Abstract: A measuring circuit includes a dither tone generator circuit and a digital signal processing circuit. The dither tone generator circuit generates a dither tone, and injects the dither tone to a delta-sigma analog-to-digital converter that is offline. The digital signal processing circuit processes a digital output of the delta-sigma analog-to-digital converter with the dither tone injected, to generate a Q-factor measurement result of a resonator-based loop filter included in the delta-sigma analog-to-digital converter.

Abstract: Described herein are DACs with low distortion for high dynamic range (HDR), extremely high dynamic range (EHDR), and other suitable applications. Some embodiments relate to a device including a DAC configured for coupling to an amplifier via a force path and a sense path. For example, the DAC may provide output current to the amplifier via the force path, and the DAC may sense the input voltage of the amplifier via the sense path. Accordingly, distortion such as harmonic distortion and/or gain offset from parasitic impedances in the force and/or sense paths may be reduced or eliminated. Some embodiments relate to a DAC including a voltage reference generator configured to compensate for variations in impedances of the DAC, such as due to semiconductor process variation. Accordingly, distortion in the DAC output due to variations in the DAC impedances may be reduced or eliminated.

Abstract: Circuits and methods for converting digital input signals into the analog domain are described. Such circuits may perform the conversion in a segmented fashion. For example, a circuit may include a most significant bit (MSB) path and a least significant bit (LSB) path. The MSB path may include a first delta-sigma modulator having first and second outputs and a first digital-to-analog converter coupled to the first output of the first delta-sigma modulator. The LSB path comprises a second delta-sigma modulator comprising a loop filter and a quantizer. The quantizer may have an input coupled to the loop filter and to the digital filter. The LSB path may further include a second digital-to-analog converter coupled to an output of the quantizer. The circuit may further include a digital filter and/or a gain stage interposed between the MSB path and the LSB path.

Abstract: Described herein are DACs with low distortion for high dynamic range (HDR), extremely high dynamic range (EHDR), and other suitable applications. Some embodiments relate to a device including a DAC configured for coupling to an amplifier via a force path and a sense path. For example, the DAC may provide output current to the amplifier via the force path, and the DAC may sense the input voltage of the amplifier via the sense path. Accordingly, distortion such as harmonic distortion and/or gain offset from parasitic impedances in the force and/or sense paths may be reduced or eliminated. Some embodiments relate to a DAC including a voltage reference generator configured to compensate for variations in impedances of the DAC, such as due to semiconductor process variation. Accordingly, distortion in the DAC output due to variations in the DAC impedances may be reduced or eliminated.

Abstract: Circuits and methods for converting digital input signals into the analog domain are described. Such circuits may perform the conversion in a segmented fashion. For example, a circuit may include a most significant bit (MSB) path and a least significant bit (LSB) path. The MSB path may include a first delta-sigma modulator having first and second outputs and a first digital-to-analog converter coupled to the first output of the first delta-sigma modulator. The LSB path comprises a second delta-sigma modulator comprising a loop filter and a quantizer. The quantizer may have an input coupled to the loop filter and to the digital filter. The LSB path may further include a second digital-to-analog converter coupled to an output of the quantizer. The circuit may further include a digital filter and/or a gain stage interposed between the MSB path and the LSB path.

Abstract: A comparator is described. The comparator may be used in several applications, including in digital-to-analog converters (ADC). The comparator may comprise a high-speed amplifier, a low-noise amplifier, a controller and a bi-stable circuit. The high-speed amplifier may be activated during a first period, for example when the comparator tends to exhibit a slow response. During this period, the comparator may sacrifice the noise performance. The low-noise amplifier may be activated during a second period, for example when the difference between the signals appearing as inputs to the comparator is small. The low-noise amplifier may have a gain that is large enough to limit decision errors. The bi-stable circuit, which may be implemented using a latch, may be configured to output a signal equal to one of the supply voltages, in response to receiving the input signal from one of the stages.

