An error compensation circuit for analog capacitor memory circuits includes a first transistor and a second transistor with gates connected respectively to top and bottom of an analog memory capacitor to read a voltage charged in the analog memory capacitor; a first switch and a second switch connected respectively to the first transistor and the second transistor to select the voltage to read; a first capacitor and a second capacitor to charge an electric charge to compensate or refresh the analog memory capacitor according to on/off of the first switch and the second switch; and an input terminal connected to sources of the first transistor and the second transistor to apply the voltage to operate the circuit. Accordingly, it is possible to compensate for an unintended phenomenon of the analog capacitor memory or refresh a change in memory value caused by leakage.

A semiconductor memory cell includes a floating body region configured to be charged to a level indicative of a state of the memory cell; a first region in electrical contact with said floating body region; a second region in electrical contact with said floating body region and spaced apart from said first region; and a gate positioned between said first and second regions. The cell may be a multi-level cell. Arrays of memory cells are disclosed for making a memory device. Methods of operating memory cells are also provided.

Methods of maintaining a state of a memory cell without interrupting access to the memory cell are provided, including applying a back bias to the cell to offset charge leakage out of a floating body of the cell, wherein a charge level of the floating body indicates a state of the memory cell; and accessing the cell.

Methods, systems, and devices related to an improved driver for non-binary signaling are described. A driver for a signal line may include a set of drivers of a first type and a set of drivers of a second type. When the driver drives the signal line using multiple drivers of the first type, at least one additional driver of the first type may compensate for non-linearities associated with one or more other drivers of the first type, which may have been calibrated at other voltages. The at least one additional driver of the first type may be calibrated for use at a particular voltage, to compensate for non-linearities associated with the one or more other drivers of the first type as exhibited at that particular voltage.

A memory device includes a plurality of memory cells. A first memory cell of the plurality of memory cells includes a first write transistor includes a first write gate, a first write source, and a first write drain. A first read transistor includes first read gate, a first read source, a first read drain, and a first body region separating the first read source from the first read drain. The first read source is coupled to the first write source. A first capacitor has a first upper capacitor plate coupled to the first write drain and a first lower capacitor plate coupled to the first body region of the first read transistor.

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.

According to one embodiment, a memory system includes a semiconductor memory device including a memory cell capable of holding at least 4-bit data and a controller configured to control a first write operation and a second write operation based on the 4-bit data. The controller includes a conversion circuit configured to convert 4-bit data into 2-bit data. The semiconductor memory device includes a recovery controller configured to recover the 4-bit data based on the converted 2-bit data and data written in the memory cell by the first write operation. The first write operation is executed based on the 4-bit data received from the controller, and the second write operation is executed based on the 4-bit data recovered by the recovery controller.

A semiconductor memory device includes a memory cell array, an ECC engine, a voltage generator and a control logic circuit. The memory cell array includes a plurality of memory cells coupled to word-lines and bit-lines, and a plurality of sense amplifiers to sense data stored in the plurality of memory cells. The ECC engine reads memory data from a target page of the memory cell array, performs an ECC decoding on the memory data, detects, based on the ECC decoding, an error in the memory data, and outputs error information associated with the error. The voltage generator provides driving voltages to the plurality of sense amplifiers, respectively. The control logic circuit controls the ECC engine, and controls the at least one voltage generator to increase an operating margin of each of the plurality of sense amplifiers based on error pattern information including the error information.

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 volatile memory device includes: a first sense amplifier connected to a first memory cell through a first bit line, and configured to sense 2-bit data stored in the first memory cell; a second sense amplifier connected to a second memory cell through a second bit line, and configured to sense 2-bit data stored in the second memory cell, the second bit line having a length greater than a length of the first bit line; and a driving voltage supply circuit configured to supply a first driving voltage to the first sense amplifier, and supply a second driving voltage to the second sense amplifier, the second driving voltage having a voltage level different from a voltage level of the first driving voltage.