Claims
- 1. A memory device comprising memory cells, access lines, and support electronics for facilitating access to information stored in the memory cells via the access lines, both the memory cells and the support electronics comprising multi-layer thin film structures exhibiting giant magnetoresistance.
- 2. The memory device of claim 1 wherein each of the memory cells comprises:
a plurality of magnetic layers, at least one of the magnetic layers being for magnetically storing one bit of information; a plurality of the access lines integrated with the plurality of magnetic layers and configured such that the bit of information may be accessed using selected ones of the plurality of access lines and the giant magnetoresistive effect; and at least one keeper layer; wherein the magnetic layers, the access lines, and the at least one keeper layer form a substantially closed flux structure.
- 3. The memory device of claim 2 wherein some of the plurality of magnetic layers comprise cobalt.
- 4. The memory device of claim 2 wherein some of the plurality of magnetic layers comprises permalloy.
- 5. The memory device of claim 2 wherein some of the plurality of access lines comprise copper.
- 6. The memory device of claim 2 wherein some of the plurality of access lines comprise multi-layer lines.
- 7. The memory device of claim 2 wherein each of the memory cells comprises a dibit memory cell, the plurality of magnetic layers comprising two storage layers.
- 8. The memory device of claim 7 wherein the two storage layers and the plurality of access lines are configured to read the bits of information destructively.
- 9. The memory device of claim 7 wherein the two storage layers and the plurality of access lines are configured to read the bits of information nondestructively.
- 10. The memory device of claim 2 wherein each of the memory cells comprises a three bit memory cell, the plurality of magnetic layers comprising three storage layers.
- 11. The memory device of claim 10 wherein the three storage layers and the plurality of access lines are configured to read the bits of information destructively.
- 12. The memory device of claim 10 wherein the three storage layers and the plurality of access lines are configured to read the bits of information nondestructively.
- 13. The memory device of claim 2 wherein each of the memory cells comprises a four bit memory cell, the plurality of magnetic layers comprising four storage layers.
- 14. The memory device of claim 13 wherein the four storage layers and the plurality of access lines are configured to read the bits of information destructively.
- 15. The memory device of claim 13 wherein the four storage layers and the plurality of access lines are configured to read the bits of information nondestructively.
- 16. The memory device of claim 2 wherein each of the memory cells comprises a single bit memory cell, the plurality of magnetic layers comprising one storage layer.
- 17. The memory device of claim 16 wherein the storage layer and the plurality of access lines are configured to read the bit of information destructively.
- 18. The memory device of claim 16 wherein the storage layer and the plurality of access lines are configured to read the bit of information nondestructively.
- 18. The memory device of claim 1 wherein all of the memory cells and support electronics comprise the multi-layer thin film structures exhibiting giant magnetoresistance, the memory device therefore comprising an all metal memory device.
- 19. The memory device of claim 1 wherein only selected ones of the memory cells and support electronics comprise the multi-layer thin film structures exhibiting giant magnetoresistance.
- 20. The memory device of claim 1 wherein the support electronics comprise a plurality of access line selection matrices for selecting selected ones of the plurality of access lines.
- 21. The memory device of claim 20 wherein each selection matrix comprises an array of transpinnors, each transpinnor comprising a network of the multi-layer thin film structures, and at least one of the access lines inductively coupled to at least one of the thin film structures for applying at least one magnetic field thereto, each transpinnor generating an output when the network is resistively unbalanced.
- 22. The memory device of claim 1 wherein the support electronics comprise a plurality of transpinnors, each transpinnor comprising a network of the multi-layer thin film structures, and at least one conductor inductively coupled to at least one of its thin film structures for applying at least one magnetic field thereto, each transpinnor generating an output when the network is resistively unbalanced.
- 23. The memory device of claim 22 wherein selected ones of the transpinnors are configured as amplifiers for amplifying signals on selected ones of the access lines.
- 24. The memory device of claim 22 wherein selected ones of the transpinnors are configured as differential amplifiers for resistively balancing pairs of the access lines.
- 25. The memory device of claim 22 wherein selected subsets of the transpinnors are configured as a selection matrix for facilitating selection of specific ones of the access lines.
- 26. The memory device of claim 1 wherein the support electronics comprise a plurality of configurable resistive elements.
- 27. The memory device of claim 26 wherein each configurable resistive element comprises at least one high coercivity layer and at least one low coercivity layer, a resistance value associated with each configurable resistive element being configurable by at least partially switching a first magnetization vector associated with the high coercivity layer.
