Abstract: An analog read circuit measures the resistance of each of a plurality of bits in an array of resistive memory elements. Data stored within a latch determines whether to selectively enable the analog read circuit. In an alternate embodiment, a sense amplifier is coupled to the latch and the array, and the data stored in the latch determines whether to selectively enable the sense amplifier.

Abstract: An analog read circuit measures the resistance of each of a plurality of bits in an array of resistive memory elements. Data stored within a latch determines whether to selectively enable the analog read circuit. In an alternate embodiment, a sense amplifier is coupled to the latch and the array, and the data stored in the latch determines whether to selectively enable the sense amplifier.

Abstract: A random access memory architecture includes a first series connected pair of memory elements (202, 206, 302, 306, 402, 404) having a first resistance and a second series connected pair of memory elements (204, 208, 304, 308, 406, 408) having a second resistance coupled in parallel with the first series connected pair of memory elements, wherein a current flows in the first direction through both of the first and second series connected pair of memory elements. A sense amplifier (14) is coupled to an array (16) of MRAM cells (77), each including a memory element, and includes a voltage bias portion (12), the voltage bias portion including the first and second series connected pair of memory elements. The memory elements may be, for example, magnetic tunnel junctions.

Abstract: A random access memory architecture includes a first series connected pair of memory elements (202, 206, 302, 306, 402, 404) having a first resistance and a second series connected pair of memory elements (204, 208, 304, 308, 406, 408) having a second resistance coupled in parallel with the first series connected pair of memory elements, wherein a current flows in the first direction through both of the first and second series connected pair of memory elements. A sense amplifier (14) is coupled to an array (16) of MRAM cells (77), each including a memory element, and includes a voltage bias portion (12), the voltage bias portion including the first and second series connected pair of memory elements. The memory elements may be, for example, magnetic tunnel junctions.

Abstract: A memory device, such an MRAM device, includes self-healing reference bits (104) associated with a set of array bits (102). The memory performs an error detection step (e.g., using an error-correction coding (ECC) algorithm, to detect the presence of a set of errors within the data bits. One of the reference bits (104) is toggled to a different state if an error count is greater than a predetermined threshold. If the set of errors remains unchanged when subsequently read, the reference bit (104) is toggled back to its original state.

Abstract: A non-volatile storage element disposed at an integrated circuit is disclosed. The storage element includes a first resistive element having a first magnetic tunnel junction (MTJ) element, a first node coupled to the first resistive element, a second resistive element having of a second MTJ element, a second node coupled to the second resistive element, a sense amplifier having a first input coupled to the first node, a second input coupled to the second node, and an output, and a first conductor disposed to conduct a first current to set the first resistive element to a first resistive value and the second resistive element to a second resistive value different from the first resistive value.

Abstract: A controller for a toggle memory that performs burst writes by reading a group of bits in the toggle memory and comparing each received data word of the burst with a portion of the group to determine which cells to toggle to enter the data of the burst write in the toggle memory. In one example the toggle memory includes magnetoresistive random access memory (MRAM) with cells using multiple free magnetic layers that toggle between states when subjected to a sequence of magnetic pulses along two directions. Because one read is performed for a group of data of the burst, the time needed to perform the burst write is reduced.

Abstract: An antifuse circuit provides on a per bit basis a signal that indicates whether an MTJ (magnetic tunnel junction) antifuse has been previously programmed to a low resistance state in response to a program voltage. A sense amplifier provides the resistance state signal. A plurality of reference magnetic tunnel junctions are coupled in parallel and to the sense amplifier, each having a resistance within a range to provide a collective resistance that can be determined by the sense amplifier to differ from each resistance state of the MTJ antifuse. A write circuit selectively provides a current sufficient to create the program voltage when the write circuit is enabled to program the antifuse magnetic tunnel junction. Upon detecting a change in resistance in the MTJ antifuse, the write circuit reduces current supplied to the antifuse. Multiple antifuses may be programmed concurrently. Gate oxide thicknesses of transistors are adjusted for optimal performance.

Abstract: A non-volatile storage element disposed at an integrated circuit is disclosed. The storage element includes a first resistive element having a first magnetic tunnel junction (MTJ) element, a first node coupled to the first resistive element, a second resistive element having of a second MTJ element, a second node coupled to the second resistive element, a sense amplifier having a first input coupled to the first node, a second input coupled to the second node, and an output, and a first conductor disposed to conduct a first current to set the first resistive element to a first resistive value and the second resistive element to a second resistive value different from the first resistive value.

Abstract: A memory circuit includes a sense amplifier in which a single reference signal is compared to two data signals from two memory cells. The reference signal is generated from the combination of memory cells in opposite logic states. The data signal capacitance is matched to the reference signal capacitance. With reduced but matched capacitance both high speed and high sensitivity can be achieved.

Abstract: An antifuse circuit provides on a per bit basis a signal that indicates whether an MTJ (magnetic tunnel junction) antifuse has been previously programmed to a low resistance state in response to a program voltage. A sense amplifier provides the resistance state signal. A plurality of reference magnetic tunnel junctions are coupled in parallel and to the sense amplifier, each having a resistance within a range to provide a collective resistance that can be determined by the sense amplifier to differ from each resistance state of the MTJ antifuse. A write circuit selectively provides a current sufficient to create the program voltage when the write circuit is enabled to program the antifuse magnetic tunnel junction. Upon detecting a change in resistance in the MTJ antifuse, the write circuit reduces current supplied to the antifuse. Multiple antifuses may be programmed concurrently. Gate oxide thicknesses of transistors are adjusted for optimal performance.

