Embodiments of the disclosure are drawn to apparatuses, systems, and methods for direct access hybrid testing. A memory device, such as a high bandwidth memory (HBM) may include direct access terminals. During a testing procedure, test instructions may be provided to the memory through the direct access terminals. The test instructions include a data pointer which is associated with one of a plurality of test patterns pre-loaded in the memory and an address. The selected test pattern may be written to, and subsequently read from, the memory cells associated with the address. The read test pattern may be compared to the selected test pattern to generate result information. The test patterns may be loaded to the memory, and the result information may be read out from the memory, in an operational mode different than the operational mode in which the test instructions are provided.

A memory device includes a first comparison circuit suitable for comparing read data read from a plurality of memory cells with write data written in the memory cells and outputting a comparison result, a path selection circuit suitable for transferring selected data selected among the read data and test data as read path data based on the comparison result of the first comparison circuit, and an output data alignment circuit suitable for converting the read path data into serial data to output the serial data as output data.

A method of operating a controller includes randomly transmitting a first command to a non-volatile memory device upon a read request from a host; receiving first read data corresponding to the first command from the non-volatile memory device; determining whether the number of first error bits of the first read data is greater than a first reference value; determining whether the number of first error bits is greater than a second reference value, when the number of first error bits is not greater than the first reference value; storing a target wordline in a health buffer, when the number of first error bits is greater than the second reference value; periodically transmitting a second command to the non-volatile memory device; and receiving second read data corresponding to the second command from the non-volatile memory device.

The invention introduces a method for verifying memory interface, performed by a processing unit, to include: driving a physical layer of a memory interface to pull-high or pull-low a signal voltage on each Input-Output (IO) pin thereof to a preset level according to a setting; obtaining a verification result corresponding to each IO pin from the memory interface; and storing each verification result in a static random access memory (SRAM), thereby enabling a testing host to obtain each verification result of the SRAM through a test interface. The testing host may examine each verification result to know whether any unexpected error has occurred in signals on the IO pins of the memory interface.

A control circuit, a memory system and a control method are provided. The control circuit is configured to control a plurality of memory cells of a memory array. The control circuit comprises a program controller. The program is configured to program a first electrical characteristic distribution and a second electrical characteristic distribution of the memory cells according to error tolerance of a first bit of a data type. A first overlapping area between the first electrical characteristic distribution and the second electrical characteristic distribution is smaller than a first predetermined value.

A memory device includes a content addressable memory (CAM) block storing a plurality of stored search keys. The memory device further includes control logic that determines a first number of memory cells in at least one string of the CAM block storing one of the plurality of stored search keys, the first number of memory cells storing a first logical value, and stores a calculated parity value representing the first number of memory cells in a page cache associated with the CAM block. The control logic further reads stored parity data from one or more memory cells in the at least one string, the one or more memory cells connected to one or more additional wordlines in the CAM block, and compares the calculated parity value to the stored parity data to determine whether an error is present in the one of the plurality of stored search keys in the CAM block.

An image processing apparatus including a plurality of transfer units, a data storage, an image processing processor, and a test circuit. A plurality of captured image data are respectively assigned to the plurality of transfer units and the plurality of transfer units transfer the assigned image data. The data storage unit stores the plurality of image data which are transferred by the plurality of transfer units. The image processing processor performs image processing on the plurality of image data which are stored in the data storage unit. The test circuit tests the image processing processor in a period during which the image data are not input from the data storage unit to the image processing processor.

An integrated memory assembly comprises a memory die and a control die bonded to the memory die. The memory die includes a memory structure of non-volatile memory cells. The control die is configured to program user data to and read user data from the memory die based on one or more operational parameters. The control die is configured to calibrate the one or more operational parameters for the memory die. The control die is also configured to perform testing of the memory die using the calibrated one or more operational parameters.

A memory test method includes: testing a first memory to acquire defect information of the first memory; acquiring repair information of the first memory according to the defect information of the first memory; and storing the repair information of the first memory in a second memory. In the technical solutions provided in the embodiments of the present disclosure, other memories may be used to store the repair information of the currently tested memory, so that the storage space can be increased and the test efficiency can be improved.

According to one embodiment, an arithmetic device includes a first computational circuit including a first string, the first string having a first magnetoresistive effect element on a first conducting layer; a second computational circuit including a second strings, the second string having second magnetoresistive effect element on a second conducting layer; a third computational circuit executing computational processing using a first signal from the first computational circuit and a second signal from the second computational circuit; and a control circuit. The control circuit sets a condition on write operations with respect to at least one of the first and second magnetoresistive effect elements, based on information related to write error in at least one of the first and second magnetoresistive effect elements.