Patent application number | Description | Published |
20100008134 | TRANSMISSION GATE-BASED SPIN-TRANSFER TORQUE MEMORY UNIT - A transmission gate-based spin-transfer torque memory unit is described. The memory unit includes a magnetic tunnel junction data cell electrically coupled to a bit line and a source line. A NMOS transistor is in parallel electrical connection with a PMOS transistor and they are electrically connected with the source line and the magnetic tunnel junction data cell. The magnetic tunnel junction data cell is configured to switch between a high resistance state and a low resistance state by passing a polarized write current through the magnetic tunnel junction data cell. The PMOS transistor and the NMOS transistor are separately addressable so that a first write current in a first direction flows through the PMOS transistor and a second write current in a second direction flows through the NMOS transistor. | 01-14-2010 |
20100032778 | MAGNETIC MEMORY WITH SEPARATE READ AND WRITE PATHS - Magnetic memory having separate read and write paths is disclosed. The magnetic memory unit includes a ferromagnetic strip having a first end portion with a first magnetization orientation, an opposing second end portion with a second magnetization orientation, and a middle portion between the first end portion and the second end portion, the middle portion having a free magnetization orientation. The first magnetization orientation opposes the second magnetization orientation. A tunneling barrier separates a magnetic reference layer from the middle portion forming a magnetic tunnel junction. A bit line is electrically coupled to the second end portion. A source line is electrically coupled to the first end portion and a read line is electrically coupled to the magnetic tunnel junction. | 02-11-2010 |
20100058125 | DATA DEVICES INCLUDING MULTIPLE ERROR CORRECTION CODES AND METHODS OF UTILIZING - A method of utilizing at least one block of data, wherein the at least one block of data includes a plurality of cells for storing data and at least one error flag bit, the method including: scanning the block of data for errors; determining the error rate of the block of data; and applying an error correction code to data being read from or written to a cell within the at least one block of data, wherein the error correction code is applied based on the error rate, wherein a weak error correction code is applied when the error rate is below an error threshold, and a strong error correction code is applied when the error rate is at or above the error threshold. | 03-04-2010 |
20100067281 | VARIABLE WRITE AND READ METHODS FOR RESISTIVE RANDOM ACCESS MEMORY - Variable write and read methods for resistance random access memory (RRAM) are disclosed. The methods include initializing a write sequence and verifying the resistance state of the RRAM cell. If a write pulse is needed, then two or more write pulses are applied through the RRAM cell to write the desired data state to the RRAM cell. Each subsequent write pulse has substantially the same or greater write pulse duration. Subsequent write pulses are applied to the RRAM cell until the RRAM cell is in the desired data state or until a predetermined number of write pulses have been applied to the RRAM cell. A read method is also disclosed where subsequent read pulses are applied through the RRAM cell until the read is successful or until a predetermined number of read pulses have been applied to the RRAM cell. | 03-18-2010 |
20100067282 | MEMORY ARRAY WITH READ REFERENCE VOLTAGE CELLS - The present disclosure relates to memory arrays with read reference voltage cells. In particular the present disclosure relates to variable resistive memory cell apparatus and arrays that include a high resistance state reference memory cell and a low resistance state reference memory cell that provides a reliable average reference voltage on chip to compare to a read voltage of a selected memory cell and determine if the selected memory cell is in the high resistance state or low resistance state. These memory arrays are particularly suitable for use with spin-transfer torque memory cells and resolves many systematic issues related to generation of a reliable reference voltage. | 03-18-2010 |
20100091546 | HIGH DENSITY RECONFIGURABLE SPIN TORQUE NON-VOLATILE MEMORY - One time programmable memory units include a magnetic tunnel junction cell electrically coupled to a bit line and a word line. The magnetic tunnel junction cell is pre-programmed to a first resistance state, and is configured to switch only from the first resistance state to a second resistance state by passing a voltage across the magnetic tunnel junction cell. In some embodiments, a transistor is electrically coupled between the magnetic tunnel junction cell and the word line or the bit line. In other embodiments, a device having a rectifying switching characteristic, such as a diode or other non-ohmic device, is electrically coupled between the magnetic tunnel junction cell and the word line or the bit line. Methods of pre-programming the one time programmable memory units and reading and writing to the units are also disclosed. | 04-15-2010 |
20100091562 | TEMPERATURE DEPENDENT SYSTEM FOR READING ST-RAM - A memory device that includes at least one memory cell, the memory cell includes: a magnetic tunnel junction (MTJ); and a transistor, wherein the transistor is operatively coupled to the MTJ; a bit line; a source line; and a word line, wherein the memory cell is operatively coupled between the bit line and the source line, and the word line is operatively coupled to the transistor; a temperature sensor; and control circuitry, wherein the temperature sensor is operatively coupled to the control circuitry and the control circuitry and temperature sensor are configured to control a current across the memory cell. | 04-15-2010 |
