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.

The invention introduces a method for verifying memory interface, performed by a processing unit, to include: driving a physical layer of a memory interface to pull-high or pull-low a signal voltage on each Input-Output (IO) pin thereof to a preset level according to a setting; obtaining a verification result corresponding to each IO pin from the memory interface; and storing each verification result in a static random access memory (SRAM), thereby enabling a testing host to obtain each verification result of the SRAM through a test interface. The testing host may examine each verification result to know whether any unexpected error has occurred in signals on the IO pins of the memory interface.

The present disclosure relates to a memory test system and a memory test method. The memory test system comprises: a plurality of test devices, a host computer, and driving modules. Each of the test devices is provided with a test interface used for connecting a memory to be tested. The host computer is respectively connected to the plurality of test devices and configured to control the test devices to test the memory to be tested. The driving modules are connected to the test devices and configured to output, to the test devices, driving signals used for driving the test devices to perform data interaction with the host computer.

A memory storage device that performs real-time monitoring is provided. The memory storage device comprises a memory controller, and a status indicating module/circuit, wherein the memory controller is configured to perform a first a second initialization operation, the first and second initialization operations performed in response to turning-on of the memory storage device, to generate a first status parameter regarding a status of the memory storage device in which the first initialization operation is performed, and to generate a second status parameter regarding the status of the memory storage device in which a second initialization operation is performed. The status indicating circuit includes a first transistor configured to operate on the basis of the first status parameter, a first resistor connected to the first transistor, a second transistor configured to operate on the basis of the second status parameter, and a second resistor connected to the second transistor.

A testing apparatus comprises a tester comprising a plurality of racks, wherein each rack comprises a plurality of slots, wherein each slot comprises: (a) an interface board affixed in a slot of a rack, wherein the interface board comprises test circuitry and a plurality of sockets, each socket operable to receive a device under test (DUT); and (b) a carrier comprising an array of DUTs, wherein the carrier is operable to displace into the slot of the rack; and (c) an array of POP memory devices, wherein each POP memory device is disposed adjacent to a respective DUT in the array of DUTs. Further, the testing apparatus comprises a pick-and-place mechanism for loading the array of DUTs into the carrier and an elevator for transporting the carrier to the slot of the rack.

A testing device comprises test interface circuitry, probe circuitry, and initiate state machine circuitry. The test interface circuitry is configured to receive NAND signaling when operatively coupled to a M-NAND memory device under test and to operate the M-NAND memory device under test to receive memory access requests and to provide status or data at the same rate it receives memory access requests. The probe circuitry is configured to detect memory operations of the memory device under test. The finite state machine circuitry is operatively coupled to the probe circuitry and is configured to advance through multiple circuit states according to the detected memory operations; and log memory events of the memory device under test according to the circuit states.

A test board for testing a memory signal includes a first surface and a second surface. The first surface of the test board comprises a convex region and a non-convex region. The convex region is provided with a first connection area connectable to a main board, and a level at which the convex region is located is higher than a level at which the non-convex region is located by a preset value. The second surface of the test board includes a test area and a second connection area connectable to a memory chip. The test board is provided with a first connection harness for connecting the test area to the first connection area and a second connection harness for connecting the test area to the second connection area, to enable the memory signal of the memory chip to be tested based on the test area.

A semiconductor device may include: first to n-th through-electrodes; first to n-th through-electrode driving circuits suitable for charging the first to n-th through-electrodes to a first voltage level, or discharging the first to n-th through-electrodes to a second voltage level; and first to n-th error detection circuits, each suitable for storing the first voltage level or the second voltage level of a corresponding through-electrode of the first to n-th through-electrodes as a down-detection signal and an up-detection signal, and outputting a corresponding error detection signal of first to n-th error detection signals by sequentially masking the down-detection signal and the up-detection signal.

Methods and apparatus relating to a resistive network splitter for enhanced probing solutions are described. In one embodiment, an interposer interface is coupled between a first component and a second component to allow a probe to capture one or more waveforms to be exchanged between the first component and the second component. A resistive network splitter couples the interposer interface to the probe and the second component and the resistive network comprises a plurality of resistors. Other embodiments are also claimed and disclosed.

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.