Abstract: A system and method are provided for interfacing JESD204-to-PCIe communications. The method transceives JESD204 link layer messages with a JESD204 link layer. The method converts between JESD204 link layer messages and PCIe scrambled messages. The method converts between PCIe scrambled messages and PCIe encoded messages. The PCIe encoded messages are transceived at a JESD clock rate. The PCIe encoded messages transceived at the JESD clock rate are buffered and PCIe encoded messages are then transceived at a PCIe clock rate. The PCIe encoded messages at the PCIe clock rate are transceived with a PCIe physical layer. That is, PCIe encoded messages are either transmitted to the PCIe physical layer at the PCIe clock rate (the transmission path), or received from the PCIe physical layer (at the PCIe clock rate) and buffered (the receive path). The system and method also enable conventional JESD link layer-to-JESD physical layer communications.

Abstract: A transformer based voltage controlled oscillator (VCO) is provided with a primary resonant circuit having a first inductor connected in parallel with a variable first capacitance circuit. A secondary resonant circuit is formed from a second inductor connected in parallel with a variable second capacitance circuit, and also includes a mode control circuit. The mode control circuit controls the direction of current flow through the secondary resonant circuit inductor. The first and second inductors are inductively mutually coupled in either an even mode or an odd mode in response to the mode control circuit. The VCO supplies a first resonant frequency in response to even mode operation, or a second resonant frequency, greater than the first resonant frequency, responsive to odd mode operation. The VCO may include a first electrically tunable varactor shunted across the first capacitance circuit and a second electrically tunable varactor shunted across the second capacitance circuit.

Abstract: A phase accumulation digital-to-analog converter (DAC) is provided. A digital-to-time converter (DTC), including a reference clock chain with N number of series connected delay elements, accepts a clock signal with a leading clock edge and supplies a set signal representing a first delay of the leading clock edge. A data clock chain including N number of series connected accumulators, accepts the clock signal with the leading clock edge, accepts a binary coded digital word, and supplies a reset signal representing a second delay of the leading clock edge, responsive to the digital word. A phase-to-time logic (PTL) receives the set and reset signals and supplies a DTC output signal representing the difference in delay between the set and reset signals. A time-to-voltage converter (TVC) charges a load capacitor every clock period in response to the DTC output signal to supply an analog output signal.

Abstract: A multi-zone digital-to-analog device is provided with a digital-to-analog (D/A) stage having an input to accept a digital input signal with a data bandwidth of M Hertz (Hz), a clock input to accept a clock signal with a clock frequency of P Hz, and an output to supply an analog value having a bandwidth of M Hz. An upsampling stage has an input to accept the analog value and a clock input to accept the clock signal. The upsampling stage has a device bandwidth of L Hz to supply an analog output signal with a full power bandwidth of K Hz, where (P/2)=M and M<K<L. The upsampling stage supplies analog output signal images in a plurality of Nyquist zones. In one aspect, the D/A stage supplies N deinterleaved analog values having a combined bandwidth of M Hz, where N×(P/2)=M.

Abstract: A system and method are provided for calibrating an interleaved digital-to-analog converter (DAC). Sets of sub-DACs are enabled, and by creating a high frequency fundamental signal, spurs can be driven down sufficiently low in frequency to be sampled and digitally converted. By minimizing the power of these digital signals, the duty cycles of the different clock phases are calibrated. Then, sets of sub-DACs are enabled and high pass filtered, so that the spurs can be downconverted using corresponding phases of the clock, to a frequency low enough to sampled and digitally converted. The power of the digital signals is minimized as a first step in phase calibration. As a final step, all the sub-DACs are enabled, the high pass filter removed, and a high frequency fundamental signal is downconverted using at least two clock phases, so that the phase difference can be measured and corrected.

Abstract: Disclosed herein is circuitry that extends the charge-steering (CS) logic library with a 2:1 CS-multiplexor (MUX) cell that can be used in a tree fashion to compose a 2N:1 CS-MUX. Also presented is the integration of 2N:1 CS-MUX with conventional CMOS signals at a parallel input, and a current-mode driver at the serialized output. Also presented are a non-return-to-zero (NRZ) to RZ serializing transmitter, a charge-steering multiplexor (CSM) pre-driver, and a CSM transmitter.

Abstract: Devices and methods are presented for supplying logic gate signals with a data-independent delay. The method provides a logic gate comprising a pull-up network connected to a pull-down network. The method supplies binary level digital data input signals to the pull-up network and pull-down network, which may be either single-ended or complementary. The pull-up network and pull-down network regulate current through the logic gate with a delay and impedance independent of the data signals. As a result, the logic gate supplies binary level digital logic output signals in response to the data input signals, with a uniform delay. For example, the logic gates may be one of the following: NOR gate, NAND gate, AND gate, or OR gate.