20100095050 | COMPUTER MEMORY DEVICE WITH STATUS REGISTER - Method and apparatus for operating a memory device with a status register. In some embodiments, the memory device has a plurality of individually programmable non-volatile memory cells comprised of at least a resistive sense memory. The memory device engages an interface and maintains a status register in some embodiments by logging at least an error or busy signal during data transfer operations. | 04-15-2010 |
20100117121 | MIRRORED-GATE CELL FOR NON-VOLATILE MEMORY - A memory comprising at least one memory cell operationally connected to a bit line, a source line and a word line. The memory cell comprises a substrate having a first source contact, a second source contact, and a bit contact between the first source contact and the second source contact, a first transistor gate electrically connecting the first source contact and the bit contact and a second transistor gate electrically connecting the bit contact and the second source contact. The word line electrically connects the first transistor gate to the second transistor gate. | 05-13-2010 |
20100118602 | DOUBLE SOURCE LINE-BASED MEMORY ARRAY AND MEMORY CELLS THEREOF - A memory array includes a plurality of first and second source, lines overlapping a plurality of bit lines, and a plurality of magnetic storage elements, each coupled to a corresponding first and second source line and to a corresponding bit line. Current may be driven, in first and second directions, through each magnetic element, for example, to program the elements. Diodes may be incorporated to avert sneak paths in the memory array. A first diode may be coupled between each magnetic element and the corresponding first source line, the first diode being biased to allow read and write current flow through the magnetic element, from the corresponding first source line; and a second diode may be coupled between each magnetic element and the corresponding second source line, the second diode being reverse-biased to block read and write current flow through the magnetic element, from the corresponding second source line. | 05-13-2010 |
20100124352 | MICRO MAGNETIC DEVICE WITH MAGNETIC SPRING - A micro magnetic device having a body defining at least part of an enclosed chamber, the body comprising a first sidewall and a second sidewall. A pole comprising a soft magnetic material is within the chamber and an electrically conductive coil is positioned around the pole. A diaphragm is connected to the first sidewall and a permanent dipole magnet is connected to the second sidewall at a first end and to the diaphragm at a second end. The dipole magnet is offset centrally from the pole. The diaphragm may also be offset centrally from the first pole. The micro magnetic device may be made by MEMS or thin film techniques. | 05-20-2010 |
20100135066 | BIT LINE CHARGE ACCUMULATION SENSING FOR RESISTIVE CHANGING MEMORY - A memory array includes a plurality of magneto-resistive changing memory cells. Each resistive changing memory cell is electrically between a source line and a bit line and a transistor electrically between the resistive changing memory cell and the bit line. The transistor has a gate electrically between a source region and a drain region and the source region being electrically between the magneto-resistive changing memory cell and the gate. A word line is electrically coupled to the gate. A bit line charge accumulation sensing for magneto-resistive changing memory is also disclosed. | 06-03-2010 |
20100202191 | nvSRAM HAVING VARIABLE MAGNETIC RESISTORS - Non-volatile static random access memory (nvSRAM) that has a six transistor static random access memory (6T SRAM) cell electrically connected to a non-volatile random access memory (nvRAM) cell. The nvRAM cell has first and second variable magnetic resistors and first, second and third transistors. | 08-12-2010 |
20100207219 | SINGLE LINE MRAM - A magnetic memory device includes a first electrode separated from a second electrode by a magnetic tunnel junction. The first electrode provides a write current path along a length of the first electrode. The magnetic tunnel junction includes a free magnetic layer having a magnetization orientation that is switchable between a high resistance state magnetization orientation and a low resistance state magnetization orientation. The free magnetic layer is spaced from the first electrode a distance of less than 10 nanometers. A current passing along the write current path generates a magnetic field. The magnetic field switches the free magnetic layer magnetization orientation between a high resistance state magnetization orientation and a low resistance state magnetization orientation. | 08-19-2010 |
20100232211 | MEMORY ARRAY WITH READ REFERENCE VOLTAGE CELLS - The present disclosure relates to memory arrays with read reference voltage cells. In particular the present disclosure relates to variable resistive memory cell apparatus and arrays that include a high resistance state reference memory cell and a low resistance state reference memory cell that provides a reliable average reference voltage on chip to compare to a read voltage of a selected memory cell and determine if the selected memory cell is in the high resistance state or low resistance state. These memory arrays are particularly suitable for use with spin-transfer torque memory cells and resolves many systematic issues related to generation of a reliable reference voltage. | 09-16-2010 |
