In some examples, a device includes a control circuit configured to deliver driving signals to a switch. The device also includes a testing circuit configured to cause the control circuit to toggle the switch at a first instance and determine a parameter magnitude at the switch at a second instance after toggling the switch at the first instance by at least determining a voltage magnitude at the switch at the second instance. The testing circuit is also configured to cause the control circuit to toggle the switch after the second instance and determine a parameter magnitude at the switch at a third instance after toggling the switch after the second instance. The testing circuit is further configured to generate an output based on the determined parameter magnitudes at the switch at the second and third instances.

An apparatus for testing a device under test (DUT) is provided. The apparatus includes a power supply device and a data generating device. The power supply device is configured to provide a first voltage and a second voltage to the DUT. The data generating device is configured to provide first data to the DUT. The power supply device is configured to provide the first voltage to the DUT in a first time duration. The data generating device is configured to provide the first data to the DUT in the first time duration. The power supply device is configured to provide the second voltage to the DUT in a second time duration after the first time duration. The second voltage is different from the first voltage.

A margin testing device includes at least one interface structured to connect to a device under test (DUT) one or more controllers structured to create a set of test signals based on a sequence of pseudo random data and one or more pre-defined parameters, and an output structured to send the set of test signals to the DUT. Methods and a system for testing a DUT with the disclosed margin tester and other testing device are also described.

It is described a leakage compensation circuit for a measurement device which comprises a measurement circuit with a leaking device that is connected to a measurement path and causes a leakage current. The leakage compensation circuit comprises: i) a replica device of the leaking device, wherein the replica device is connected to a replica path, and wherein the replica device is configured to cause a replica leakage current that is essentially equal to the leakage current of the leaking device, ii) a voltage regulator which is connected to the measurement path and to the replica path, wherein the voltage regulator is configured to regulate the voltage in the replica path based on the voltage of the measurement path, and iii) a current mirror which is connected to the measurement path and to the replica path, wherein the current mirror is configured to mirror the replica leakage current of the replica device into the measurement path.

Circuits and methods for testing voltage monitor circuits are provided. In one embodiment, a method includes setting voltage monitor circuits to test mode; setting, a monitor reference in each voltage monitor circuit, to a respective targeted threshold voltage using a corresponding trim code; ramping, a voltage provided to a subset of voltage monitor circuits, from a first voltage to a second voltage using a test voltage supply, voltages between the first voltage and the second voltage corresponding with targeted threshold voltages of the subset of voltage monitor circuits; determining, for each voltage monitor circuit in the subset of voltage monitor circuits, a voltage value of the test voltage supply resulting in a change in a logic state at an output of a corresponding voltage monitor circuit.

A device binning and/or matching process includes measuring with a testing device currents and/or voltages of a device with respect to time, determining with the testing device binning and/or matching criteria for the device based on transfer data generated from the device currents and/or the voltages measured with respect to time, and outputting with the testing device the binning and/or matching criteria for the device. A system and power module are also disclosed.

Systems, devices, and methods are described herein for measuring an impedance of a DUT using an integrated impedance measurement device. A system includes a plurality of measurement circuits, a FFT processor, and a controller. The measurement circuits are coupled to the DUTs. Each measurement circuit is configured to generate a clock signal for a respective DUT, detect a voltage of the respective DUT, and generate first voltage related data using the clock signal and the voltage. The FFT processor is coupled to the measurement circuits. The FFT processor is configured to convert the first voltage related data into second voltage related data using a fast Fourier transform for each measurement circuit. The controller is coupled to the measurement circuits and the FFT processor. The controller is configured to calculate an impedance using the second voltage related data for each measurement circuit and output the impedance to each DUT.

Systems, devices, and methods are described herein for measuring an impedance of a DUT using an integrated impedance measurement device. A system includes a plurality of measurement circuits, a FFT processor, and a controller. The measurement circuits are coupled to the DUTs. Each measurement circuit is configured to generate a clock signal for a respective DUT, detect a voltage of the respective DUT, and generate first voltage related data using the clock signal and the voltage. The FFT processor is coupled to the measurement circuits. The FFT processor is configured to convert the first voltage related data into second voltage related data using a fast Fourier transform for each measurement circuit. The controller is coupled to the measurement circuits and the FFT processor. The controller is configured to calculate an impedance using the second voltage related data for each measurement circuit and output the impedance to each DUT.

Apparatuses for characterizing system channels and associated methods and systems are disclosed. In one embodiment, a tester is coupled to an adaptor configured to plug into a CPU socket of a system platform (e.g., a motherboard). The motherboard includes a memory socket that is connected to the CPU socket through system channels. The adaptor may include a connector configured to physically and electrically engage with the CPU socket, an interface configured to receive test signals from the tester, and circuitry configured to internally route the test signals to the connector. The adaptor, if plugged into the CPU socket, can facilitate the tester to directly assess signal transfer characteristics of the system channels. Accordingly, the tester can determine optimum operating parameters for the memory device in view of the system channel characteristics.

Apparatuses for characterizing system channels and associated methods and systems are disclosed. In one embodiment, a tester is coupled to an adaptor configured to plug into a CPU socket of a system platform (e.g., a motherboard). The motherboard includes a memory socket that is connected to the CPU socket through system channels. The adaptor may include a connector configured to physically and electrically engage with the CPU socket, an interface configured to receive test signals from the tester, and circuitry configured to internally route the test signals to the connector. The adaptor, if plugged into the CPU socket, can facilitate the tester to directly assess signal transfer characteristics of the system channels. Accordingly, the tester can determine optimum operating parameters for the memory device in view of the system channel characteristics.