Abstract: Systems and methods for low-power single-wire communication are provided. In some embodiments, a method of operation of a transmitter to transmit a data word to a receiver using low-power single-wire communication includes receiving the data word to be transmitted to the receiver. The method also includes encoding the data word to be transmitted in a Pulsed Index Communication (PIC) format to produce a PIC data word and transmitting the PIC data word to the receiver. In this way, the transmitter may be able to transmit an increased amount of data while maintaining a simple communication protocol that uses low power and does not require a Clock-Data Recovery circuit.

Abstract: A comparator is described. The comparator may be used in several applications, including in digital-to-analog converters (ADC). The comparator may comprise a high-speed amplifier, a low-noise amplifier, a controller and a bi-stable circuit. The high-speed amplifier may be activated during a first period, for example when the comparator tends to exhibit a slow response. During this period, the comparator may sacrifice the noise performance. The low-noise amplifier may be activated during a second period, for example when the difference between the signals appearing as inputs to the comparator is small. The low-noise amplifier may have a gain that is large enough to limit decision errors. The bi-stable circuit, which may be implemented using a latch, may be configured to output a signal equal to one of the supply voltages, in response to receiving the input signal from one of the stages.

Abstract: A continuous-time sigma-delta analog-to-digital converter includes a plurality of integrator stages, in which one of the integrator stages includes a current buffer that drives an integrating capacitor. The analog-to-digital converter includes an outer feedback digital-to-analog converter and an inner digital-to-analog converter. The inner digital-to-analog converter is a current-mode digital-to-analog converter that converts the digital output signal to an analog current feedback signal, which is provided to an output of the integrator stage that includes the current buffer. Both the analog current feedback signal and an input signal provided to the current buffer are integrated by the integrating capacitor.

Abstract: A reconfigurable analog-to-digital (ADC) modulator structure that includes a plurality of ADC structures being coupled to each other through their respective noise quantization transfer functions. Each ADC structure receives as input an analog signal and each ADC structure outputting a plurality of first output signals. An adder module receives the first output signals and performs addition on the first output signals and generates a second output signal. A division module receives the second output signal and performs division on the second output signal by a predetermined factor.

Abstract: The invention relates to a cascaded scheme in which an RRC filter, a modified RRC filter or other digital filter is implemented at a relatively low data rate, such as twice the symbol or chip rate, or 2×. Interpolation filters are used to increase the data rate to a higher data rate, such as 8×. Decimation filters are used to reduce the data rate from a higher rate, such as 8×, to a lower rate, such as 2×. The coefficients of the digital filter may be adjusted to compensate for characteristics of other components across the entire filter chain. Most of the implementation complexity of the filter chain is consolidated into the relatively low rate (such as 2×) digital filter while interpolation or decimation filters can be implemented at very low cost. The compensation capability provided by the digital filter makes design of simple decimation or interpolation filters much easier.

Abstract: A multi-input-multi-output-system (MIMO) is provided that includes a first input signal and a second input signal. A plurality of analog-to-digital converter (ADC) cell structures receive as input a combination of the first input signal and the second input signal as well as a combination of quantization noise signals from the respective other ADC cell structures of the plurality of ADC cell structures. The ADC cell structures generate a plurality of first output signals and the noise quantization signals. A plurality of adder modules receive the first output signals and performing either addition or subtraction on a selected combination of the first output signals, the adder modules generate a plurality of second output signals. A plurality of division modules receive the second output signals and perform a division operation on the second output signals by a predetermined factor. The division modules generate a plurality of final output signals of the MIMO.

Abstract: A continuous-time sigma-delta analog-to-digital converter includes a plurality of integrator stages, in which one of the integrator stages includes a current buffer that drives an integrating capacitor. The analog-to-digital converter includes an outer feedback digital-to-analog converter and an inner digital-to-analog converter. The inner digital-to-analog converter is a current-mode digital-to-analog converter that converts the digital output signal to an analog current feedback signal, which is provided to an output of the integrator stage that includes the current buffer. Both the analog current feedback signal and an input signal provided to the current buffer are integrated by the integrating capacitor.

