An address control circuit includes an address timing control circuit configured to latch address signals inputted from outside the address timing control circuit, sequentially store the latched signals at predetermined timings, and output the stored signals as a bank group address. The address control circuit also includes an address multiplexing circuit configured to generate bank group select signals according to the bank group address. The address multiplexing circuit is configured to generate the bank group select signals having a second value according to the bank group address having a first value when a preset memory access mode is a first memory access mode, and generate the bank group select signals having the second value according to the bank group address having a third value different from the first value when the preset memory access mode is a second memory access mode.

An address control circuit includes an address timing control circuit configured to latch address signals inputted from outside the address timing control circuit, sequentially store the latched signals at predetermined timings, and output the stored signals as a bank group address. The address control circuit also includes an address multiplexing circuit configured to generate bank group select signals according to the bank group address. The address multiplexing circuit is configured to generate the bank group select signals having a second value according to the bank group address having a first value when a preset memory access mode is a first memory access mode, and generate the bank group select signals having the second value according to the bank group address having a third value different from the first value when the preset memory access mode is a second memory access mode.

Apparatuses and methods for temperature and process corner sensitive control of power gated domains are described. An example apparatus includes an internal circuit; a power supply line; and a power gating control circuit which responds, at least in part, to a first change from a first state to a second state of a control signal to initiate supplying a power supply voltage from the power supply line to the internal circuit, and continue supplying the power supply voltage from the power supply line to internal circuit for at least a timeout period from a second change from the second state to the first state of the control signal, in which the timeout period represent temperature dependency.

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 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.

An input sampling method includes the following operations. A first pulse signal and a second pulse signal are received. Logical operation is performed on the first pulse signal and the second pulse signal to determine a to-be-sampled signal. The to-be-sampled signal is obtained by shielding an invalid part of the second pulse signal according to a logical operation result. Sampling process is performed on the to-be-sampled signal to obtain a target sampled signal.

The present disclosure provides a memory device, wherein: an address latch can output a block selection control signal according to a block selection enable signal; a test mode selection unit can output a test mode selection signal according to a test mode selection instruction signal; a block selection unit outputs a block selection signal according to a mode selection signal and a block selection enable signal; when the memory enters a first test mode according to the test mode selection signal, an output buffer disables some of the input/output ports, and sequentially outputs the first input/output data and the second input/output data through un-disabled the input/output ports. The memory device according to the present disclosure can occupy less input/output ports of a test machine.

The present disclosure provides a memory device, wherein: an address latch can output a block selection control signal according to a block selection enable signal; a test mode selection unit can output a test mode selection signal according to a test mode selection instruction signal; a block selection unit outputs a block selection signal according to a mode selection signal and a block selection enable signal; when the memory enters a first test mode according to the test mode selection signal, an output buffer disables some of the input/output ports, and sequentially outputs the first input/output data and the second input/output data through un-disabled the input/output ports. The memory device according to the present disclosure can occupy less input/output ports of a test machine.

A memory device of a memory module includes a CA buffer that receives a command/address (CA) signal through a bus shared by a memory device different from the memory device of the memory module, and a calibration logic circuit that identifies location information of the memory device on the bus. The memory device recognizes its own location on a bus in a memory module to perform self-calibration, and thus, the memory device appropriately operates even under an operation condition varying depending on a location in the memory module.

Aspects of the present disclosure are directed to devices and methods for performing MAC operations using a memory array as a compute-in-memory (CIM) device that can enable higher computational throughput, higher performance and lower energy consumption compared to computation using a processor outside of a memory array. In some embodiments, an activation architecture is provided using a bit cell array arranged in rows and columns to store charges that represent a weight value in a weight matrix. A read word line (RWL) may be repurposed to provide the input activation value to bit cells within a row of bit cells, while a read-bit line (RBL) is configured to receive multiplication products from bit cells arranged in a column. Some embodiments provide multiple sub-arrays or tiles of bit cell arrays.