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.

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.

Apparatuses and methods including multiple read modes for reading data from a memory are described. An example apparatus includes a memory including a first read mode and a second read mode. The memory has a read operation for the first read mode including a first pre-access phase, an access phase, and a first post-access phase. The read operation for the second read mode includes a second pre-access phase, the access phase, and a second post-access phase. The read operation for either the first read mode or the second read mode is performed responsive to the memory receiving a read command. The second pre-access phase is different from the first pre-access phase, with the second pre-access phase having a shorter time than the first pre-access phase measured from receipt of the read command.

Apparatuses and methods including multiple read modes for reading data from a memory are described. An example apparatus includes a memory including a first read mode and a second read mode. The memory has a read operation for the first read mode including a first pre-access phase, an access phase, and a first post-access phase. The read operation for the second read mode includes a second pre-access phase, the access phase, and a second post-access phase. The read operation for either the first read mode or the second read mode is performed responsive to the memory receiving a read command. The second pre-access phase is different from the first pre-access phase, with the second pre-access phase having a shorter time than the first pre-access phase measured from receipt of the read command.

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.

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.

The present technology includes a memory device. The memory device includes memory cells, page buffers configured to store sensed data obtained from the memory cells, a current sensing circuit configured to compare a sensed voltage generated according to the sensed data and a reference voltage generated according to an allowable fail bit code, and output a pass signal or a fail signal according to a comparison result, and a fail bit manager configured to increase an allowable number of fail bits included in the allowable fail bit code until the pass signal is output from the current sensing circuit, change the allowable fail bit code according to the allowable number of fail bits, and provide the allowable fail bit code to the current sensing circuit.

The present technology includes a memory device. The memory device includes memory cells, page buffers configured to store sensed data obtained from the memory cells, a current sensing circuit configured to compare a sensed voltage generated according to the sensed data and a reference voltage generated according to an allowable fail bit code, and output a pass signal or a fail signal according to a comparison result, and a fail bit manager configured to increase an allowable number of fail bits included in the allowable fail bit code until the pass signal is output from the current sensing circuit, change the allowable fail bit code according to the allowable number of fail bits, and provide the allowable fail bit code to the current sensing circuit.

Systems and methods are provided for limiting a negative bit line voltage in a SRAM cell. A voltage limiter circuit may be implemented in a write driver to control the magnitude of negative voltage imposed on a bit line. The voltage limiter circuit can produce the required magnitude of negative bit line voltage at lower operating voltage levels. The voltage limiter circuit can also limit the magnitude of negative bit line voltage to not exceed a predetermined value. The reduction of the magnitude of the negative bit line voltage can reduce the active power of a SRAM cell.

A memory includes first signal lines divided into groups respectively including m (m is an integer equal to or larger than 2) lines, and second signal lines. A memory cell array includes memory cells. (m+2) or more global signal lines are configured to apply a selection voltage to any of the first signal lines. First transistors are provided to correspond to each of the first signal lines in one-to-one correspondence and are connected between the first signal lines and the global signal lines. First selection signal lines are provided to respectively correspond to the groups, and are each connected to gate electrodes of the first transistors included in a corresponding one of the groups in common. The first signal lines located at both ends of each of any two of the groups which are adjacent to each other are connected to mutually different ones of the global signal lines.