Apparatuses and methods involving accessing distributed sub-blocks of memory cells are described. In one such method, distributed sub-blocks of memory cells in a memory array are enabled to be accessed at the same time. Additional embodiments are described.

Apparatuses and methods involving accessing distributed sub-blocks of memory cells are described. In one such method, distributed sub-blocks of memory cells in a memory array are enabled to be accessed at the same time. Additional embodiments are described.

In a configuration including a memory cell that retains multilevel data by controlling the on/off state of a transistor, correct data can be read out even if a potential of data retained by turning off the transistor is changed. The memory cell controls writing or retention of data corresponding to one of a plurality of potentials by controlling an on/off state of the transistor. The write voltage generator circuit outputs a first write voltage of data to be written to the memory cell. The write voltage generator circuit obtains a read voltage of the data by reading the first write voltage written to the memory cell. The write voltage generator circuit generates a second write voltage by correcting a change of the first write voltage caused by turning off the transistor, and outputs the second write voltage to the memory cell.

In a configuration including a memory cell that retains multilevel data by controlling the on/off state of a transistor, correct data can be read out even if a potential of data retained by turning off the transistor is changed. The memory cell controls writing or retention of data corresponding to one of a plurality of potentials by controlling an on/off state of the transistor. The write voltage generator circuit outputs a first write voltage of data to be written to the memory cell. The write voltage generator circuit obtains a read voltage of the data by reading the first write voltage written to the memory cell. The write voltage generator circuit generates a second write voltage by correcting a change of the first write voltage caused by turning off the transistor, and outputs the second write voltage to the memory cell.

A semiconductor memory device includes a memory cell array, an error correction code (ECC) engine, a scrubbing control circuit and a control logic circuit. The memory cell array includes memory cell rows, and each of the memory cell rows including volatile memory cells. The scrubbing control circuit generates scrubbing addresses for performing a normal scrubbing operation on the memory cell rows with a first period based on refresh row addresses for refreshing the memory cell rows. The control logic circuit controls the ECC engine the scrubbing control circuit to distribute a scrubbing operation on weak codewords dynamically within the refresh operation such that a dynamic allocated scrubbing (DAS) operation is performed with a second period smaller than the first period. An error bit is detected in each of the weak codewords during the normal scrubbing operation or normal read operation on at least one of the memory cell rows.

Aspects of the disclosure provide a sense amplifier that includes a first amplifying circuit, a second amplifying circuit, a coupling circuit and a detection circuit. The first amplifying circuit is configured to receive an input signal that carries digital values and amplify the input signal to generate a first output. The coupling circuit is configured to combine the input signal with an offset signal to form a combined signal. The offset signal is used to cancel an offset of the first amplifying circuit. The second amplifying circuit is configured to receive the combined signal of the input signal and the offset signal and amplify the combined signal to generate a second output. The first output and the second output are combined to form a combined output. The detection circuit is configured to detect the digital values based on the combined output.

An integrated circuit can include multiple SRAM cells, each including at least two pull-up transistors, at least two pull-down transistors, and at least two pass-gate transistors, each of the transistors having a gate; at least one of the pull-up transistors, the pull-down transistors, or the pass-gate transistors having a screening region a distance below the gate and separated from the gate by a semiconductor layer, the screening region having a concentration of screening region dopants, the concentration of screening region dopants being higher than a concentration of dopants in the semiconductor layer, the screening region providing an enhanced body coefficient for the pull-down transistors and the pass-gate transistors to increase the read static noise margin for the SRAM cell when a bias voltage is applied to the screening region; and a bias voltage network operable to apply one or more bias voltages to the multiple SRAM cells.

An integrated circuit can include multiple SRAM cells, each including at least two pull-up transistors, at least two pull-down transistors, and at least two pass-gate transistors, each of the transistors having a gate; at least one of the pull-up transistors, the pull-down transistors, or the pass-gate transistors having a screening region a distance below the gate and separated from the gate by a semiconductor layer, the screening region having a concentration of screening region dopants, the concentration of screening region dopants being higher than a concentration of dopants in the semiconductor layer, the screening region providing an enhanced body coefficient for the pull-down transistors and the pass-gate transistors to increase the read static noise margin for the SRAM cell when a bias voltage is applied to the screening region; and a bias voltage network operable to apply one or more bias voltages to the multiple SRAM cells.

Provided is a data bus driving circuit including: a data processing unit that processes input data and outputs processed data; a first logic inversion unit that selects, based on a determination result signal, one of the processed data and inverted data obtained by logically inverting each value of a plurality of bits constituting the processed data, and outputs the selected data to a data bus; and an inversion determination unit that compares the data output from the first logic inversion unit with the input data that has not been processed by the data processing unit, and outputs the determination result signal based on a comparison result.

Provided is a data bus driving circuit including: a data processing unit that processes input data and outputs processed data; a first logic inversion unit that selects, based on a determination result signal, one of the processed data and inverted data obtained by logically inverting each value of a plurality of bits constituting the processed data, and outputs the selected data to a data bus; and an inversion determination unit that compares the data output from the first logic inversion unit with the input data that has not been processed by the data processing unit, and outputs the determination result signal based on a comparison result.