A method for testing semiconductor devices is disclosed, which includes: obtaining a result measured on a semiconductor device in one of a set of tests; comparing the result with a maximum value determined among respective results that were previously measured in one or more of the set of tests and a minimum value determined among respective results that were previously measured in one or more of the set of tests; determining, based on the comparison between the first result and the maximum and minimum values, whether to update the maximum and minimum values to calculate a delta value; comparing the delta value with a noise threshold value; determining based on the comparison between the delta value and the noise threshold value, whether to update a value of a timer; determining that the value of the timer satisfies a timer threshold; and determining that the semiconductor device incurs noise.

Circuits and methods for compensating mismatches in sense amplifiers are disclosed. In one example, a circuit is disclosed. The circuit includes: a first branch, a second branch, a first plurality of trimming transistors and a second plurality of trimming transistors. The first branch comprises a first transistor, a second transistor, and a first node coupled between the first transistor and the second transistor. The second branch comprises a third transistor, a fourth transistor, and a second node coupled between the third transistor and the fourth transistor. The first node is coupled to respective gates of the third transistor and the fourth transistor. The second node is coupled to respective gates of the first transistor and the second transistor. The first plurality of trimming transistors is coupled to the second transistor in parallel. The second plurality of trimming transistors is coupled to the fourth transistor in parallel.

Command/address (CA) pads of a wafer may be coupled with one or more logic circuits of the wafer to support transmission of a test signal between different memory dies of the wafer. A CA pad of a first memory die may be coupled with a repeater circuit in a scribe region of the wafer, and the repeater circuit may be coupled with a corresponding control circuit in the scribe region. These circuits may support repetition of a signal from a probe card to one or more other CA conductive paths of one or more other memory dies of the wafer. The repeater circuit may receive a test signal from the CA pad, which may be coupled with and receive the test signal from the probe card, and may transmit the test signal to another CA pad of another memory die based on a configuration of the control circuit.

Nonvolatile memory device includes a memory cell array and a control circuit. The memory cell array includes a plurality of memory blocks, the memory blocks including a plurality of memory cells coupled to word-lines respectively, the word-lines are stacked vertically on a substrate, and some memory cells of the plurality of memory cells are selected by sub-block unit smaller than one memory block. The control circuit divides sub-blocks of a first memory block into at least one bad sub-block and at least one normal sub-block based on error occurrence frequency of each of the sub-blocks, and applies different program/erase cycles to the at least one bad sub-block and the at least one normal sub-block based on a command and an address provided from external to the nonvolatile memory device. The at least one bad sub-block and the at least one normal sub-block are adjacent each other.

A memory device includes a plurality of input/output (I/O) nodes, a circuit, a latch, a memory, and control logic. The plurality of I/O nodes receive a predefined data pattern. The circuit adjusts a delay for each I/O node as the predefined data pattern is received. The latch latches the data received on each I/O node. The memory stores the latched data. The control logic compares the stored latched data to an expected data pattern and sets the delay for each I/O node based on the comparison.

Presented embodiments facilitate efficient and effective flexible implementation of different types of testing procedures in a test system. In one embodiment, a multiple-name-space testing system comprises a load board, testing electronics, and a namespace testing tracker. The load board is configured to couple with a plurality of devices under test (DUTs). The testing electronics are configured to test the plurality of DUTs, wherein the testing electronics are coupled to the load board. The controller is configured to direct testing of multiple-name-spaces across the plurality of DUTs at least in part in parallel. The controller can be coupled to the testing electronics. The namespace testing tracker is configured to track testing of the plurality of DUTs, including the testing of the multiple-name-spaces across the plurality of DUTs at least in part in parallel. In one embodiment, the DUTs are NVMe SSD devices.

A memory module may include: a battery; a plurality of devices including a first memory, a second memory, and a controller; and a power management integrated circuit configured to adjust a level of a battery power, received from the battery, and configured to supply a power supply voltage to each of the plurality of devices.

Some examples relate to a method. In this method, a metal isolation test circuit, which is disposed on a semiconductor substrate, is received. The metal isolation test circuit includes a plurality of transistors and an interconnect structure coupled to the plurality of transistors. The interconnect structure includes a plurality of pins. A first voltage bias is applied across first and second pins of the plurality of pins, and a first leakage current is measured while the first voltage bias is applied. A process or a design rule by which the metal isolation test circuit is made is characterized based on the first leakage current.

According to a certain embodiment, the semiconductor integrated circuit includes a plurality of memories and a first control circuit configured to control the plurality of memories. The first control circuit includes a first state transition circuit configured to execute at least one of write control and read control during an operation of the plurality of memories; and a second state transition circuit connected to the first state transition circuit, the second state transition circuit capable of causing the first state transition circuit to sequentially execute tests of the plurality of memories.

Techniques for refreshing memory cells of a stack of random-access memory are provided. In an example, a method can include exchanging data between a host processor and a buffer die at a first data speed, exchanging data between the buffer die and one or more DRAM dies at a second speed, slower than the first speed, and controlling refresh of the one or more DRAM dies via a controller of the buffer die.