Abstract: A magnetoresistive random access memory (MRAM) (900) that is susceptible to a residual magnetic field is compensated during a write operation. A first magnetic field (208) is applied to a memory cell during a first time period, the first magnetic field having a first direction (y) and a first magnitude. A second magnetic field (212) is applied to the memory cell during a second time period and having a second direction (x) and a second magnitude. A third magnetic field (702) is applied to the memory cell during a third time period, wherein the third time period overlaps at least a portion of the second time period, the third magnetic field having a third direction (?y) which is approximately opposite to the first direction of the first magnetic field. Currents are selectively applied through conductors in the memory cell to apply the three magnetic fields.

Abstract: A magnetoresistive random access memory (MRAM) has separate read and write paths. This reduces the peripheral circuitry by not requiring switching between read and write functions on a particular line. By having the paths dedicated to either read signals or write signals, the voltage levels can be optimized for these functions. The select transistors, which are part of only the read function, may be of the low-voltage type because they do not have to receive the relatively higher voltages of the write circuitry. Similarly, the write voltages do not have to be degraded to accommodate the lower-voltage type transistors. The size of the overall memory is kept efficiently small while improving performance. The memory cells are grouped so that adjacent to groups are coupled to a common global bit line which reduces the space required for providing the capacitance-reducing group approach to memory cell selection.

Abstract: An MRAM is provided that minimizes the limits in MRAM density imposed by utilization of an isolation or select device in each memory cell. In addition, methods are provided for reading an MTJ in a ganged memory cell of the MRAM. The method includes determining an electrical value that is at least partially associated with a resistance of a ganged memory cell of the MRAM. The MTJ in the ganged memory cell is toggled and a second electrical value, which is at least partially associated with the resistance of the ganged memory cell, is determined after toggling the MTJ. Once the electrical value prior to the toggling and after the toggling is determined, the difference between the two electrical values is analyzed to determine the value of the MTJ.

Abstract: A magnetoresistive random access memory (MRAM) has separate read and write paths. This reduces the peripheral circuitry by not requiring switching between read and write functions on a particular line. By having the paths dedicated to either read signals or write signals, the voltage levels can be optimized for these functions. The select transistors, which are part of only the read function, may be of the low-voltage type because they do not have to receive the relatively higher voltages of the write circuitry. Similarly, the write voltages do not have to be degraded to accommodate the lower-voltage type transistors. The size of the overall memory is kept efficiently small while improving performance. The memory cells are grouped so that adjacent to groups are coupled to a common global bit line which reduces the space required for providing the capacitance-reducing group approach to memory cell selection.

Abstract: A circuit provides a stress voltage to magnetic tunnel junctions (MTJs), which comprise the storage elements of a magnetoresitive random access memory (MRAM), during an accelerated life test of the MRAM. The stress voltage is selected to provide a predetermined acceleration of aging compared to normal operation. A source follower circuit is used to apply a stress voltage to a subset of the memory cells at given point in time during the life test. The stress voltage is maintained at the desired voltage by a circuit that mocks the loading characteristics of the portion of the memory array being stressed. The result is a closely defined voltage applied to the MTJs so that the magnitude of the acceleration is well defined for all of the memory cells.

Abstract: An MRAM architecture is provided that reduces the number of isolation transistors. The MRAM architecture includes magnetoresistive memory cells that are electrically coupled to form a ganged memory cell. The magnetoresistive memory cells of the ganged memory cell are formed with Magnetic Tunnel Junctions (MTJs) and formed without isolation devices, such as isolation transistors, and a programming line and a bit line are adjacent to each of the magnetoresistive memory cells. Preferably, the magnetoresistive memory cells of the ganged memory cell only include MTJs, and a programming line and a bit line are adjacent to each of the magnetoresistive memory cells.

Abstract: A circuit and method for counteracting stray magnetic fields generated by write currents in an MRAM memory reuses the write current in adjoining write columns via a current redistribution bus at a first end of the write lines. A first switch connected to a second end of each write line controls the write current in the write line. If the first switch is not conductive, a second switch connects the second end of the write line to a reference voltage terminal. For write lines located at sub-array edges, a predetermined amount of spacing may be used to avoid magnetic field disturbance in an adjacent sub-array. The number of spaces required can be minimized by specific activation of write line switches.

Abstract: A write driver uses a reference current that is reflected to a driver circuit by a voltage. The driver circuit is sized in relation to the device that provides the voltage so that the current through the driver is a predetermined multiple of the reference current. This voltage is coupled to the driver circuit through a switch. The switch is controlled so that the driver circuit only receives the voltage when the write line is to have write current through it as determined by a decoder responsive to an address. The driver is affirmatively disabled when the write line is intended to not have current passing through it. As an enhancement to overcome ground bounce due to high currents, the input to the driver can be capacitively coupled to the ground terminal that experiences such bounce. Additional enhancements provide benefits in amplitude and edge rate control.

Abstract: A sense amplifier (1300, 1500) is provided for sensing the state of a toggling type magnetoresistive random access memory (MRAM) cell without using a reference. The sense amplifier (1300, 1500) employs a sample-and-hold circuit (1336, 1508) combined with a current-to-voltage converter (1301, 1501), gain circuit (1303), and cross-coupled latch (1305, 1503) to sense the state of a bit. The sense amplifier (1300, 1500), first senses and holds a first state of the cell. The cell is toggled to a second state. Then, the sense amplifier (1300, 1500) compares the first state to the second state to determine the first state of a toggling type memory cell.