A device includes a memory array, bit line pairs, word lines, a modulation circuit and a control signal generator. The memory array has bit cells arranged in rows and columns. Each bit line pair is connected to a respective column of bit cells. Each word line is connected to a respective row of bit cells. The modulation circuit is coupled with at least one bit line pair. The control signal generator is coupled with the modulation circuit. The control signal generator includes a tracking wiring with a tracking length positively correlated with a depth distance of the word lines. The control signal generator is configured to produce a control signal, switching to a first voltage level for a first time duration in reference with the tracking length, for controlling the modulation circuit. A method of controlling aforesaid device is also disclosed.

The present disclosure provides a method for discharging a memory device after an erase operation. The method comprises grounding a source line of the memory device; and switching on a discharge transistor to connect a bit line of the memory device to the source line by maintaining a constant voltage difference between a gate terminal of the discharge transistor and the source line. The method also includes comparing an electrical potential of the source line with a first predetermined value; and floating the gate terminal of the discharge transistor when the electrical potential of the source line is lower than the first predetermined value.

Disclosed herein are related to a memory device. In one aspect, the memory device includes a memory cell, a precharge circuit, a reset voltage control circuit, and a logic control circuit. In one aspect, the precharge circuit is configured to set a voltage of the bit line to a first voltage level. In one aspect, the reset voltage control circuit includes a transistor coupled to the bit line to set the voltage of the bit line to a second voltage level. The transistor can be arranged or operate as a diode. In one aspect, the logic control circuit is configured to cause the reset voltage control circuit to set the voltage of the bit line to the second voltage level during a reset phase and cause the precharge circuit to set the voltage of the bit line to the first voltage level during a precharge phase after the reset phase.

Systems and methods are provided for controlling a wake-up operation of a memory circuit. The memory circuit is configured to precharge the bit lines of a memory array sequentially during wakeup. A sleep signal is received by the first bit line of a memory cell and then a designed delay occurs prior to the precharge of a second complementary bit line. The sleep signal may then precharge the bit lines of a second memory cell with further delay between the precharge of each bit line. The memory circuit is configured to precharge both bit lines of a memory cell at the same time when an operation associated with that cell is designated.

The present disclosure relates to a precharge circuitry for bit lines of an array of memory cells, the precharge circuitry comprising a precharge and limiting unit configured to precharge a first bit line and a second bit line, the precharge and limiting unit further configured to limit a first bit line precharge level of the first bit line and a second bit line precharge level of the second bit line during a precharge cycle of a read and/or write operation of any of the memory cells, wherein the precharge and limiting unit is configured to limit the first bit line precharge level and the second bit line precharge level in a single precharge cycle, preferably without substantial delay. The disclosure further relates to a memory comprising a plurality of memory cells arranged in columns and rows, and at least one precharge circuit, wherein the precharge circuit is connected to a first bit line and a second bit line of all memory cells within a column, wherein each precharge circuit is configured to limit the first bit line to a first bit line precharge level and the second bit line to a second bit line precharge level during a precharge cycle.

A data receiving circuit is provided. The data receiving circuit includes a data input circuit, a latch circuit, and an equalizer. The data input circuit is configured to receive an input signal, and the latch circuit is connected to the data input circuit and configured to output an output signal in response to the input signal. The equalizer includes a first transistor having a source connected to latch circuit; and a second transistor having a source connected to the latch circuit and a gate connected to a gate of the first transistor.

An operating method of a memory device includes selecting a receiver from a plurality of receivers of each memory chip of a plurality of memory chips included in the memory device as a first receiver. The plurality of memory chips share a plurality of data signal lines, each memory chip includes a plurality of on-die termination (ODT) resistors, and the plurality of ODT resistors are respectively connected to the plurality of receivers of each memory chip. The method further includes setting each ODT resistor which is connected to a first receiver to a first resistance value, setting ODT resistors which are connected to receivers which are not first receivers to a second resistance value, and setting an amplification strength of an equalizer circuit of each first receiver by performing training operations. Each data signal line of the plurality of data signal lines is respectively connected to a first receiver.

A data receiving circuit is provided. The data receiving circuit includes a data input circuit, a latch circuit, and an equalizer. The data input circuit is configured to receive an input signal, and the latch circuit is connected to the data input circuit and configured to output an output signal in response to the input signal. The equalizer includes a first transistor having a source connected to latch circuit; and a second transistor having a source connected to the latch circuit and a gate connected to a gate of the first transistor.

A device includes a memory array, bit line pairs, word lines, a modulation circuit and a control signal generator. The memory array has bit cells arranged in rows and columns. Each bit line pair is connected to a respective column of bit cells. Each word line is connected to a respective row of bit cells. The modulation circuit is coupled with at least one bit line pair. The control signal generator is coupled with the modulation circuit. The control signal generator includes a tracking wiring with a tracking length positively correlated with a depth distance of the word lines. The control signal generator is configured to produce a control signal, switching to a first voltage level for a first time duration in reference with the tracking length, for controlling the modulation circuit. A method of controlling aforesaid device is also disclosed.

A device includes a memory array, bit line pairs, word lines, a modulation circuit and a control signal generator. The memory array has bit cells arranged in rows and columns. Each bit line pair is connected to a respective column of bit cells. Each word line is connected to a respective row of bit cells. The modulation circuit is coupled with at least one bit line pair. The control signal generator is coupled with the modulation circuit. The control signal generator includes a tracking wiring with a tracking length positively correlated with a depth distance of the word lines. The control signal generator is configured to produce a control signal, switching to a first voltage level for a first time duration in reference with the tracking length, for controlling the modulation circuit. A method of controlling aforesaid device is also disclosed.