Abstract: A reconfigurable analog-to-digital (ADC) modulator structure that includes a plurality of ADC structures being coupled to each other through their respective noise quantization transfer functions. Each ADC structure receives as input an analog signal and each ADC structure outputting a plurality of first output signals. An adder module receives the first output signals and performs addition on the first output signals and generates a second output signal. A division module receives the second output signal and performs division on the second output signal by a predetermined factor.

Abstract: A multi-input-multi-output-system (MIMO) is provided that includes a first input signal and a second input signal. A plurality of analog-to-digital converter (ADC) cell structures receive as input a combination of the first input signal and the second input signal as well as a combination of quantization noise signals from the respective other ADC cell structures of the plurality of ADC cell structures. The ADC cell structures generate a plurality of first output signals and the noise quantization signals. A plurality of adder modules receive the first output signals and performing either addition or subtraction on a selected combination of the first output signals, the adder modules generate a plurality of second output signals. A plurality of division modules receive the second output signals and perform a division operation on the second output signals by a predetermined factor. The division modules generate a plurality of final output signals of the MIMO.

Abstract: This invention features a high voltage multiplexer element including a voltage to current converting input resistance connected to the input of the element, first and second MOSFET switches connected in series between the input resistance and the output of the multiplexer element, and a third MOS switch connected between the junction of the first and second MOSFET switches and a voltage equal to or less than the supply; the first MOSFET switch being drain engineered and having drain-source breakdown voltage higher than the supply.

Abstract: A method for determining a state of charge value for an electrical power cell comprises obtaining an indication of a charge level of the electrical power cell, obtaining at least one indication of at least one operating condition for the electrical power cell, and determining an available charge indication value and a potential charge indication value based at least partly on the charge level indication and the at least one operating condition indication.

Abstract: An integrated circuit comprises a threshold generation circuitry for generating at least one differential voltage signal. The threshold generation circuitry comprises at least one common mode current generation circuit arranged to generate at least one common mode current signal, whereby said at least one common mode current signal is combined with at least one input current signal to produce a combined current signal comprising a combined signal common mode component. Conversion circuitry is arranged to receive the combined current signal and convert the combined current signal into the at least one differential voltage signal for use within the comparator circuit. The threshold generation circuitry further comprises feedback circuitry arranged to receive an indication of the combined signal common mode component, compare the received indication to a reference value, and regulate the at least one common mode current signal based at least partly on the comparison results.

Abstract: An integrated circuit comprises a threshold generation circuitry for generating at least one differential voltage signal. The threshold generation circuitry comprises at least one common mode current generation circuit arranged to generate at least one common mode current signal, whereby said at least one common mode current signal is combined with at least one input current signal to produce a combined current signal comprising a combined signal common mode component. Conversion circuitry is arranged to receive the combined current signal and convert the combined current signal into the at least one differential voltage signal for use within the comparator circuit. The threshold generation circuitry further comprises feedback circuitry arranged to receive an indication of the combined signal common mode component, compare the received indication to a reference value, and regulate the at least one common mode current signal based at least partly on the comparison results.

Abstract: A method for identifying multiple touch user interaction with a touchscreen device. The method includes receiving an indication that a touch has been detected on the touchscreen device, applying a first voltage across a first conductive layer of the touchscreen device and measuring first and second voltage signals at first and second electrical contacts of a second conductive layer of the touchscreen device, applying a second voltage across the second conductive layer of the touchscreen device and measuring third and fourth voltage signals at third and fourth electrical contacts of the first conductive layer of the touchscreen device, and interpreting the user interaction with the touchscreen device and identifying multiple touch gestures based at least partly on at least one of a difference between the first and second voltage signals, and a difference between the third and fourth voltage signals.