Disclosed herein is an apparatus that includes a first circuit configured to measure a first time period from a first active edge of one of plurality of internal signals to a second active edge of one of the plurality of internal signals, and a second circuit configured to compare the first time period with a second time period to generate an alert signal.

An embodiment of a method for automated test pattern generation (ATPG), a system for ATPG, and a memory configured for ATPG. For example, an embodiment of a memory includes a first test memory cell, a data-storage memory cell, and a test circuit configured to enable the test cell and to disable the data-storage cell during a test mode.

An embodiment of a method for automated test pattern generation (ATPG), a system for ATPG, and a memory configured for ATPG. For example, an embodiment of a memory includes a first test memory cell, a data-storage memory cell, and a test circuit configured to enable the test cell and to disable the data-storage cell during a test mode.

Semiconductor memory testing devices and methods are disclosed. In one respect, a device is disclosed that includes a first memory cell array having a first bit-line and a plurality of first memory cells connected to the first bit-line; a second memory cell array having a second bit-line and a plurality of second memory cells connected to the second bit-line, the number of second memory cells being smaller than that of the first memory cells; a sense amplifier connected to the first bit-line and a first end of the second bit-line; a word decoder configured to operate the second memory cells responsive to a first test signal; and a transistor coupled to a second end of the second bit-line and operated by a second test signal.

An operating method of a memory system includes storing normal data to a first storage area of a non-volatile memory in a first program mode among multiple program modes defined according to a number of bits stored in each memory cell; storing dummy data in the first storage area in at least one of the multiple program modes including the first program mode; and copying the normal data from the first storage area to a second storage area of the non-volatile memory based on dummy data stored in the first program mode.

The present disclosure relates to a method for improving the safety of the reading phase of a non-volatile memory device including at least an array of memory cells and with associated decoding and sensing circuitry and a memory controller, the method comprising: storing in a dummy row of said memory block at least a known pattern; performing some reading cycles changing the read trimming parameters up to the moment wherein said known value is read correctly; adopting the trimming parameters of the correct reading for the subsequent reading phases.

The disclosure further relates to a memory device structured for implementing the above method.

The present disclosure relates to a method for improving the safety of the reading phase of a non-volatile memory device including at least an array of memory cells and with associated decoding and sensing circuitry and a memory controller, the method comprising: storing in a dummy row of said memory block at least a known pattern; performing some reading cycles changing the read trimming parameters up to the moment wherein said known value is read correctly; adopting the trimming parameters of the correct reading for the subsequent reading phases.

The disclosure further relates to a memory device structured for implementing the above method.

According to one embodiment, a semiconductor memory device includes: a first delay circuit configured to delay a first signal and provide a variable delay time; a first select circuit configured to select a second signal or a third signal based on the first signal delayed by the first delay circuit; a first output buffer configured to output a fourth signal based on a signal selected by the first select circuit; a first output pad configured to externally output the fourth signal; and a counter configured to count a number of times the fourth signal is output.

Methods, systems, and devices for modifiable repair solutions for a memory array are described to support storing repair information for a memory array within the memory array itself. A memory device may include the memory array and an on-die microprocessor, where the microprocessor may retrieve the repair information from the memory array and write the repair information to repair circuitry used for identifying defective memory addresses. The microprocessor may support techniques for identifying additional defects and updating the repair information during operation of the memory array. For example, the microprocessor may identify additional defects based on errors associated with one or more memory cells of the memory array or based on testing performed on one or more memory cells of the memory array. In some cases, a host device may identify additional defects and may notify the microprocessor of the additional defects.

Disclosed are systems and methods involving memory-side write training to improve data valid window. In one implementation, a method for performing memory-side write training may comprise delaying a rising edge or a falling edge of a first data signal, delaying a rising edge or a falling edge of a second data signal, and aligning the two adjusted signals to reduce a window of time that the data signals are not valid and thereby improve or optimize the data valid window (DVW) of a memory array. According to implementations herein, various edges of data signals and clock signals may be adjusted or delayed via dedicated trim cells or circuitry present in the data paths located on the memory side of a system.