A method for performing an in-memory computation includes: storing data in memory cells of a memory array, the data including weights for computation; determining whether an update command to change at least one of the weights is received; in response to receiving the update command, performing a write operation on the memory array to update the at least one weight; and disabling the write operation on the memory array until receiving a next update command to change the at least one weight.

Methods, systems, and devices for activate commands for memory preparation are described. A memory device may receive an activate command for a row of a memory bank in the memory device. The activate command may include an indicator that indicates a type of an access operation associated with the activate command. The memory device may perform, based on the type of the access operation, an operation to prepare the memory device for the access operation. The memory device may then receive an access command for the access operation after performing the operation to prepare the memory device for the access operation.

A high resolution impedance adjustment (ZQ) calibration method using a hidden least significant bit (HLSB) is provided. The high resolution ZQ calibration method generates a data input/output (DQ) code of n+1 bits without a calibration time increase by adding the hidden least significant bit (HLSB) to a ZQ code of n bits output in a ZQ calibration operation of an impedance adjustment (ZQ) pad. A change in a termination resistance of the DQ pad is reduced as small as possible by the DQ code of n+1 bits.

The present disclosure relates to the field of semiconductor circuit design, and in particular to a readout circuit layout structure and a method of reading data. The readout circuit layout structure includes: a first readout circuit structure and a second readout circuit structure having identical structures, wherein the first readout circuit structure and the second readout circuit structure each include: a first isolation module, configured to be turned on according to a first isolation signal, electrically connect a bit line and a first readout bit line, and electrically connect a complementary bit line and a first complementary readout bit line; a second isolation module, configured to be turned on according to a second isolation signal, electrically connect the first readout bit line and a second readout bit line, and electrically connect the first complementary readout bit line and a second complementary readout bit line.

Apparatuses and methods are provided for logic/memory devices. An example apparatus comprises a plurality of memory components adjacent to and coupled to one another. A logic component is coupled to the plurality of memory components. At least one memory component comprises a memory device having an array of memory cells and sensing circuitry coupled to the array. The sensing circuitry includes a sense amplifier and a compute component. Timing circuitry is coupled to the array and sensing circuitry and configured to control timing of operations for the sensing circuitry. The logic component comprises control logic coupled to the timing circuitry. The control logic is configured to execute instructions to cause the sensing circuitry to perform the operations.

The present invention is directed to methods and compositions for generating a pool of oligonucleotides. The invention finds use in preparing a population or subpopulations of oligonucleotides in solution. The pool of oligonucleotides finds use in a variety of nucleic acid detection and/or amplification assays.

A method of programming a nonvolatile memory device includes performing a single-pulse program operation in a program loop, determining whether a condition is satisfied in the a program loop, and performing a multi-pulse program operation in a next program loop when the condition is satisfied. The single-pulse program operation includes applying a first program pulse and applying plural verification pulses, the multi-pulse program operation includes applying a second program pulse, applying a third program pulse, and applying plural verification pulses, and each of the second program pulse and the third program pulse has a level lower than a level of the first program pulse.

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.

A data receiving circuit includes: a first amplification module configured to receive a data signal and a reference signal, compare the data signal and the reference signal in response to a first sampling clock signal, and output a first voltage signal and a second voltage signal; a decision feedback control module configured to generate a second sampling clock signal in response to the enable signal; a decision feedback equalization module configured to, when the enable signal is in a first level value interval, perform decision feedback equalization in response to the second sampling clock signal and stop performing the decision feedback equalization when the enable signal is in a second level value interval; and a second amplification module configured to process the first voltage signal and the second voltage signal and output the first output signal and the second output signal.

A semiconductor device comprises: a first or a second path configured to transmit a first signal which swings between a ground level and a first level, a third path configured to transmit a second signal which swings between the ground level and a second level lower than the first level, a transmitter configured to output received the first signal through the first or second path as the second signal to the third path, and initialize in response to an enable signal, and a receiver configured to output received the second signal through the third path as the first signal through the first or second path, determine level of the second signal through a reference level that is regulated according to a fed-back level of an output terminal thereof, and initialize in response to the enable signal.