Abstract: A digital-to-analog (DAC) element may include a plurality of switches arranged to form two circuit branches between a current source and a first and a second outputs. The first circuit branch may include two switches defining parallel current paths between the current source and the first output terminal. The second circuit branch may include two switches defining parallel current paths between the current source and the second output terminal. A control circuit, responsive to an input signal that selects one of the circuit branches, may provide control signals to close one of switches in the selected circuit branch in a first portion of a clock cycle and to close the other of the switches in the selected circuit branch in a second portion of the clock cycle.

Abstract: In an example, a multistring DAC is described and includes at least two DAC stages. Each DAC stage includes a string of impedance elements and a switching network. In one configuration, the multi-string DAC is configured to use the voltage change at terminals of a first string separately to the voltage drop across a first switching network that couples the first and second strings to provide an analog output in response to a digital input to the DAC.

Abstract: An analog switch may be maintained reliably in an off state. The switch comprises: a P-type first transistor having a source, a drain and a gate, a N-type second transistor having a source, a drain and a gate, and a switch control circuit to drive the gates of the first and second transistors. The drain of the first transistor and the source of the second transistor are connected at a first node, and the source of the first transistor and the drain of the second transistor are connected at a second node. When the voltage at the first or second nodes falls outside of a supply voltage range of the switch control circuit, the switch control circuit is operable, in response to a signal to make the switch high impedance, by adjusting the gate voltages of the first transistor and the second transistor.

Abstract: In one aspect, an electrical signal converter is disclosed. The exemplary electrical signal converter may include a plurality of ordered converter elements. Element selection logic may be provided to pseudorandomly select a pointer to a switch matrix, wherein the switch matrix maps converter elements according to a stepwise “delta-two-maximum pattern.” Advantageously, pseudorandom stepwise delta-two-maximum patterns may be applied both to a first order converter, and to a feedback converter for error correction.

Abstract: A silicon substrate is provided that may facilitate the formation of RF components more cheaply by using a silicon layer formed by the Czochralski process, and having a carrier life time killing layer deposited on the silicon layer.

Abstract: The present disclosure discloses a digital-to-analog converter (DAC) design which is suitable for providing a high output power high-speed DAC, e.g., in radio frequency applications. The DAC design utilizes a parallel DAC structure, e.g., having 8 parallel DACs and an aggregate current output, to provide a high and programmable current output (in some implementations, up to 512 mA or more). The parallel DAC structure alleviates the design problems which exist in trying to output a high amount of current using a single DAC. The DAC design further utilizes a hybrid structure which integrates the signal chain for a more reliable system. In some embodiments, the hybrid structure uses a CMOS process for the current sources and switches and a GaAs cascode stage for combining the outputs to optimally leverage the advantages of both technologies. The result is a highly efficient DAC (with peak output power programmable up to 29 dBm or more).

Abstract: In an example embodiment, a signal processor is disclosed that is configured to decode a clock-first, change-on-zero differential Manchester encoded data stream. The data stream has no local clock, and both combinatorial and sequential logic is used to decode the stream into a clocked data signal and an optional error signal. Decoding comprises a parser that separates the input data stream into an intermediate data signal, an intermediate clock signal, and a conditioning signal. A data and error generator receives the three signals and outputs a clocked data signal and a clocked error signal.

Abstract: A phase corrector for laser trimming a component, the phase corrector comprising: a first correction structure located to a first side of the component, the first correction structure comprising first and second correction regions at first and second distances from the component; and a second correction structure located to a second side the component, the second correction structure comprising third and fourth correction regions at third and fourth distances from the component.

Abstract: A proportional to absolute temperature, PTAT, circuit is provided. By judiciously combining circuit elements it is possible to generate a voltage at an output node of the circuit that is temperature dependent. Such a PTAT circuit can be used as a temperature sensor or can be combined with other temperature dependent circuits to provide a voltage reference.

Abstract: A power converter can include an electrical isolation circuit between input and output nodes. An input signal monitor node can be provided, such as on a converter output side of the isolation circuit. In an example, a peak detection circuit can be coupled to the input signal monitor node. The output node of the power converter can be configured to supply an output power signal that is a function of an input signal at the input node. The power converter can include multiple, independently-switchable switches at one or more of the input and output sides of the isolation circuit. In an example, the power converter with the input signal monitor node can be configured as a bias supply to provide power, at the output node, to a controller circuit for a main stage power converter circuit.

Abstract: A signal processing device has a first discrete time analog signal processing section, which has an input, an output, a plurality of charge storage elements, and plurality of switch elements coupling the charge storage elements. The device has a controller coupled to the first signal processing section configured to couple different subsets of the charge elements of the first signal processing section in successive operating phases to apply a signal processing function to an analog signal presented at the input of the first signal processing section and provide a result of the applying of the signal processing function as an analog signal to the output of first signal processing section. The signal processing function of the first signal processing section comprises a combination of a filtering function operating at a first sampling rate and one or more modulation functions operating at corresponding modulation rates lower than the first sampling rate.

