Abstract: A method of writing data into a memory device is disclosed. The method comprises utilizing a pipeline to process write operations of a first plurality of data words addressed to a memory bank. Further, the method comprises writing a second plurality of data words and associated memory addresses into a cache memory, wherein the cache memory is associated with the memory bank and wherein further each data word of the second plurality of data words is either awaiting write verification associated with the memory bank or is to be re-written into the memory bank. The method also comprises detecting a power down signal and responsive to the power down signal, transferring the second plurality of data words and associated memory addresses from the cache memory into a secure memory storage area reserved in the memory bank. Finally, the method comprises powering down the memory device.

Abstract: Dynamic redundancy buffers for use with a device are disclosed. The dynamic redundancy buffers allow a memory array of the device to be operated with high write error rate (WER). A first level redundancy buffer (e1 buffer) is couple to the memory array. The e1 buffer may store data words that have failed verification or have not been verified. The e1 buffer may transfer data words to another dynamic redundancy buffer (e2 buffer). The e1 buffer may transfer data words that have failed to write to a memory array after a predetermined number of re-write attempts. The e1 buffer may also transfer data words upon power down.

Abstract: A memory cell apparatus is provided. The apparatus comprises two or more magnetic tunnel junctions (MTJs), including a first MTJ having a first magnetic characteristic and a first electrical characteristic and a second MTJ having a second magnetic characteristic and a second electrical characteristic. The first magnetic characteristic is distinct from the second magnetic characteristic. The apparatus further comprises a transistor having three terminals, where the first MTJ is coupled to a first terminal of the three terminals and a metallic separator coupling the first MTJ with the second MTJ. The first MTJ and the second MTJ are arranged in series.

Abstract: A memory device comprising an array of memory cells wherein each memory cell comprises a respective magnetic random access memory (MRAM) element, a respective gating transistor, and a common wordline coupled to gates of gating transistors of said array of memory cells. The memory device further comprises a common source line coupled to sources of said gating transistors, wherein said common source line is routed perpendicular to said plurality of bit lines within said array of memory cells, and a plurality of bit lines which are routed parallel to each other and connected to the drains of said gating transistors, wherein each bit line is associated with a respective memory cell of said array of memory cells.

Abstract: A memory device comprising an array of memory cells wherein each memory cell includes a respective magnetic random access memory (MRAM) element, and a respective gating transistor. A plurality of bit lines are routed parallel to each other, wherein each bit line is associated with a respective memory cell of the array of memory cells. A common word line is coupled to gates of gating transistors of the array of memory cells. A common source line is coupled to sources of the gating transistors, wherein the common source line is routed perpendicular to the plurality of bit lines within the array of memory cells. A sacrificial circuit element is coupled to a sacrificial bit line, coupled to the common word line and coupled to the common source line, wherein the sacrificial circuit element is operable to provide a desired voltage to the common source line wherein the desired voltage originates from the sacrificial bit line.

Abstract: Dynamic redundancy buffers for use with a device are disclosed. The dynamic redundancy buffers allow a memory array of the device to be operated with high write error rate (WER). A first level redundancy buffer (e1 buffer) is couple to the memory array. The e1 buffer may store data words that have failed verification or have not been verified. The e1 buffer may transfer data words to another dynamic redundancy buffer (e2 buffer). The e1 buffer may transfer data words that have failed to write to a memory array after a predetermined number of re-write attempts. The e1 buffer may also transfer data words upon power down.

Abstract: Dynamic redundancy registers for use with a device are disclosed. The dynamic redundancy registers allow a memory bank of the device to be operated with high write error rate (WER). A first level redundancy register (e1 register) is couple to the memory bank. The e1 register may store data words that have failed verification or have not been verified. The e1 register may transfer data words to another dynamic redundancy register (e2 register). The e1 register may transfer data words that have failed to write to a memory bank after a predetermined number of re-write attempts. The e1 register may also transfer data words upon power down.

Abstract: Methods and structures useful for magnetoresistive random-access memory (MRAM) are disclosed. The MRAM device has a magnetic tunnel junction stack having a significantly improved performance of the free layer in the magnetic tunnel junction structure. The MRAM device utilizes an in-plane polarization magnetic layer and a perpendicular MTJ in conjugation with a alternating current precharge and a programming current pulse that comprises an alternating perturbation frequency and a direct current.

Abstract: A method of writing data into a memory device is disclosed. The method comprises utilizing a pipeline to process write operations of a first plurality of data words addressed to a memory bank. The method further comprises writing a second plurality of data words and associated memory addresses into a cache memory, and wherein each data word of the second plurality of data words is associated with a pending operation. Additionally, the method comprises detecting a power up signal and responsive to the power up signal, transferring the second plurality of data words and associated memory addresses from the secure memory storage area to the cache memory. Finally, responsive to the transferring, and before the memory device is powered up, the method comprises processing the second plurality of data words and associated memory addresses from the cache memory to the pipeline for writing data to the memory bank during power up.

Abstract: A device includes an array of memory cells, input/output lines coupled to the memory cells, and sense amplifiers coupled to the input/output lines. Each sense amplifier is associated with a respective input/output line. The device also includes trim circuits. Each trim circuit is associated with and coupled to a respective sense amplifier. Each sense amplifier receives a respective reference voltage that allows the sense amplifier to sense a bit value of an addressed memory cell. Each trim circuit is operable for compensating for variations in the reference voltage used by the respective sense amplifier.

