signal at an output node, a second circuit for applying a variable current to the output node, and a third circuit for controlling the magnitude of the variable current in accordance with the input signal. In an illustrative embodiment, the third circuit is adapted to generate a controlling current in accordance with the input signal, and the second circuit includes a current mirror adapted to receive the controlling current and output a scaled version of the controlling current to the output node.

Abstract: A digitally trimmed current source. The novel current source includes a first circuit for generating a current in response to an applied voltage and a resistance variable in response to a control signal, and a second circuit for supplying the control signal. The first circuit includes a resistive network comprised of a plurality of resistors; a plurality of switches, each switch coupled to one of the resistors and adapted to selectively switch the resistor in and out of the resistive network in response to the control signal; and a transistor adapted to apply a voltage across the resistive network to generate a current.

Abstract: A sample and hold circuit including a first arrangement for receiving an input signal; a second arrangement for sampling and holding the signal in response to a control signal; and a third arrangement for minimizing the change in an input transistor's base current when the circuit switches from track to hold or hold to track and for keeping the collector emitter voltage constant at the input transistor. An arrangement is disclosed to increase the dynamic current accuracy of a current mirror for a diode connected transistor, by holding the voltage across one transistor in the current mirror constant. Another arrangement is disclosed for holding collector to emitter voltage constant for intermediate transistors resulting in improved gain accuracy and linearity. In one embodiment, a dummy leg is added to isolate the output voltage from switching transients that occur when an intermediate transistor is turned on at the transition from track to hold.