Abstract: Devices and methods are presented for supplying logic gate signals with a data-independent delay. The method provides a logic gate comprising a pull-up network connected to a pull-down network. The method supplies binary level digital data input signals to the pull-up network and pull-down network, which may be either single-ended or complementary. The pull-up network and pull-down network regulate current through the logic gate with a delay and impedance independent of the data signals. As a result, the logic gate supplies binary level digital logic output signals in response to the data input signals, with a uniform delay. For example, the logic gates may be one of the following: NOR gate, NAND gate, AND gate, or OR gate.

Abstract: A sample-and-hold circuit is presented that is current driven at the input and current sensed at the output, using two capacitors—one at the input to the ground and second past a pair of complementary CMOS switches at the output to the ground. These capacitors in connection with an input current drive form a highpass noise transfer function that substantially reduces the 1/f noise of the switches and then rolls the transfer function off, further reducing the noise. The overall noise level is significantly lower as compared to a conventional voltage-driven and voltage-sensed sample-and-hold circuit that has a lowpass transfer function which, after integration, demonstrates a noise limit of kT/C. Depending on the circuit parameters the present sample-and-hold circuit shows an integrated noise improvement of between 5 and 10 dB over kT/C limit.

Abstract: A multi-zone analog-to-digital converter (ADC) is provided that includes a track-and-hold (T/H) stage having a bandwidth of L Hertz (Hz) to accept an analog input signal, a clock input to accept a clock signal with a clock frequency of P Hz, and N deinterleaved signal outputs with a combined bandwidth of M Hz. N×(P/2)=M, L>Q×M, and Q is an integer >1. The T/H stage is able to sample an analog input signal in the Qth Nyquist Zone, where Q is an integer. A quantizer stage has N interleaved signal inputs connected to corresponding T/H stage signal outputs, a clock input to accept the clock signal, and an output to supply a digital output signal having a bandwidth of M Hz. A packaging interface typically connects the T/H stage to the quantizer stage, and has a bandwidth less than the clock frequency.

Abstract: A multi-zone digital-to-analog device is provided with a digital-to-analog (D/A) stage having an input to accept a digital input signal with a data bandwidth of M Hertz (Hz), a clock input to accept a clock signal with a clock frequency of P Hz, and an output to supply an analog value having a bandwidth of M Hz. An upsampling stage has an input to accept the analog value and a clock input to accept the clock signal. The upsampling stage has a device bandwidth of L Hz to supply an analog output signal with a full power bandwidth of K Hz, where (P/2)=M and M<K<L. The upsampling stage supplies analog output signal images in a plurality of Nyquist zones. In one aspect, the D/A stage supplies N deinterleaved analog values having a combined bandwidth of M Hz, where N×(P/2)=M.

Abstract: A system and method are provided for converting voltage-to-time-to-digital signals. The method periodically samples a continuous analog input and discharges the sampled analog input at a predetermined rate to supply a continuous analog ramp signal. The ramp signal is converted into an n-bit coded digital word representing the q most significant bits (MSBs) of a k-bit binary word, where q is an integer greater than 0, n is an integer greater than 1, and k is an integer greater than q. At least one bit of the coded digital word is supplied at a time representing the p least significant bits (LSBs) of the k-bit binary word. The coded digital word is converted into a single-bit pulse signal containing timing information representing the p LSBs of the k-bit binary word at an output, and the timing information is converted into the p LSBs of the k-bit binary word.

Abstract: A system and method are provided for calibrating timing mismatch in an n-path time interleaved analog-to-digital converter (ADC). The method digitizes an analog signal with an n-path interleaved ADC, creating an interleaved ADC signal. In a first process, the phase of the interleaved ADC signal is rotated by 90 degrees, creating a rotated signal. This rotation may be accomplished using a finite impulse response (FIR) filter with taps at {0.5, 0, ?0.5}, enabled as a derivative filter, or as a Hilbert transformation. In a parallel second process, the interleaved ADC signal is delayed, creating a delayed signal. The rotated signal is multiplied by the delayed signal to create a timing error signal. Using the timing error signal, timing errors are accumulated for the ADC signal paths, and corrections are applied that minimize timing errors in each of the n ADC signal paths.