20100238712 | VARIABLE WRITE AND READ METHODS FOR RESISTIVE RANDOM ACCESS MEMORY - Variable write and read methods for resistance random access memory (RRAM) are disclosed. The methods include initializing a write sequence and verifying the resistance state of the RRAM cell. If a write pulse is needed, then two or more write pulses are applied through the RRAM cell to write the desired data state to the RRAM cell. Each subsequent write pulse has substantially the same or greater write pulse duration. Subsequent write pulses are applied to the RRAM cell until the RRAM cell is in the desired data state or until a predetermined number of write pulses have been applied to the RRAM cell. A read method is also disclosed where subsequent read pulses are applied through the RRAM cell until the read is successful or until a predetermined number of read pulses have been applied to the RRAM cell. | 09-23-2010 |
20100265749 | THREE DIMENSIONALLY STACKED NON VOLATILE MEMORY UNITS - A memory unit including a first transistor spanning a first transistor region in a first layer of the memory unit; a second transistor spanning a second transistor region in a second layer of the memory unit; a first resistive sense memory (RSM) cell spanning a first memory region in a third layer of the memory unit; and a second RSM cell spanning a second memory region in the third layer of the memory unit, wherein the first transistor is electrically coupled to the first RSM cell, and the second transistor is electrically coupled to the second RSM cell, wherein the second layer is between the first and third layers, wherein the first and second transistor have an transistor overlap region, and wherein the first memory region and the second memory region do not extend beyond the first transistor region and the second transistor region. | 10-21-2010 |
20110058409 | MRAM DIODE ARRAY AND ACCESS METHOD - A memory unit includes a magnetic tunnel junction data cell is electrically coupled to a bit line and a source line. The magnetic tunnel junction data cell is configured to switch between a high resistance state and a low resistance state by passing a write current through the magnetic tunnel junction data cell. A first diode is electrically between the magnetic tunnel junction data cell and the source line and a second diode is electrically between the magnetic tunnel junction data cell and the source line. The first diode and second diode are in parallel electrical connection, and having opposing forward bias directions. The memory unit is configured to be precharged to a specified precharge voltage level and the precharge voltage is less than a threshold voltage of the first diode and second diode. | 03-10-2011 |
20110089509 | MAGNETIC MEMORY WITH SEPARATE READ AND WRITE PATHS - Magnetic memory having separate read and write paths is disclosed. The magnetic memory unit includes a ferromagnetic strip having a first end portion with a first magnetization orientation, an opposing second end portion with a second magnetization orientation, and a middle portion between the first end portion and the second end portion, the middle portion having a free magnetization orientation. The first magnetization orientation opposes the second magnetization orientation. A tunneling barrier separates a magnetic reference layer from the middle portion forming a magnetic tunnel junction. A bit line is electrically coupled to the second end portion. A source line is electrically coupled to the first end portion and a read line is electrically coupled to the magnetic tunnel junction. | 04-21-2011 |
20110134682 | VARIABLE WRITE AND READ METHODS FOR RESISTIVE RANDOM ACCESS MEMORY - Variable write and read methods for resistance random access memory (RRAM) are disclosed. The methods include initializing a write sequence and verifying the resistance state of the RRAM cell. If a write pulse is needed, then two or more write pulses are applied through the RRAM cell to write the desired data state to the RRAM cell. Each subsequent write pulse has substantially the same or greater write pulse duration. Subsequent write pulses are applied to the RRAM cell until the RRAM cell is in the desired data state or until a predetermined number of write pulses have been applied to the RRAM cell. A read method is also disclosed where subsequent read pulses are applied through the RRAM cell until the read is successful or until a predetermined number of read pulses have been applied to the RRAM cell. | 06-09-2011 |
20110194330 | MEMORY ARRAY WITH READ REFERENCE VOLTAGE CELLS - The present disclosure relates to memory arrays with read reference voltage cells. In particular the present disclosure relates to variable resistive memory cell apparatus and arrays that include a high resistance state reference memory cell and a low resistance state reference memory cell that provides a reliable average reference voltage on chip to compare to a read voltage of a selected memory cell and determine if the selected memory cell is in the high resistance state or low resistance state. These memory arrays are particularly suitable for use with spin-transfer torque memory cells and resolves many systematic issues related to generation of a reliable reference voltage. | 08-11-2011 |
