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 includes pages of memory of a physical memory device. A subset of the pages of the block is identified. 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.

Methods and systems for testing memory systems are disclosed. A refresh rate for a test system including a number of memory devices may be controlled based on estimated power scenario of a memory system design. In response to performance of a number of refresh operations on the memory devices and based on the refresh rate, one or more conditions of the test system may be monitored to generate estimated performance data for the memory system design.

Embodiments presented herein are directed to testing and/or debugging a memory device of a memory module (e.g., a dual in-line memory module (DIMM)) without having to remove the DIMM from a corresponding computing device and without having to interrupt operation of the computing device. A particular memory device (e.g., DRAM) may be identified for testing and/or debugging based on a failure message. However, the failure message may not identify a specific location or hardware of the module that caused the failure. Embodiments presented herein provide techniques to obtain data for analysis to determine and/or deliver a cause of the failure while reducing or eliminating downtime of the computing device. Test modes to do so may include a synchronous test mode, an asynchronous test mode, and an analog compare mode. A test mode may be selected based on the failure or a signal/function of the DRAM to be tested or debugged.

A semiconductor apparatus may include a fuse cell array, an address generation circuit, a control circuit, and a command generation circuit. The fuse cell array may store a fail address. The address generation circuit may generate a copy address according to test information containing the fail address. The control circuit may control a repair operation including enabling a copy start signal according to the test information and storing the fail address in the fuse cell array according to a copy done signal. The command io generation circuit may generate an address and a plurality of commands for a data copy operation according to the copy start signal and enable the copy done signal when the data copy operation is completed.

A semiconductor apparatus may include a fuse cell array, an address generation circuit, a control circuit, and a command generation circuit. The fuse cell array may store a fail address. The address generation circuit may generate a copy address according to test information containing the fail address. The control circuit may control a repair operation including enabling a copy start signal according to the test information and storing the fail address in the fuse cell array according to a copy done signal. The command io generation circuit may generate an address and a plurality of commands for a data copy operation according to the copy start signal and enable the copy done signal when the data copy operation is completed.

The present disclosure includes systems, apparatuses, and methods for improving safety and correctness of data reading in flash memory devices associated with System-on-Chips. An example may include a plurality of sub-arrays, a plurality of memory blocks in each sub-array of the plurality of sub-arrays, a plurality of memory rows in each memory block of the plurality of memory blocks, and a plurality of extended pages in each memory row of the plurality of memory rows, wherein each extended page of the plurality of extended pages includes a group of data, an address, and an error correction code (ECC).

A memory device to program a group of memory cells to store multiple bits per memory cell. Each bit per memory cell in the group from a page. After determining a plurality of read voltages of the group of memory cells, the memory device can read the multiple pages of the group using the plurality of read voltages. For each respective page in the multiple pages, the memory device can determine a count of first memory cells in the respective page that have threshold voltages higher than a highest read voltage, among the plurality of read voltages, used to read the respective page. The count of the first memory cells can be compared with a predetermined range of a fraction of memory cells in the respective page to evaluate the plurality of read voltages (e.g., whether any of the read voltages is in a wrong voltage range).

In some aspects of the present disclosure, a memory device is disclosed. In some aspects, the memory device includes a plurality of memory cells arranged in an array, an input/output (I/O) interface connected to the plurality of memory cells to output data signal from each memory cell, and a control circuit. In some embodiments, the control circuit includes a first clock generator to generate a first clock signal and a second clock signal according to an input clock signal and a chip enable (CE) signal and provide the first clock signal to the plurality of memory cells. In some embodiments, the control circuit includes a second clock generator to generate a third clock signal according to the input clock signal and a DFT (design for testability) enable signal. In some embodiments, the control circuit generates an output clock signal according to the second clock signal or the third clock signal.

An integrated circuit (IC) includes first and scan latches that are enabled to load data during a first part of a clock period. A clocking circuit outputs latch clocks with one latch clock driven to an active state during a second part of the clock period dependent on a first address input. A set of storage elements have inputs coupled to the output of the first scan latch and are respectively coupled to a latch clock to load data during a time that their respective latch clock is in an active state. A selector circuit is coupled to outputs of the first set of storage elements and outputs a value from one output based on a second address input. The second scan latch then loads data from the selector's output during the first part of the input clock period.

An apparatus includes a first group of memory units and a second group of memory units coupled to a first data path and a second data path coupled to a controller, a first delay element on the first data path coupled to the second group of memory units and configured to send, from the controller to the second group of memory units, signals for write and read operations in a sequence of time cycles delayed by a time cycle with respect to the first group of memory units, and a second delay element on the second data path and coupled to the first group of memory units and configured to send, from the first group of memory units to the controller, test result signals delayed by a time cycle, the delayed test result signals having a matching delay to the delayed write and read operations.