In some embodiments, a semiconductor wafer testing system is provided. The semiconductor wafer testing system includes a semiconductor wafer prober having one or more conductive probes, where the semiconductor wafer prober is configured to position the one or more conductive probes on an integrated chip (IC) that is disposed on a semiconductor wafer. The semiconductor wafer testing system also includes a ferromagnetic wafer chuck, where the ferromagnetic wafer chuck is configured to hold the semiconductor wafer while the wafer prober positions the one or more conductive probes on the IC. An upper magnet is disposed over the ferromagnetic wafer chuck, where the upper magnet is configured to generate an external magnetic field between the upper magnet and the ferromagnetic wafer chuck, and where the ferromagnetic wafer chuck amplifies the external magnetic field such that the external magnetic field passes through the IC with an amplified magnetic field strength.

A controller can be configured to enable a host to control media testing on a memory device. The interface between the host and the memory can be abstract, such that the host does not have direct control over the memory. Instead, the controller can provide translation between a host protocol, such as compute express link (CXL), and a memory protocol, such as a protocol to control a dual data rate (DDR) interface. The controller can enable media test capability discovery, configuration, and/or control for the host. The controller can enable media test result reporting from the memory to the host.

The present disclosure provides a method of testing a testing device with a ground noise. The method includes coupling a device under test in series between a source and a ground in an automatic test equipment, coupling a ground bounce generator in series between the device under test and the ground, coupling the testing device to the device under test, providing a current by the source through the device under test and the ground bounce generator, controlling the ground bounce generator to generate the ground noise, and collecting a performance result of the testing device in the automatic test equipment.

Methods, systems, and devices supporting an auto-power on mode for biased testing of a power management integrated circuit (PMIC) are described. A system may program a PMIC of a memory system to a specific mode. The mode may cause the PMIC to apply a bias to a memory device of the memory system upon receiving power and independent of a command to apply the bias to the memory device. The system may transmit power to the memory system while controlling one or more operating conditions (e.g., temperature, humidity) for a threshold time. The PMIC may apply a bias to the memory device during the threshold time based on the PMIC being programmed to the mode and the transmitted power. The system may identify a capability or defect of the memory device resulting from transmitting the power to the memory system while controlling the operating conditions for the threshold time.

In some embodiments, a semiconductor wafer testing system is provided. The semiconductor wafer testing system includes a semiconductor wafer prober having one or more conductive probes, where the semiconductor wafer prober is configured to position the one or more conductive probes on an integrated chip (IC) that is disposed on a semiconductor wafer. The semiconductor wafer testing system also includes a ferromagnetic wafer chuck, where the ferromagnetic wafer chuck is configured to hold the semiconductor wafer while the wafer prober positions the one or more conductive probes on the IC. An upper magnet is disposed over the ferromagnetic wafer chuck, where the upper magnet is configured to generate an external magnetic field between the upper magnet and the ferromagnetic wafer chuck, and where the ferromagnetic wafer chuck amplifies the external magnetic field such that the external magnetic field passes through the IC with an amplified magnetic field strength.

A memory device, and a method of operating the same, includes a plurality of pages, a peripheral circuit, and control logic. The peripheral circuit is configured to receive a command, an address, and data from an external controller to program a page selected from among the plurality of pages, and to generate internal input data depending on an input mode for the command, the address, and the data. The control logic is configured to determine whether internal input data is to be generated based on the data depending on the input mode and to control the peripheral circuit so that a program operation of programming the internal input data is performed.

A Magnetoresistive Random Access Memory (MRAM) device is tested using a high repetition test that detects one or more low-likelihood failures, such as a failure to properly switch between a high or low resistive state. A series of write and read operations are performed for a large number of test cycles at high frequency. A first tier measurement is used to determine if a switching failure occurred, e.g. by comparing the read signal to target level(s) after each operation. When a switching failure event is detected, a second tier measurement is used to measure and store switching performance parameters, for example, the value of the read signal, while the MRAM device is in a failure state. The high frequency testing may be paused during the second tier measurements. Additional performance parameters may be measured during the second tier measurements.

A method of testing a non-volatile memory (NVM) array includes heating the NVM array to a target temperature. While the NVM array is heated to the target temperature, a current distribution is obtained by measuring a plurality of currents of a subset of NVM cells of the NVM array, each NVM cell of the NVM array is programmed to one of a logically high state or a logically low state, and first and second pass/fail (P/F) tests on each NVM cell of the NVM array are performed. A bit error rate is calculated based on the current distribution and the first and second P/F tests.

A detection is made by a processing device allocated to a memory device test board of a distributed test platform that a memory sub-system has engaged with a memory device test resource of the memory device test board. A test is identified to be performed for a memory device of the memory sub-system. The test includes first instructions to be executed by a memory sub-system controller of the memory sub-system in performance of the test and second instructions to be executed by the processing device in performance of the test. The second instructions are to cause one or more test condition components of the memory device test resource to generate one or more test conditions to be applied to the memory device while the memory sub-system executes the first instructions. Responsive to a transmission of the first instructions to the memory sub-system controller, the second instructions are executed.

A memory chip unit includes a pad electrode including first and second portions, and a memory cell array. A prober includes a probe card and a movement mechanism. The probe card includes a probe electrode to be in contact with the pad electrode, and a memory controller electrically coupled to the probe electrode and executes reading and writing on the memory cell array. The movement mechanism executes a first operation that brings the probe electrode into contact with the first portion and does not bring the probe electrode into contact with the second portion, and a second operation that does not bring the probe electrode into contact with the first portion and brings the probe electrode into contact with the second portion.