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.

In one embodiment, an apparatus comprises read circuitry to apply a read voltage to a three dimensional crosspoint (3DXP) memory cell; and write setback circuitry to apply a first setback pulse having a first magnitude to the 3DXP memory cell in response to the application of the read voltage, wherein applying the first setback pulse comprises bypassing a current mirror that is to limit or control a magnitude of a second setback pulse applied to the 3DXP memory cell when the current mirror is coupled to the 3DXP memory cell.

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.

Static random access memory device comprising a memory matrix provided with at least one column (COL.sub.1) formed from a plurality of SRAM memory cells (C.sub.11, C.sub.N1), the device being provided with a fast erase memory circuit configured to connect a first bit line (BL.sub.T) and a second bit line (BL.sub.F) shared by cells in said column, following reception of an erase signal (ERASE).

A memory circuit and a memory device including the same are provided. The memory circuit may be connected to a bit line and a complementary bit line and configured to perform precharging on the bit line and the complementary bit line. The memory circuit may include: an equalizer configured to equalize voltage levels of the bit line and the complementary bit line by connecting the bit line with the complementary bit line in response to an equalizing signal; and a precharger configured to precharge the bit line and the complementary bit line to a precharge voltage in response to a precharge signal. The equalizing signal and the precharge signal may be received via separate lines.

A circuit for reading a memory cell of a non-volatile memory device provided with a memory array with cells arranged in wordlines and bitlines, among which a first bitline, associated to the memory cell, and a second bitline, has: a first circuit branch associated to the first bitline and a second circuit branch associated to the second bitline, each with a local node, coupled to which is a first dividing capacitor, and a global node, coupled to which is a second dividing capacitor; a decoder stage for coupling the local node to the first or second bitlines and coupling the global node to the local node; and a differential comparator stage supplies an output signal indicative of the datum stored; and a control unit for controlling the decoder stage, the coupling stage, and the differential comparator stage for generation of the output signal.

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.

Embodiments of the present application provide a readout circuit layout structure, a readout circuit, and a memory layout structure. The readout circuit layout structure includes: a readout amplification module, a first processing module, and a second processing module arranged along a preset direction, wherein the readout amplification module is configured to read a voltage of a bit line, and the first processing module and the second processing module are at least configured to perform a noise cancellation on an output signal of the readout amplification module. The readout amplification module includes: a first NMOS region and a first PMOS region arranged close to the first processing module, and a second NMOS region and a second PMOS region arranged close to the second processing module, the first NMOS region, the first PMOS region, the second PMOS region, and the second NMOS region being arranged along the preset direction.

In one embodiment, an apparatus comprises read circuitry to apply a read voltage to a three dimensional crosspoint (3DXP) memory cell; and write setback circuitry to apply a first setback pulse having a first magnitude to the 3DXP memory cell in response to the application of the read voltage, wherein applying the first setback pulse comprises bypassing a current mirror that is to limit or control a magnitude of a second setback pulse applied to the 3DXP memory cell when the current mirror is coupled to the 3DXP memory cell.

A method of operating a memory device is disclosed. The memory device includes a memory string coupled with a bit line and a common source line. An erase voltage is applied to the bit line and the common source line in an erase operation. The bit line and the common source line are discharged in a discharge operation after the erase operation. A voltage difference between the bit line and the common source line is less than a first predetermined value during a period of the discharge operation.