Abstract: A method is provided for supplying a customized data converter fabricated from a universal function die. The method initially fabricates a plurality of universal data converter dice. Each universal data converter die is capable of performing a first plurality of data conversion algorithms. After the dice are made, each universal data converter die is tested to verify the performance of the first plurality of data conversion algorithms. Subsequently, a request is received for a customized data converter capable of performing a first data conversion function, which is selected from among the first plurality of data conversion algorithms. The method then fabricates a customized data converter capable of performing the first data conversion function, using a tested universal data converter die. The unselected data converter functions are disabled (not enabled). A configuration interface may be used to enable the requested data conversion function.

Abstract: A current impulse (CI) method is provided for converting digital data signals to analog values. First, digital data bits are converted into current impulses. Then, the current impulses are converted into analog currents representing the digital data bits. More typically, the method accepts a k-bit digital word, and converts the k-bit digital word into (k) corresponding current impulses. In one aspect, the method accepts (n) consecutive k-bit digital words. Then, for each bit position in the k-bit digital word, (n) consecutive bits are sampled using (n) consecutive phases of an n-phase clock, creating (n) interleaved current impulses. The (n) interleaved current impulses are converted into an analog current representing the (n) consecutive k-bit digital words. Alternatively, (n) consecutive bits are sampled using (n) consecutive phases of an n-phase clock for each bit position in the k-bit digital word, creating (n) summed current impulses. A CI digital-to-analog converter is also provided.

Abstract: A Traveling Pulse Wave Quantization method is provided for converting a time sensitive signal to a digital value. A first stop signal is delayed by a first time delay, a first plurality of times, to create a delayed first stop signal. A clock signal is delayed by a second time delay, a first plurality of times, to create a delayed clock signal first period. Each second time delay is associated with a corresponding first time delay, and the second time delay is greater than the first time delay. When the delayed first stop signal occurs before the delayed clock signal first period, a count of the delays is stopped and converted into a digital or thermometer value. An accurate resampled value is provided regardless of the duration in delay between the first stop signal and a second stop signal that is accepted after the first stop signal.

Abstract: A method is provided for calibrating the mean frequency of a voltage controlled oscillator (VCO) based analog-to-digital converter (ADC). The method accepts a differential analog input signal comprising a positive signal and a negative signal. The positive signal is converted into a first frequency and the negative signal is converted into a second frequency. The first frequency is converted into a first digital value and the second frequency is converted into a second digital value. The first digital value is added to the second digital value to find a common mode value, and the common mode value is compared to a predetermined common mode value to find a first error. The first error is converted to a first bias modification of the differential analog input signal, and in response to the differential analog input first bias modification, the first error is minimized.

Abstract: A system and method are provided of performing background corrections for an interleaving analog-to-digital converter (ADC). An analog input signal s1(t) is accepted having a first frequency f1 and a bandwidth (BW). A clock at frequency fs creates n sample clocks with evenly spaced phases, each having a sample clock frequency of fs/2. A first tone signal s2(t) is generated at second frequency f2, outside BW. The analog input signal and the first tone signal are combined, creating a combination signal, which is sampled using the sample clocks, creating n digital sample signals per clock period 1/fs. The n digital sample signals are interleaved, creating an interleaved signal. Corrections are applied that minimize errors in the interleaved signal, to obtain a corrected digital output. Errors are determined at an alias frequency f3, associated with the second frequency f2, to obtain correction information for a rotating pair of digital sample signals.

Abstract: A charge canceling multiplying digital-to-analog converter (MDAC) is provided with a reference block having inputs to accept reference voltages each sample clock cycle. The MDAC includes a sampling block having inputs to accept differential analog input voltage signals each sample clock cycle. A differential amplifier has a negative input and positive input connected to the reference block and sampling block to receive differential amplifier input signals, and a positive output and a negative output to supply differential output voltage signals each amplify clock cycle. The sampling section includes a first pair of feedback capacitors connected between the differential amplifier negative input and positive output, and a second pair of feedback capacitors connected between the differential amplifier positive input and negative output each amplify clock cycle. A capacitor from the first pair of parallel feedback capacitors is swapped with a capacitor from the second pair prior to each sample clock cycle.

Abstract: A method is provided for supplying a customized data converter fabricated from a universal function die. The method initially fabricates a plurality of universal data converter dice. Each universal data converter die is capable of performing a first plurality of data conversion algorithms. After the dice are made, each universal data converter die is tested to verify the performance of the first plurality of data conversion algorithms. Subsequently, a request is received for a customized data converter capable of performing a first data conversion function, which is selected from among the first plurality of data conversion algorithms. The method then fabricates a customized data converter capable of performing the first data conversion function, using a tested universal data converter die. The unselected data converter functions are disabled (not enabled). A configuration interface may be used to enable the requested data conversion function.