Abstract: A magnetic storage device is provided. The magnetic storage device comprises a magnetic memory cell, which includes two or more magnetic tunnel junctions (MTJs), including a first MTJ having a first magnetic characteristic and a first electrical characteristic and a second MTJ has a second magnetic characteristic and a second electrical characteristic, wherein the first magnetic characteristic is distinct from the second magnetic characteristic. The magnetic memory cell further comprises a bottom electrode and a top electrode, wherein the two or more MTJs are arranged between the top and bottom electrode in parallel with respect to each other. The magnetic storage device further comprises readout circuitry coupled to the bottom electrode or the top electrode of the magnetic memory cell and write circuitry coupled to the bottom electrode or the top electrode of the magnetic memory cell.

Abstract: An advantageous write verify operation for bipolar memory devices is disclosed. The verify operation is performed under the same bias conditions as the write operation. Thus, the verify operation reduces disturb conditions caused when verify operation is performed in opposite bias to write operation. The advantageous write verify operation may be performed with control logic on source and bit lines. In another embodiment, the advantageous write operation is performed with mux coupled to control logic. The mux determines whether verify (0) or verify (1) operation should be performed based on data in a program latch. Moreover, the mux may select bias conditions for read operations based on a register bit. Trim circuits optionally provide guard banding and modify reference voltages for verify operations performed in opposite polarity to normal read operation.

Abstract: A memory device includes a write port, a read port, source lines, bit lines, and word lines orthogonal to the bit lines. The memory device also includes memory cells that can be arrayed in columns that are parallel to the bit lines and in rows that are orthogonal to the bit lines. The memory cells are configured so that a write by the write port to a first memory cell in a column associated with (e.g., parallel to) a first bit line and a read by the read port of a second memory cell in a column associated with (e.g., parallel to) a second, different bit line can be performed during overlapping time periods (e.g., at a same time or during a same clock cycle).

Abstract: A memory device comprising an array of memory cells wherein each memory cell comprises a respective magnetic random access memory (MRAM) element, a respective gating transistor, and a common wordline coupled to gates of gating transistors of said array of memory cells. The memory device further comprises a common source line coupled to sources of said gating transistors, wherein said common source line is routed perpendicular to said plurality of bit lines within said array of memory cells, and a plurality of bit lines which are routed parallel to each other and connected to the drains of said gating transistors, wherein each bit line is associated with a respective memory cell of said array of memory cells.

Abstract: A magnetic storage device is provided. The magnetic storage device comprises a magnetic memory cell, which includes two or more magnetic tunnel junctions (MTJs), including a first MTJ having a first magnetic characteristic and a first electrical characteristic and a second MTJ has a second magnetic characteristic and a second electrical characteristic, wherein the first magnetic characteristic is distinct from the second magnetic characteristic. The magnetic memory cell further comprises a bottom electrode and a top electrode, wherein the two or more MTJs are arranged between the top and bottom electrode in parallel with respect to each other. The magnetic storage device further comprises readout circuitry coupled to the bottom electrode or the top electrode of the magnetic memory cell and write circuitry coupled to the bottom electrode or the top electrode of the magnetic memory cell.

Abstract: An memory device comprising an array of memory cells wherein each memory cell includes a respective magnetic random access memory (MRAM) element, and a respective gating transistor. A plurality of bit lines are routed parallel to each other, wherein each bit line is associated with a respective memory cell of the array of memory cells. A common word line is coupled to gates of gating transistors of the array of memory cells. A common source line is coupled to sources of the gating transistors, wherein the common source line is routed perpendicular to the plurality of bit lines within the array of memory cells. A first circuit provides a first voltage on an addressed bit line of the plurality of bit lines during a write cycle, wherein the addressed bit line corresponds to an addressed memory cell.

Abstract: A memory device comprising an array of memory cells wherein each memory cell includes a respective magnetic random access memory (MRAM) element, and a respective gating transistor. A plurality of bit lines are routed parallel to each other, wherein each bit line is associated with a respective memory cell of the array of memory cells. A common word line is coupled to gates of gating transistors of the array of memory cells. A common source line is coupled to sources of the gating transistors, wherein the common source line is routed perpendicular to the plurality of bit lines within the array of memory cells. A sacrificial circuit element is coupled to a sacrificial bit line, coupled to the common word line and coupled to the common source line, wherein the sacrificial circuit element is operable to provide a desired voltage to the common source line wherein the desired voltage originates from the sacrificial bit line.

Abstract: Methods and structures useful for magnetoresistive random-access memory (MRAM) are disclosed. The MRAM device has a magnetic tunnel junction stack having a significantly improved performance of the free layer in the magnetic tunnel junction structure. The MRAM device utilizes an in-plane polarization magnetic layer and a perpendicular MTJ in conjugation with a alternating current precharge and a programming current pulse that comprises an alternating perturbation frequency and a direct current.

Abstract: A device includes an array of memory cells, input/output lines coupled to the memory cells, and sense amplifiers coupled to the input/output lines. Each sense amplifier is associated with a respective input/output line. The device also includes trim circuits. Each trim circuit is associated with and coupled to a respective sense amplifier. Each sense amplifier receives a respective reference voltage that allows the sense amplifier to sense a bit value of an addressed memory cell. Each trim circuit is operable for compensating for variations in the reference voltage used by the respective sense amplifier.

Abstract: A memory cell apparatus is provided. The apparatus comprises two or more magnetic tunnel junctions (MTJs), including a first MTJ having a first magnetic characteristic and a first electrical characteristic and a second MTJ having a second magnetic characteristic and a second electrical characteristic. The first magnetic characteristic is distinct from the second magnetic characteristic. The apparatus further comprises a transistor having three terminals, where the first MTJ is coupled to a first terminal of the three terminals and a metallic separator coupling the first MTJ with the second MTJ. The first MTJ and the second MTJ are arranged in series.