20110228598 | TRANSMISSION GATE-BASED SPIN-TRANSFER TORQUE MEMORY UNIT - A transmission gate-based spin-transfer torque memory unit is described. The memory unit includes a magnetic tunnel junction data cell electrically coupled to a bit line and a source line. A NMOS transistor is in parallel electrical connection with a PMOS transistor and they are electrically connected with the source line and the magnetic tunnel junction data cell. The magnetic tunnel junction data cell is configured to switch between a high resistance state and a low resistance state by passing a polarized write current through the magnetic tunnel junction data cell. The PMOS transistor and the NMOS transistor are separately addressable so that a first write current in a first direction flows through the PMOS transistor and a second write current in a second direction flows through the NMOS transistor. | 09-22-2011 |
20120037875 | MIRRORED-GATE CELL FOR NON-VOLATILE MEMORY - A memory comprising at least one memory cell operationally connected to a bit line, a source line and a word line. The memory cell comprises a substrate having a first source contact, a second source contact, and a bit contact between the first source contact and the second source contact, a first transistor gate electrically connecting the first source contact and the bit contact and a second transistor gate electrically connecting the bit contact and the second source contact. The word line electrically connects the first transistor gate to the second transistor gate. | 02-16-2012 |
20120039113 | THREE DIMENSIONALLY STACKED NON VOLATILE MEMORY UNITS - A memory unit including a first transistor spanning a first transistor region in a first layer of the memory unit; a second transistor spanning a second transistor region in a second layer of the memory unit; a first resistive sense memory (RSM) cell spanning a first memory region in a third layer of the memory unit; and a second RSM cell spanning a second memory region in the third layer of the memory unit, wherein the first transistor is electrically coupled to the first RSM cell, and the second transistor is electrically coupled to the second RSM cell, wherein the second layer is between the first and third layers, wherein the first and second transistor have an transistor overlap region, and wherein the first memory region and the second memory region do not extend beyond the first transistor region and the second transistor region. | 02-16-2012 |
20120230093 | TRANSMISSION GATE-BASED SPIN-TRANSFER TORQUE MEMORY UNIT - A transmission gate-based spin-transfer torque memory unit is described. The memory unit includes a magnetic tunnel junction data cell electrically coupled to a bit line and a source line. A NMOS transistor is in parallel electrical connection with a PMOS transistor and they are electrically connected with the source line and the magnetic tunnel junction data cell. The magnetic tunnel junction data cell is configured to switch between a high resistance state and a low resistance state by passing a polarized write current through the magnetic tunnel junction data cell. The PMOS transistor and the NMOS transistor are separately addressable so that a first write current in a first direction flows through the PMOS transistor and a second write current in a second direction flows through the NMOS transistor. | 09-13-2012 |
20120230094 | BIT LINE CHARGE ACCUMULATION SENSING FOR RESISTIVE CHANGING MEMORY - A memory array includes a plurality of magneto-resistive changing memory cells. Each resistive changing memory cell is electrically between a source line and a bit line and a transistor electrically between the resistive changing memory cell and the bit line. The transistor has a gate electrically between a source region and a drain region and the source region being electrically between the r magneto-resistive changing memory cell and the gate. A word line is electrically coupled to the gate. A bit line charge accumulation sensing for magneto-resistive changing memory is also disclosed. | 09-13-2012 |
20130003448 | MRAM DIODE ARRAY AND ACCESS METHOD - A memory unit includes a magnetic tunnel junction data cell is electrically coupled to a bit line and a source line. The magnetic tunnel junction data cell is configured to switch between a high resistance state and a low resistance state by passing a write current through the magnetic tunnel junction data cell. A first diode is electrically between the magnetic tunnel junction data cell and the source line and a second diode is electrically between the magnetic tunnel junction data cell and the source line. The first diode and second diode are in parallel electrical connection, and having opposing forward bias directions. The memory unit is configured to be precharged to a specified precharge voltage level and the precharge voltage is less than a threshold voltage of the first diode and second diode. | 01-03-2013 |
20140015075 | MAGNETIC MEMORY WITH SEPARATE READ AND WRITE PATHS - Magnetic memory having separate read and write paths is disclosed. The magnetic memory unit includes a ferromagnetic strip having a first end portion with a first magnetization orientation, an opposing second end portion with a second magnetization orientation, and a middle portion between the first end portion and the second end portion, the middle portion having a free magnetization orientation. The first magnetization orientation opposes the second magnetization orientation. A tunneling barrier separates a magnetic reference layer from the middle portion forming a magnetic tunnel junction. A bit line is electrically coupled to the second end portion. A source line is electrically coupled to the first end portion and a read line is electrically coupled to the magnetic tunnel junction. | 01-16-2014 |