A tool is presented herein capable of performing several electrical measurements and generating several electrical outputs. The tool can be configured to perform measurements and provide outputs most commonly utilized when developing and diagnosing failures of a hardware platform based around a microcontroller. The tool can have a form factor and a header configuration compatible for mating with an external microcontroller or minicomputer developer board such as Arduino, UDOO, Raspberry Pi, TI LaunchPad, STM Nucleo, BeagleBone, etc.

A method embodiment includes combining a control signal of a voltage regulator circuit of an apparatus with pseudo-random noise, and using the control signal to provide an output voltage signal as attenuated by a power supply rejection ratio (PSRR) of an analog mixed-signal (AMS) circuit of the apparatus. The method further includes self-testing the AMS circuit by cross-correlating a signal indicative of the output voltage signal from the AMS circuit with the pseudo-random noise and, in response, assessing the results of the cross-correlation relative to a known threshold indicative of a performance level of the AMS circuit.

A method embodiment includes combining a control signal of a voltage regulator circuit of an apparatus with pseudo-random noise, and using the control signal to provide an output voltage signal as attenuated by a power supply rejection ratio (PSRR) of an analog mixed-signal (AMS) circuit of the apparatus. The method further includes self-testing the AMS circuit by cross-correlating a signal indicative of the output voltage signal from the AMS circuit with the pseudo-random noise and, in response, assessing the results of the cross-correlation relative to a known threshold indicative of a performance level of the AMS circuit.

A stimulus/response controller within a magnetic electrical test apparatus is configured for generating and transmitting stimulus waveforms to a high-speed DAC for application to a MTJ DUT. The response signal from the MTJ DUT is applied to an ADC that digitizes and transfers the response signal to the stimulus/response controller. The stimulus/response controller has a configurable function circuit that is selectively configured for performing evaluation and analysis of the digitized stimulus and response signals. The configurable functions are structured for performing any evaluation and analysis function for determining the characteristics of the MTJ DUT(s). Examples of the evaluation and analysis operations include averaging the stimulus and/or response signals, determining the differential resistance, the degradation times, failure counts, or the bit error rate of the MTJ DUT(s). The evaluations and analysis of the MTJ DUT are then available for transfer to a tester controller within the magnetic electrical test apparatus.

A stimulus/response controller within a magnetic electrical test apparatus is configured for generating and transmitting stimulus waveforms to a high-speed DAC for application to a MTJ DUT. The response signal from the MTJ DUT is applied to an ADC that digitizes and transfers the response signal to the stimulus/response controller. The stimulus/response controller has a configurable function circuit that is selectively configured for performing evaluation and analysis of the digitized stimulus and response signals. The configurable functions are structured for performing any evaluation and analysis function for determining the characteristics of the MTJ DUT(s). Examples of the evaluation and analysis operations include averaging the stimulus and/or response signals, determining the differential resistance, the degradation times, failure counts, or the bit error rate of the MTJ DUT(s). The evaluations and analysis of the MTJ DUT are then available for transfer to a tester controller within the magnetic electrical test apparatus.

A mixed-signal integrated circuit includes an analog circuit comprising at least one digital block embedded in the analog circuit, the at least one digital block comprising a plurality of functional bits and a plurality of configuration bits, the plurality of functional bits providing for a functionality of the analog circuit according to a designed functionality and the plurality of configuration bits being usable for configuring a plurality of operational modes of the analog circuit; and a digital circuit comprising a scan chain configured to scan at least part of the functional bits of the digital block embedded in the analog circuit with respect to the designed functionality, wherein the scan chain is further configured to set at least part of the configuration bits of the digital block embedded in the analog circuit according to a selected operational mode of the plurality of operational modes of the analog circuit.

A mixed-signal integrated circuit includes an analog circuit comprising at least one digital block embedded in the analog circuit, the at least one digital block comprising a plurality of functional bits and a plurality of configuration bits, the plurality of functional bits providing for a functionality of the analog circuit according to a designed functionality and the plurality of configuration bits being usable for configuring a plurality of operational modes of the analog circuit; and a digital circuit comprising a scan chain configured to scan at least part of the functional bits of the digital block embedded in the analog circuit with respect to the designed functionality, wherein the scan chain is further configured to set at least part of the configuration bits of the digital block embedded in the analog circuit according to a selected operational mode of the plurality of operational modes of the analog circuit.

A circuit includes: first analog-to-digital converters (ADCs) configured to be coupled to respective ones of first sensors; a first multiplexer (MUX) coupled to output terminals of the first ADCs; a second MUX configured to be coupled to second sensors which are redundant sensors for the first sensors; a second ADC coupled to an output terminal of the second MUX, the first MUX and the second MUX being controlled by a selection signal; a first checker circuit configured to compare a first data at an output terminal of the first MUX with a second data at an output terminal of the second ADC; and a plurality of switches coupled between respective ones of the input terminals of the second MUX and a reference voltage node.

A circuit includes: first analog-to-digital converters (ADCs) configured to be coupled to respective ones of first sensors; a first multiplexer (MUX) coupled to output terminals of the first ADCs; a second MUX configured to be coupled to second sensors which are redundant sensors for the first sensors; a second ADC coupled to an output terminal of the second MUX, the first MUX and the second MUX being controlled by a selection signal; a first checker circuit configured to compare a first data at an output terminal of the first MUX with a second data at an output terminal of the second ADC; and a plurality of switches coupled between respective ones of the input terminals of the second MUX and a reference voltage node.

In an example implementation, an integrated circuit (IC) includes: a plurality of transistors disposed in a plurality of locations on a die of the IC; conductors coupled to terminals of each of the plurality of transistors; a digital-to-analog converter (DAC), coupled to the conductors, to drive voltage signals to the plurality of transistors in response to a digital input; and an analog-to-digital converter (ADC), coupled to at least a portion of the conductors, to generate samples in response to current signals induced in the plurality of transistors in response to the voltage signals, the samples being indicative of at least one electrostatic characteristic for the plurality of transistors.