A memory device includes a memory cell array including normal memory cells and redundant memory cells; first page buffers connected to the normal memory cells through first bit lines including a first bit line group and a second bit line group and arranged in a first area corresponding to the first bit lines in a line in a first direction; and second page buffers connected to the redundant memory cells through second bit lines including a third bit line group and a fourth bit line group and arranged in a second area corresponding to the second bit lines in a line in the first direction, wherein, when at least one normal memory cell connected to the first bit line group is determined as a defective cell, normal memory cells connected to the first bit line group are replaced with redundant memory cells connected to the third bit line group.

Technology is disclosed for a fast ECC engine for a mixed read of MRAM cells. A codeword read from MRAM cells using a referenced read is decoded using a first ECC mode. If decoding passes, results are provided to a host. If decoding fails, a self-referenced read (SRR) is performed. The data read using the SRR is decoded with a second ECC mode that is capable of correcting a greater number of bits than the first ECC mode. The second ECC mode may have a higher mis-correction rate than the first ECC mode (for a given raw bit error rate (RBER)). However, the RBER may be lower when using the second ECC mode. Therefore, the first and second ECC modes may result in about the same probability of an undetectable error (or mis-correction).

Methods, systems, and devices for word line capacitance balancing are described. A memory device may include a set of memory tiles, where one or more memory tiles may be located at a boundary of the set. Each boundary memory tile may have a word line coupled with a driver and a subarray of memory cells, and may also include a load balancing component (e.g., a capacitive component) coupled with the driver. In some examples, the load balancing component may be coupled with an output line of the driver (such as a word line) or an input of the driver (such as a line providing a source signal). The load balancing component may adapt a load output from the driver to the subarray of memory cells such that the load of the memory tile at the boundary may be similar to the load of other memory tiles not at the boundary.

A processor coupled to a NAND memory device comprising an n by m array of dies having n channels performs error recovery message scheduling and read error recovery on the dies by receiving indications of read errors responsive to attempted execution of a read command on a destination die and creates an error recovery message or instruction in response to the indication. The processor determines the destination die of the error recovery message and sends the error recovery message to a die queue based on the determined destination die. The n×m die queues can each be further divided into p priority queues, and error recovery messages are sent to the appropriate die priority queue based on a priority associated with the error recovery message. The processor fetches error recovery messages from a head of each die priority queue and performs read error recovery at the destination die.

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.

The present disclosure provides memory devices and methods for using shared latch elements thereof. A memory device includes a substrate, an interposer disposed over the substrate, and a logic die and stacked memory dies disposed over the interposer. In the logic die, the test generation module performs a memory test operation for the memory device. The functional elements stores functional data in latch elements during a functional mode of the memory device. The repair analysis module determines memory test/repair data based on the memory test operation. The memory test/repair data comprises memory addresses of faulty memory storage locations of the memory device that are identified during the memory test operation. The repair analysis module configures the latch elements into a scan chain, accesses the memory test/repair data during the test mode of the memory device, and repairs the memory device using the memory test/repair data.

An integrated circuit (IC) includes a non-volatile memory and boot circuitry. The boot circuitry is configured to boot the IC, including reading from the non-volatile memory one or more values indicative of whether production testing of the IC was completed successfully, and initiating a responsive action if the one or more values indicate that the production testing was not completed successfully.

A read signal generator generates read signals to control read operations of a memory array. The read signal generator can be selectively controlled to generate an oscillating signal having a period that corresponds to a feature one of the read signals. The oscillating signal is passed to a frequency divider that divides the oscillating signal and provides the divided oscillating signal to an output pad. The frequency of the oscillating signal can be measured at the output pad. The frequency of the oscillating signal, and the duration of the read signal feature can be calculated from the frequency of the oscillating signal. The read signal feature can then be adjusted if needed.

A system includes a memory cell array including multi-level cells, an input data scramble circuit configured to receive input data and match lower error tolerant bits with higher error tolerant bits to provide matched bit sets, wherein each of the matched bit sets includes at least one lower error tolerant bit and at least one higher error tolerant bit, and a write driver configured to receive the matched bit sets and store each of the matched bit sets into one memory cell of the multi-level cells.

Wafer-level testing of multiple adjacent semiconductor die of a semiconductor wafer in parallel using built-in self-test circuitry for a memory (mBIST) and scribe lines that connect certain terminals of a semiconductor die to terminals of an adjacent semiconductor die. During the wafer-level testing, probe needles of a test setup connect to a single one of the multiple adjacent semiconductor die, and mBIST commands are passed from the single one of the multiple adjacent semiconductor die to one or more adjacent semiconductor die. In some examples, the scribe lines connect mBIST circuit terminals of one semiconductor die to mBIST circuit terminals of an adjacent semiconductor die. In some examples, the scribe lines connect I/O terminals of one semiconductor die to I/O terminals of an adjacent semiconductor die. The scribe lines may cross scribe regions of the wafer to connect the respective terminals of the adjacent semiconductor die.