A data storage device includes a flash memory and a controller. The controller is coupled to the flash memory and includes a ROM which stores a boot code. In an initialization procedure of the data storage device, the controller does not access the flash memory and receives a debug code from an external device, and executes the boot code and the debug code to complete the initialization procedure.

Apparatuses and methods of sharing error correction memory on an interface chip are described. An example apparatus includes: at least one memory chip having a plurality of first memory cells and an interface chip coupled to the at least one memory chip and having a control circuit and a storage area. The control circuit detects one or more defective memory cells of the first memory cells of the at least one memory chip. The control circuit further stores first defective address information of the one or more defective memory cells of the first memory cells into the storage area. The interface chip responds to the first defective address information and an access request to access the storage area in place of the at least one memory chip when the access request has been provided with respect to the one or more defective memory cells of the first memory cells.

Disclosed is a methods and apparatus which can improve defect tolerability of a hardware-based neural network. In one embodiment, a method for performing a calculation of values on first neurons of a first layer in a neural network, includes: receiving a first pattern of a memory cell array; determining a second pattern of the memory cell array according to a third pattern; determining at least one pair of columns of the memory cell array according to the first pattern and the second pattern; switching input data of two columns of each of the at least one pair of columns of the memory cell array; and switching output data of the two columns in each of the at least one pair of columns of the memory cell array so as to determine the values on the first neurons of the first layer.

A memory device includes a memory cell array having a plurality of memory cell groups with a corresponding plurality of independent channels, and the device and an operating method thereof perform an internal data processing operation for the memory cell groups. The memory device includes an internal command generator configured to generate one or more internal commands in order to perform an internal data processing operation in response to a reception of a command, and an internal common bus for a common internal processing channel which is disposed to be shared by the plurality of memory cell groups and configured to form a transmission path of data between the plurality of memory cell groups when the internal data processing operation is performed.

According to some embodiments, for a memory device including a base die and a stack of memory dies including a plurality of memory dies stacked on the base die, the base die including a plurality of first input/output (i/o) terminals that are command/address and data terminals and a plurality of second i/o terminals that are direct access terminals, a method includes receiving at the plurality of first i/o terminals a command/address, a clock signal, and data; first transmitting the command/address, clock signal, and data received by the plurality of first i/o terminals from the base die to the stack of memory dies; and second transmitting at least part of one or more of the command/address, clock signal, and data received by a set of the plurality of first i/o terminals through a circuit of the base die to the plurality of second i/o terminals.

The present disclosure relates to a memory device comprising: an array of memory cells; and an access management architecture providing a secure access to a test mode of the array of memory cells, the access management architecture comprising: a register group comprising data identifying the memory device; a cryptographic algorithm calculating an internal signature having a mechanism for ensuring data freshness; a non volatile memory area storing specific data to be used by the cryptographic algorithm for calculating the internal signature; a comparison block for comparing the calculated internal signature with a user provided signature to generate an enable signal allowing access to a test mode of the array of memory cells. The disclosure also relates to a System-on-Chip (SoC) component comprising a memory device as well as to a method for managing access to a memory array into a test mode.

A test apparatus includes a device under test (DUT) configured to exchange data using a serial interface protocol and a test controller configured to receive a binary vector corresponding to a physical layer of the serial interface protocol from an external device and to buffer and transmit the received binary vector to the DUT.

According to an embodiment, a semiconductor device includes a transmission circuit including first and second transistors coupled in series between a first voltage terminal and a second voltage terminal, and a first common node coupled between the first and second transistors and coupled to a through line, the transmission circuit outputting a signal transferred from an internal circuit to the first common node according to an output control signal; a reception circuit including third and fourth transistors coupled in series between the first voltage terminal and the second voltage terminal, and a second common node coupled between the third and fourth transistors and coupled to the internal circuit, the reception circuit transferring a signal transferred through the through line to the internal circuit according to a first input control signal; and a deterioration acceleration circuit for applying stress to the first and third transistors according to a test signal.

An exemplary testing environment can operate in a testing mode of operation to test whether a memory device or other electronic devices communicatively coupled to the memory device operate as expected or unexpectedly as a result of one or more manufacturing faults. The testing mode of operation includes a shift mode of operation, a capture mode of operation, and/or a scan mode of operation. In the shift mode of operation and the scan mode of operation, the exemplary testing environment delivers a serial input sequence of data to the memory device. In the capture mode of operation, the exemplary testing environment delivers a parallel input sequence of data to the memory device. The memory device thereafter passes through the serial input sequence of data or the parallel input sequence of data to provide an output sequence of data in the shift mode of operation or the capture mode of operation or passes through the serial input sequence of data to provide a serial output sequence of scan data in the scan mode of operation.

An exemplary testing environment can operate in a testing mode of operation to test whether a memory device or other electronic devices communicatively coupled to the memory device operate as expected or unexpectedly as a result of one or more manufacturing faults. The testing mode of operation includes a shift mode of operation, a capture mode of operation, and/or a scan mode of operation. In the shift mode of operation and the scan mode of operation, the exemplary testing environment delivers a serial input sequence of data to the memory device. In the capture mode of operation, the exemplary testing environment delivers a parallel input sequence of data to the memory device. The memory device thereafter passes through the serial input sequence of data or the parallel input sequence of data to provide an output sequence of data in the shift mode of operation or the capture mode of operation or passes through the serial input sequence of data to provide a serial output sequence of scan data in the scan mode of operation.