Abstract: Herein disclosed are systems and circuitry for protecting against overdrive and electrostatic discharge. For example, protection circuitry may include field effect transistors to discharge overdrive outside of an operational voltage range of a circuit in some embodiments to prevent damage to the circuit. Further, the protection circuitry may utilize diode features inherent in the field effect transistors to protect against electrostatic discharge in some embodiments. The circuitry may be implemented in radio frequency sampling analog-to-digital converters and can provide for single-ended signal input and/or output for the analog-to-digital converters.

Abstract: Herein disclosed are systems and circuitry for protecting against overdrive and electrostatic discharge. For example, protection circuitry may include field effect transistors to discharge overdrive outside of an operational voltage range of a circuit in some embodiments to prevent damage to the circuit. Further, the protection circuitry may utilize diode features inherent in the field effect transistors to protect against electrostatic discharge in some embodiments. The circuitry may be implemented in radio frequency sampling analog-to-digital converters and can provide for single-ended signal input and/or output for the analog-to-digital converters.

Abstract: A common mode feedback (CMFB) loop for a differential amplifier sense an output common mode of a differential circuit and provides feedback to the gates of tail current transistors. Many CMFB loops cannot easily adjust the output common mode voltage and the output common mode may vary over process, voltage, and temperature. An improved CMFB circuit adds a control circuit to control backgates of tail current transistor device(s) of the differential circuit such that the output common mode voltage can be made adjustable.

Abstract: A common mode feedback (CMFB) loop for a differential amplifier sense an output common mode of a differential circuit and provides feedback to the gates of tail current transistors. Many CMFB loops cannot easily adjust the output common mode voltage and the output common mode may vary over process, voltage, and temperature. An improved CMFB circuit adds a control circuit to control backgates of tail current transistor device(s) of the differential circuit such that the output common mode voltage can be made adjustable.

Abstract: A cascaded amplifier including a pre-amplifier stage having a pair of first transistors, each of the first transistors having a first gate terminal coupled to a first input voltage, a trans-conductive (gm) amplifier stage having a pair of second transistors, each of the second transistors having a second gate terminal coupled to a drain terminal of one of the first transistors, and an integrator amplifier stage having a pair of third transistors, each of the third transistors having a third gate terminal coupled to a drain node of one of the second transistors, each of the third transistors having their drain terminals coupled to an output voltage.

Abstract: One embodiment relates to an apparatus configured to cancel charge injected on a node of a differential pair of nodes. A dummy circuit element can inject charge on an inverted node to cancel charge injected on a non-inverted node by a switch when the switch is switched off. In addition, another dummy circuit element can inject charge on the non-inverted node to cancel charge injected on the inverted node by another switch when the other switch is switched off. These dummy circuits elements can be cross-coupled.

Abstract: A cascaded amplifier including a pre-amplifier stage having a pair of first transistors, each of the first transistors having a first gate terminal coupled to a first input voltage, a trans-conductive (gm) amplifier stage having a pair of second transistors, each of the second transistors having a second gate terminal coupled to a drain terminal of one of the first transistors, and an integrator amplifier stage having a pair of third transistors, each of the third transistors having a third gate terminal coupled to a drain node of one of the second transistors, each of the third transistors having their drain terminals coupled to an output voltage.

Abstract: One embodiment relates to an apparatus configured to cancel charge injected on a node of a differential pair of nodes. A dummy circuit element can inject charge on an inverted node to cancel charge injected on a non-inverted node by a switch when the switch is switched off. In addition, another dummy circuit element can inject charge on the non-inverted node to cancel charge injected on the inverted node by another switch when the other switch is switched off. These dummy circuits elements can be cross-coupled.

Abstract: A circuit for sampling an analog input signal may include a transistor disposed on a substrate and a sampling capacitor coupled to one of the source and the drain of the transistor. The transistor may be disposed on a substrate that is coupled to ground. A source and a drain of the transistor may be disposed in a back gate of the transistor. The analog input may be supplied to one of the source and the drain of the transistor, and the back gate may receive a back gate voltage having a value that is lower than ground.

Abstract: A circuit for sampling an analog input signal may include a transistor disposed on a substrate and a sampling capacitor coupled to one of the source and the drain of the transistor. The transistor may be disposed on a substrate that is coupled to ground. A source and a drain of the transistor may be disposed in a back gate of the transistor. The analog input may be supplied to one of the source and the drain of the transistor, and the back gate may receive a back gate voltage having a value that is lower than ground.

Abstract: Signal converter systems are provided which reduce degradation of system bit error rate that is caused by metastable conversion errors which generally occur when analog input signals are near reference thresholds Vth of system comparators. When operating correctly, the comparators generate a corresponding converter code when the input signals cross the threshold. Metastability, however, may cause the comparators to fail to generate the corresponding converter code. In system embodiments, logic is provided to sense the absence of comparator decisions at the end of a predetermined decision period. In response to this absence, the system is configured to substitute the corresponding converter code. In another embodiment, the system is configured to substitute the corresponding converter code when it lies outside a predetermined digital code window.

