A semiconductor circuit and an operating method for the same are provided. The method includes the following steps. A memory circuit is operated during a first timing to obtain a first memory state signal S1. The memory circuit is operated during a second timing after the first timing to obtain a second memory state signal S2. A difference between the first memory state signal S1 and the second memory state signal S2 is calculated to obtain a state difference signal SD. A calculating is performed to obtain an un-compensated output data signal OD relative with an input data signal ID and the second memory state signal S2. The state difference signal SD and the un-compensated output data signal OD are calculated to obtain a compensated output data signal OD′.

The present disclosure provides a method for detecting a memory and a device for detecting a memory. The memory includes first memory cells, second memory cells, bit lines, complementary bit lines, word lines, and a plurality of sense amplifiers, where each of the sense amplifiers is electrically coupled to a bit line and a complementary bit line; and the method includes: writing storage data into each of the first memory cells and each of the second memory cells; performing a read operation; obtaining a test result based on a difference between real data and the storage data; and obtaining a leakage position of the bit line and the word line or a leakage position the complementary bit line and the word line based on the test result.

Control logic in a memory device initiates a read operation on a memory array of the memory device and performs a calibration operation to detect a change in string resistance in the memory array. The control logic determines whether the change in string resistance is attributable to charge loss in the memory array, and responsive to determining that the change in string resistance is attributable to charge loss in the memory array, preforms the read operation using calibrated read voltage levels to read data from the memory array.

Systems and methods presented herein provide for mitigating errors in a storage device. In one embodiment, a storage system includes a storage device comprising a plurality of storage areas operable to store data, and a controller operable to evaluate operating conditions of the storage device, to perform a background scan on a first of the storage areas to characterize a read retention of the first storage area, and to adjust a read signal of the first storage area based on the characterized read retention and the operating conditions of the storage device.

A method of testing non-volatile memory cells formed on a die includes erasing the memory cells and performing a first read operation to determine a lowest read current RC1 for the memory cells and a first number N1 of the memory cells having the lowest read current RC1. A second read operation is performed to determine a second number N2 of the memory cells having a read current not exceeding a target read current RC2. The target read current RC2 is equal to the lowest read current RC1 plus a predetermined current value. The die is determined to be acceptable if the second number N2 is determined to exceed the first number N1 plus a predetermined number. The die is determined to be defective if the second number N2 is determined not to exceed the first number N1 plus the predetermined number.

A memory apparatus and method of operation are provided. The apparatus includes memory cells connected to one of a plurality of word lines and arranged in strings and configured to retain a threshold voltage corresponding to one of a plurality of memory states. A control circuit is coupled to the plurality of word lines and strings and is configured to erase the memory cells using a stripe erase operation in response to determining a cycle count is less than a predetermined cycle count maximum threshold. The control circuit is also configured to perform a dummy cycle operation in response to determining the cycle count is not less than the predetermined cycle count maximum threshold.

Technologies for performing a quick reliability scan include, for a particular block of a set of blocks of different block types, each block of the set of blocks including pages of memory of a physical memory device, identifying subset of the pages of the block. The block is scanned by scanning the subset of the plurality of pages of the block for a fold condition. A page of the subset of the plurality of pages is determined to have the fold condition. After the set of blocks has been scanned, the folding of the block that includes the page that has been determined to have the fold condition is requested.

A static random-access memory and a fault detection circuit thereof are provided. The fault detection circuit includes: a bit line coupling circuit, coupled between a first bit line and a second bit line, wherein the bit line coupling circuit is adapted to use a bit line with a lower potential between the first bit line and the second bit line to couple a bit line with a higher potential between the first bit line and the second bit line to a floating low potential in response to performing the data write operation on the memory cell in a test mode by the write circuit; and a fault determining circuit, adapted to, in response to the memory cell being at the test mode, obtain and compare write data and read data corresponding to the write data, to determine whether the SRAM has a Data Retention Fault based on a comparison result.

Methods, systems, and devices for skipping pages for weak wordlines of a memory device during pre-programming are described. A memory device may be configured to operate in a first mode involving skipping one or more pages (e.g., a lower page (LP)) associated with a set of wordlines. In some examples, a testing system may determine the set of wordlines (e.g., weak wordlines) for which to skip pages according to performance degradation for the wordlines in response to applying a threshold temperature to a test memory device. In the first mode, the memory device may store (e.g., pre-program) data in a subset of pages distinct from the skipped pages. The memory device may switch to a second mode in response to a trigger condition. In the second mode, the memory device may use each page associated with the wordlines and may refrain from skipping the one or more pages.

Embodiments of the present application provide a method and apparatus for determining a refresh counter of a DRAM. The method includes: writing data to a target memory cell connected with a target word line in the DRAM, and controlling the DRAM to perform refreshes starting from a preset word line according to a preset rule; determining, according to whether the data can be read accurately from the target memory cell after the refreshes, an intermediate refresh counter of refreshes on the target word line; and controlling, based on the intermediate refresh counter, the DRAM to perform refreshes starting from the target word line according to the preset rule, and determining the refresh counter of the DRAM according to whether the data can be read accurately from the target memory cell after the refreshes.