Techniques are provided for storing a row address of a defective row of memory cells to a bank of non-volatile storage elements (e.g., fuses or anti-fuses). After a memory device has been packaged, one or more rows of memory cells may become defective. In order to repair (e.g., replace) the rows, a post-package repair (PPR) operation may occur to replace the defective row with a redundant row of the memory array. To replace the defective row with a redundant row, an address of the defective row may be stored (e.g., mapped) to an available bank of non-volatile storage elements that is associated with a redundant row. Based on the bank of non-volatile storage elements the address of the defective row, subsequent access operations may utilize the redundant row and not the defective row.

A memory device includes a system block for storing test information and includes a data block including memory cells connected to a plurality of low bank column lines and a plurality of high bank column lines. The memory device also includes a column repair controller configured to detect, based on the test information, a concurrent repair column line in which a low bank column line among the plurality of low bank column lines and a high bank column line the plurality of high bank column lines corresponding to the same column address are concurrent repaired.

Methods, systems, and devices for vertical transistor fuse latches are described. An apparatus may include a substrate and a memory array that is coupled with the substrate. The apparatus may also include a latch that is configured to store information from a fuse for the memory array. The latch may be at least partially within an additional substrate separate from and above the substrate. The latch may include a quantity of p-type vertical transistors and a quantity of n-type vertical transistors each at least partially disposed within the additional substrate above the substrate.

A memory device includes: a memory cell array; a first latch; a second latch; a first circuit; and a second circuit. The memory cell array includes first, second, and third columns associated with first, second, and third addresses, respectively. The first latch stores the first address and is associated with a fourth address. The second latch stores the second address and is associated with a fifth address. The fourth address and the fifth address are in an ascending order. The first circuit selects the third column in place of the first column based on the first address. The second circuit determines whether or not the first address and the second address are in an ascending order.

A method for operating a memory includes determining to perform an error correction operation; determining whether to perform an error correction operation; generating an internal address when the error correction operation is performed; reading data from memory cells that are selected based on the internal address and an error correction code corresponding to the data; performing an error correction operation on the data based on the error correction code to produce an error-corrected data; writing the error-corrected data and an error correction code corresponding to the error-corrected data into the memory cells; determining one or more regions among regions in the memory as a repair-requiring region based on an error detected when the error correction operation is performed; receiving a first command; backing up the data and the error correction code into a redundant region in response to the first command; and repairing the repair-requiring region with the redundant region.

Memory devices, systems including memory devices, and methods of operating memory devices are described, in which memory devices are configured to monitor word line characteristics. In one embodiment, the memory device includes a memory array including a word line (e.g., a local word line) and a word line driver coupled thereto. When the memory device activates the word line driver, the memory device may generate a diagnostic signal in response to the word line voltage reaching a threshold. Further, the memory device may generate a reference signal to compare the diagnostic signal with the reference signal. In some cases, the memory device may generate an alert signal based on comparing the diagnostic signal with the reference signal if the diagnostic signal indicates a symptom of degradation in the word line characteristics. The memory device may implement certain preventive and/or precautionary measures upon detecting the symptom.

Apparatus and methods for soft post package repair are disclosed. One such apparatus can include memory cells in a package, volatile memory configured to store defective address data responsive to entering a soft post-package repair mode, a match logic circuit and a decoder. The match logic circuit can generate a match signal indicating whether address data corresponding to an address to be accessed matches the defective address data stored in the volatile memory. The decoder can select a first group of the memory cells to be accessed instead of a second group of the memory cells responsive to the match signal indicating that the address data corresponding to the address to be accessed matches the defective address data stored in the volatile memory. The second group of the memory cells can correspond to a replacement address associated with other defective address data stored in non-volatile memory of the apparatus.

A method of failure mapping is provided. The method includes determining that a non-volatile memory block in the memory has a defect and generating a mask that indicates the non-volatile memory block and the defect. The method includes reading from the non-volatile memory block with application of the mask, wherein the reading and the application of the mask are performed by the non-volatile solid-state storage.

Memories, and their operation, might include a plurality of content addressable memory (CAM) cells each for storing a respective data value, a match signal generator configured to generate an indication whether each CAM cell of the plurality of CAM cells indicates a match between its respective data value and a respective received signal value, and a plurality of storage elements each for storing a respective data value, wherein each storage element of the plurality of storage elements corresponds to a respective CAM cell of the plurality of CAM cells in a one-to-one relationship, and wherein each storage element of the plurality of storage elements is responsive to the indication of the match signal generator to generate a data signal indicative of the respective data value of that storage element if a match of their corresponding CAM cells is indicated.

Methods, apparatus, systems and articles of manufacture are disclosed facilitate read-modify-write support in a coherent victim cache with parallel data paths. An example apparatus includes a random-access memory configured to be coupled to a central processing unit via a first interface and a second interface, the random-access memory configured to obtain a read request indicating a first address to read via a snoop interface, an address encoder coupled to the random-access memory, the address encoder to, when the random-access memory indicates a hit of the read request, generate a second address corresponding to a victim cache based on the first address, and a multiplexer coupled to the victim cache to transmit a response including data obtained from the second address of the victim cache.