Abstract: Embodiments of the present disclosure may provide a relaxation oscillator with improved performance against phase noise error. The phase noise error may be reduced from sources whose power is greater at lower frequencies. To reduce the noise error, the relaxation oscillator may include chopping in the charging current driver; chopping in the trigger level generator; and/or chopping in the currents that feed the cells. A chopped amplifier may be provided to perform chopping of the input signals.

Abstract: In one example implementation, the present disclosure provides a loop filter for use in a continuous-time sigma-delta analog-to-digital converter. Specifically, a capacitive feedback digital-to-analog converter path is provided at the input of a first opamp in a series of opamp integrators. The capacitive feedback digital-to-analog converter at the input of the first opamp reduces the signal content at the output of the first opamp, and thereby reduces the output swing of the first opamp. A reduction in output swing provides a more efficient loop filter.

Abstract: A digital-to-analog conversion system includes a digital-to-analog converter and an output stage for converting an output signal of the digital-to-analog converter into a voltage range. The output stage includes a first amplifier including a first input for receiving the output signal of the digital-to-analog converter, a first resistance element coupled between a second input and an output of the first amplifier, a second resistance element coupled between the second input of the first amplifier and a ground reference, and a third resistance element switchably coupled from the second input of the first amplifier to an offset voltage.

Abstract: The Hough transform for circles can be implemented in a manner that avoids random access to the Hough accumulator array by successively identifying center candidates in each line of the image based on edge pixels in corresponding lines voting on the line of interest.

Abstract: In an example, there is disclosed a digital signal processor having a register containing a modular integer configured for use as a thread offset counter. In a multi-stage, pipelined loop, which may be implemented in microcode, the main body of the loop has only one repeating stage. On each stage, the operation executed by each thread of the single repeating stage is identified by the sum of a fixed integer and the thread offset counter. After each pass through the loop, the thread offset counter is incremented, thus maintaining pipelined operation of the single repeating stage.

Abstract: A method and system for encoding an analog signal on a stochastic signal, the encoded signal then converted to a digital signal by an analog to digital converter, the analog to digital converter thereafter decoding from the encoded signal a digital signal, which corresponds to the analog signal. The stochastic signal may be a noise signal shaped to a Gaussian normal curve. An encoding process is performed by a multiplication circuit, which multiplies the stochastic signal by the analog signal, producing a product signal for an analog to digital conversion. During analog to digital conversion, the product signal is decoded. The decoding is performed using an arithmetic operation, which may be a Root Sum Square function or a Root Means Square function. The decoded signal is then mapped to account for offset error, gain error, and endpoint adjustment. The result is a decoded digital signal corresponding to the analog signal.

Abstract: An all digital model of nonlinear transmitter signal distortion in signals received at a receiver of a transmitter-receiver may be used to estimate distortion. The estimated distortion may then be cancelled from the received signals to improve signal quality of the received signal. The digital nonlinear model may be part of an estimator circuit that estimates nonlinear distortion terms by applying a formula or transformation to a digitized version of the signals transmitter at a transmitter of the transmitter-receiver. A mixer may be used to shift a frequency of the estimated nonlinear terms away from a transmitter frequency so that the nonlinear terms can later be subtracted from the incoming signal received at the receiver at a receiver frequency. Circuits and methods are provided.

Abstract: Apparatus and methods for current sensing in switching regulators are provided. In certain implementations, a switching regulator includes a switch transistor, a replica transistor, a current source, a sense resistor, and a current sensing circuit. The drain and gate of the switch transistor can be electrically connected to the drain and gate of the replica transistor, respectively. Additionally, the current sensing circuit can control the voltage of the source of the replica transistor based on the polarity of a current through the switch transistor to generate an output current that changes in response to the switch transistor's current. The sense resistor can receive an offset current from the first current source and the output current from the current sensing circuit such that the voltage across the sense resistor changes in relation to the current through the switch transistor.

Abstract: Apparatus and methods for buffer linearization are provided. In certain implementations, an amplifier includes a buffer circuit and a gain circuit. The buffer circuit includes a buffer transistor pair used to buffer a differential input signal to generate a differential buffered signal. Additionally, the gain circuit includes a gain transistor pair configured to amplify the buffered differential signal to generate an amplified differential signal. The buffer circuit can include a linearization transistor pair configured to decrease the buffer circuit's output impedance and to provide feedback that reduces changes in the voltage of the differential buffered signal in response to displacement currents associated with the CJC or CGD capacitances of the gain transistor pair.