A method to manufacture a semiconductor device includes: bonding a first wafer and a second wafer to be stacked vertically with one another, in which the first wafer provides a plurality of memory components and the second wafer provides a control circuit; forming a plurality of input/output channels on a surface of one of the first and second wafers; and cutting the bonded first and second wafers into a plurality of dices; wherein a plurality of first conductive contacts in the first wafer are electrically connected to the control circuit and the first conductive contacts in combinations with a plurality of first conductive vias in the first wafer form a plurality of transmission channels through which the control circuit is capable to access the memory components.

In various examples, a test system is provided for executing built-in-self-test (BIST) on integrated circuits deployed in the field. The integrated circuits may include a first device and a second device, the first device having direct access to external memory, which stores test data, and the second device having indirect access to the external memory by way of the first device. In addition to providing a mechanism to permit the first device and the second device to run test concurrently, the hardware and software may reduce memory requirements and runtime associated with running the test sequences, thereby making real-time BIST possible in deployment. Furthermore, some embodiments permit a single external memory image to cater to different SKU configurations.

Presented embodiments facilitate efficient and effective flexible implementation of different types of testing procedures in a test system. In one embodiment, a multiple-name-space testing system comprises a load board, testing electronics, and a namespace testing tracker. The load board is configured to couple with a plurality of devices under test (DUTs). The testing electronics are configured to test the plurality of DUTs, wherein the testing electronics are coupled to the load board. The controller is configured to direct testing of multiple-name-spaces across the plurality of DUTs at least in part in parallel. The controller can be coupled to the testing electronics. The namespace testing tracker is configured to track testing of the plurality of DUTs, including the testing of the multiple-name-spaces across the plurality of DUTs at least in part in parallel. In one embodiment, the DUTs are NVMe SSD devices.

The present disclosure includes apparatuses and methods for parallel writing to multiple memory device locations. An example apparatus comprises a memory device. The memory device includes an array of memory cells and sensing circuitry coupled to the array. The sensing circuitry includes a sense amplifier and a compute component configured to implement logical operations. A memory controller in the memory device is configured to receive a block of resolved instructions and/or constant data from the host. The memory controller is configured to write the resolved instructions and/or constant data in parallel to a plurality of locations the memory device.

A memory device may include a memory cell array including a plurality of memory cells, and an internal operation circuit configured to perform a test operation in a test mode using a parallel bit operation of simultaneously comparing a plurality of bits and also perform an internal operation including a comparison operation with respect to external data in a normal mode other than the test mode using the parallel bit operation.

A resistance variable memory apparatus may include a memory cell array and a controller. The memory cell array may include a plurality of resistance variable memory cells. The controller may control a current path flowing through any one memory cell and a current path flowing through the other memory cell to be formed differently from each other in response to at least two address signals.

The present disclosure includes apparatuses and methods for parallel writing to multiple memory device locations. An example apparatus comprises a memory device. The memory device includes an array of memory cells and sensing circuitry coupled to the array. The sensing circuitry includes a sense amplifier and a compute component configured to implement logical operations. A memory controller in the memory device is configured to receive a block of resolved instructions and/or constant data from the host. The memory controller is configured to write the resolved instructions and/or constant data in parallel to a plurality of locations the memory device.

A semiconductor device includes: a multi-level receiver including N sense amplifiers and a decoder decoding an output of the N sense amplifiers, each of the N sense amplifiers receiving a multi-level signal having M levels and a reference signal (where M is a natural number, higher than 2, and where N is a natural number, lower than M); a clock buffer receiving a reference clock signal; and a clock controller generating N clock signals using the reference clock signal, inputting the N clock signals to the N sense amplifiers, respectively, and individually determining a phase of each of the N clock signals using the output of the N sense amplifiers.

A memory system includes a plurality of memory devices having respective arrays of memory cells therein, a bus electrically coupled to and shared by the plurality of memory devices, and a memory controller. The memory controller, which is electrically coupled to the bus, includes a built-in self-test (BIST) circuit, which is commonly connected to the plurality of memory devices. The BIST circuit is configured to transfer a command set including a test pattern to the plurality of memory devices via the bus, and transfer a command trigger signal for driving the test pattern to the plurality of memory devices via the bus.

A semiconductor apparatus may include: a data storage group including first to eight data storage areas; a first channel select pad configured to transmit a first channel select signal to the first and third data storage areas; a second channel select pad configured to transmit a second channel select signal to the second and fourth data storage areas; a third channel select pad configured to transmit the first channel select signal to the sixth and eighth data storage areas; a fourth channel select pad configured to transmit the second channel select signal to the fifth and seventh data storage areas; a first clock enable pad configured to transmit a first clock enable signal to the first and third data storage areas; a second clock enable pad configured to transmit a second clock enable signal to the second and fourth data storage areas; a third clock enable pad configured to transmit the first clock enable signal to the fifth and seventh data storage areas; and a fourth clock enable pad configured to transmit the second clock enable signal to the sixth and eighth data storage areas.