The present disclosure relates to circuits, systems, and methods of operation for a memory device. In an example, a memory device includes a memory array including a plurality of memory cells, each memory cell having an impedance that varies in accordance with a respective data value stored therein; and a tracking memory cell having an impedance based on a tracking data value stored therein; and a read circuit coupled to the memory array, the read circuit configured to determine an impedance of a selected memory cells with respect to the impedance of the tracking memory cell; read a data value stored within the selected memory cell based upon a voltage change of a signal node voltage corresponding to the impedance of the selected memory cell.

A method of operating a memory circuit includes generating a first voltage by a first amplifier circuit of a first driver circuit coupled to a first column of memory cells, and generating a first current in response to the first voltage. The first current includes a first set of leakage currents and a first write current. The method further includes generating, by a tracking circuit, a second set of leakage currents configured to track the first set of leakage currents of the first column of memory cells, and mirroring the first current in a first path with a second current in a second path by a first current mirror. The second current includes the second set of leakage currents and a second write current. The first write current corresponds to the second write current. The first set of leakage currents corresponds to the second set of leakage currents.

Described herein are embodiments related to first-pass continuous read level calibration (cRLC) operations on memory cells of memory systems. A processing device determines that a first programming pass of a programming operation has been performed on a memory cell of a memory component. The processing device performs a cRLC operation on the memory cell to calibrate a read level threshold between a first first-pass programming distribution and a second first-pass programming distribution before a second programming pass of the programming operation is performed on the memory cell.

In a particular implementation, a circuit comprises: a memory array including a plurality of bit cells, where each of the bit cells are coupled to a respective bit path; a first multiplexer comprising a plurality of column address locations, where each of the plurality of column address locations is coupled to the memory array and corresponds to a respective bit path capacitance; and a variable capacitance circuit coupled to a reference path and configured to substantially match reference path capacitance to each of the respective bit path capacitances.

A dynamic random-access memory array includes a plurality of memory cells and sensor cells physical arranged in a row. The sensor cells include a transistor and a capacitor having an input terminal connected to a first non-gate terminal of the transistor. A wordline is connected to transistor gates of both the memory cells and sensor cells in the row. A sensor amplifier has inputs connected to the sensor cell, a high voltage reference line, and a low voltage reference line, and an output in communication with a row refresh circuit. If the sensor amplifier detects that the sensor cell voltage falls outside of the range of the high and low voltage reference lines, then a trigger signal is output to request that the row refresh circuit perform a priority row refresh of the memory cells and the sensor cell in the row.

A memory device, a system, and a method for operating the memory device are provided. The memory device includes a first memory string and a peripheral circuit. The first memory string includes a first drain, a first drain select gate (DSG) transistor, a first drain dummy transistor between the first drain and the first DSG transistor, and a plurality of first memory cells. A first drain dummy line is coupled to the first drain dummy transistor, and a first DSG line is coupled to the first DSG transistor. The peripheral circuit is configured to, in a program operation, apply a first DSG voltage to the first DSG line and apply a first drain dummy line voltage to the first drain dummy line to turn on the first drain dummy transistor. The first drain dummy line voltage is greater than the first DSG voltage

A semiconductor memory device includes a memory cell array and a peripheral circuit. The memory cell array includes at least two planes. The peripheral circuit performs a memory operation on a selected plane of the at least two planes during a single plane operation and performs a dummy operation on an unselected plane of the at least two planes.

A receiver that receives a multi-level signal includes a compensation circuit, a sampling circuit, an output circuit and a mode selector. The compensation circuit generates a plurality of data signals and a plurality of reference voltages by compensating intersymbol interference on an input data signal. The sampling circuit generates a plurality of sample signals based on the plurality of data signals and the plurality of reference voltages. The output circuit generates output data based on the plurality of sample signals, and selects a current value of the output data based on a previous value of the output data. The mode selector generates a mode selection signal used to select one of first and second operation modes based on an operating environment. The compensation circuit and the sampling circuit are entirely enabled in the first operation mode, and the compensation circuit and the sampling circuit are partially enabled in the second operation mode.

A receiver that receives a multi-level signal includes a compensation circuit, a sampling circuit, an output circuit and a mode selector. The compensation circuit generates a plurality of data signals and a plurality of reference voltages by compensating intersymbol interference on an input data signal. The sampling circuit generates a plurality of sample signals based on the plurality of data signals and the plurality of reference voltages. The output circuit generates output data based on the plurality of sample signals, and selects a current value of the output data based on a previous value of the output data. The mode selector generates a mode selection signal used to select one of first and second operation modes based on an operating environment. The compensation circuit and the sampling circuit are entirely enabled in the first operation mode, and the compensation circuit and the sampling circuit are partially enabled in the second operation mode.

The disclosed invention presents a self-tracking reference circuit that compensates for IR drops and achieves the target resistance state at different temperatures after write operations. The disclosed self-tracking reference circuit includes a replica access path, a configurable resistor network, a replica selector mini-array and a step current generator that track PVT variations to provide a PVT tracking level for RRAM verify operation.