Abstract: Signal converter systems are provided which reduce degradation of system bit error rate that is caused by metastable conversion errors which generally occur when analog input signals are near reference thresholds Vth of system comparators. When operating correctly, the comparators generate a corresponding converter code when the input signals cross the threshold. Metastability, however, may cause the comparators to fail to generate the corresponding converter code. In system embodiments, logic is provided to sense the absence of comparator decisions at the end of a predetermined decision period. In response to this absence, the system is configured to substitute the corresponding converter code. In another embodiment, the system is configured to substitute the corresponding converter code when it lies outside a predetermined digital code window.

Abstract: Amplifier embodiments are provided that are well suited for systems which require high signal gains and high transient currents that can drive various loads (e.g., capacitive loads). At least one amplifier embodiment is realized with a cascoded complementary differential input stage, a complementary differential output stage, and a bias controller. The output stage includes lower and upper differential pairs of transistors that respectively have lower and upper coupled back gates and the bias controller is configured to provide bias voltages for the lower and upper coupled back gates.

Abstract: Amplifier embodiments are provided that are well suited for systems which require high signal gains and high transient currents that can drive various loads (e.g., capacitive loads). These embodiments are also well suited for electronic systems in which the available amplifier headroom is significantly limited. Exemplary systems are multiplying digital-to-analog converters in pipelined converter systems.

Abstract: Reference generator embodiments are provided with low output impedances to enhance reference stability in the presence of varying loads. The generators are structured to provide these impedances in an efficient manner (i.e., with low supply currents) and also to provide both sink and source currents to better handle large transient current demands. The generators also include cascode structures that facilitate operation with low values of a supply voltage and that provide a low sensitivity to variations in this supply voltage. The embodiments are especially suited for use in signal converter systems.

Abstract: Clock sources are provided which are especially useful for reducing phase noise in signal samplers that typically provide samples of an analog input signal in signal-conditioning systems such as analog-to-digital converters. This phase noise reduction is realized with the recognition that sampler noise is related to clock jitter by a ratio of the input signal's slew rate to the clock's slew rate. Clock embodiments include a frequency divider and a signal gate. The divider divides a first signal to provide a second signal with a slew rate lowered from the slew rate of the first signal and the gate passes the second signal when commanded by the first signal to thereby generate a clock signal.

Abstract: Bias controllers are provided which alter a bias control signal so that a bias signal (e.g., a current signal) of an electronic network rapidly responds to increases in the rate-of-change of the network's analog input signal. This enhances the linearity of a system that includes the electronic network. Subsequent decreases in the rate-of-change are sensed and a decrease of the bias control signal is then paced at a rate selected to ignore short-term rate-of-change variations (e.g., modulation variations) but follow longer-term rate-of-change reductions to thereby enhance system efficiency without sacrificing system linearity.

Abstract: A clock-to-clock auto-ranging ADC operates directly on an analog signal in the IF band or higher to track its gain range on a clock-to-clock basis and produce a digital signal that maintains high resolution of the analog signal without clipping or loss of signal sensitivity. This is accomplished by sampling an analog signal of sufficiently high frequency that a peak detector can accurately determine the maximum signal level over at least one-half a signal period and then reset the signal gain going into the ADC prior to the beginning of the next sampling period. This insures that the analog signal will always be within the range of the ADC. In accordance with the well known principles of sampling theory, the sampled analog signal is aliased into the frequency region between DC and one half the sampling frequency.

Abstract: A high speed wide bandwidth peak detector uses multiple peak detection stages that detect different sub-ranges of a full-scale analog signal range. Splitting the peak detector into multiple stages reduces the number of taps in each stage, and hence their capacitance, which increases their bandwidth. The number of taps can be further reduced by using a non-uniform resolution of the desired full-scale amplitude range. In the preferred embodiment, identical peak detection stages are separated by fixed gain stages that map the different sub-ranges to respective detection stages. This approach minimizes the effects of offset errors in the individual stages but requires gain stages that have wider bandwidths than the detection stages and which can be closely matched to maintain amplitude resolution.

Abstract: A digitally controlled programmable attenuator maintains tight phase matching between attenuated signals over wide ranges of frequencies and power levels regardless of the selected attenuation level. This is achieved with a multi-tap ladder network that sets a desired tap-to-tap dB step-size, a plurality of unity gain digitally switched voltage-to-voltage buffers that are connected between the respective taps and a common output, and a fixed gain stage that sets the attenuator's overall gain/attenuation. The buffers maintain a high and substantially constant impedance whether turned on or turned off. Phase matching within 0.2.degree. at frequencies up to 300 MHz for 30 dB of gain variation has been realized.