- 28. A memory device comprising memory cells, access lines, and support electronics for facilitating access to information stored in the memory cells using the access lines, both the memory cells and the support electronics comprising multi-layer thin film structures exhibiting giant magnetoresistance, each of the memory cells comprising a plurality of magnetic layers at least one which is for magnetically storing one bit of information, wherein a plurality of the access lines are integrated with the plurality of magnetic layers in each memory cell and configured such that the bit of information may be accessed using selected ones of the plurality of access lines and the giant magnetoresistive effect, and wherein the support electronics comprise a plurality of transpinnors, each transpinnor comprising a network of the multi-layer thin film structures, and at least one conductor inductively coupled to at least one of its thin film structures for applying at least one magnetic field thereto, each transpinnor generating an output when the network is resistively unbalanced.
- 29. A method for making a solid-state memory device comprising:
forming memory cells comprising first multi-layer thin film structures exhibiting giant magnetoresistance; forming access lines which are integrated with the memory cells; and forming support electronics for facilitating access to information stored in the memory cells via the access lines, the support electronics comprising second multi-layer thin film structures exhibiting giant magnetoresistance.
- 30. A method for making a solid-state memory device comprising memory cells, access lines, and support electronics, the memory comprising:
forming the memory cells, each of the memory cells comprising a plurality of magnetic layers at least one which is for magnetically storing one bit of information, wherein a plurality of the access lines are integrated with the plurality of magnetic layers in each memory cell and configured such that the bit of information may be accessed using selected ones of the plurality of access lines and the giant magnetoresistive effect; and forming the support electronics including a plurality of transpinnors, each transpinnor comprising a network of multi-layer thin film structures exhibiting giant magnetoresistance, and at least one conductor inductively coupled to at least one of its thin film structures for applying at least one magnetic field thereto, each transpinnor generating an output when its network is resistively unbalanced.
- 31. A memory architecture associated with a processor, the memory architecture comprising system memory for facilitating execution of computer program instructions by the processor, and mass memory for storing information which may be accessed by the processor, the system memory and the mass memory comprising first and second random access memories, respectively, which include first and second arrays of memory cells, respectively, each memory cell in the first and second arrays comprising a multi-layer thin film structure exhibiting giant magnetoresistance.
- 32. The memory architecture of claim 31 further comprising cache memory for facilitating execution of computer program instructions by the processor, the cache memory comprising a third random access memory which includes a third array of memory cells, the memory cells in the third array comprising additional multi-layer thin film structures exhibiting giant magnetoresistance.
- 33. The memory architecture of claim 31 further comprising read-only memory for storing computer program instructions for execution by the processor, the read-only memory comprising a third random access memory which includes a third array of memory cells, the memory cells in the third array comprising additional multi-layer thin film structures exhibiting giant magnetoresistance.
- 34. The memory architecture of claim 31 wherein the processor is part of an ISA system having an ISA bus, the mass memory being for coupling to the ISA bus.
- 35. The memory architecture of claim 31 wherein the processor is part of an EISA system having an EISA bus, the mass memory being for coupling to the EISA bus.
- 36. The memory architecture of claim 31 wherein the processor is part of a PCMCIA system having a PCMCIA bus, the mass memory being for coupling to the PCMCIA bus.
- 37. The memory architecture of claim 31 wherein the processor is part of a system kernel, the system memory being part of a first memory subsystem for coupling to the system kernel, and the mass memory being part of a second memory subsystem for coupling to the system kernel.
- 38. The memory architecture of claim 31 wherein the processor is part of a system kernel, the system memory and the mass memory both being part of a single memory subsystem for coupling to the system kernel.
- 39. The memory architecture of claim 31 wherein at least one of the system memory and mass memory are contained in a plug-in module which may be plugged into a processing system of which the processor is a part.
- 40. The memory architecture of claim 39 the plug-in module comprises a hard card for connecting to an ISA bus associated with the processing system.
- 41. The memory architecture of claim 39 the plug-in module comprises a hard card for connecting to an EISA bus associated with the processing system.
- 42. The memory architecture of claim 39 the plug-in module comprises a PCMCIA card for connecting to PCMCIA bus associated with the processing system.
- 43. The memory architecture of claim 39 wherein both the system memory and the mass memory are contained in the plug-in module.
- 44. The memory architecture of claim 39 wherein only one of the system memory and the mass memory are contained in the plug-in module.
- 45. The memory architecture of claim 31 wherein each of the memory cells comprises:
a plurality of magnetic layers, at least one of the magnetic layers being for magnetically storing a bit of information; a plurality of access lines integrated with the plurality of magnetic layers and configured such that the bit of information may be accessed using selected ones of the plurality of access lines and the giant magnetoresistive effect; and at least one keeper layer; wherein the magnetic layers, the access lines, and the at least one keeper layer form a substantially closed flux structure.
- 46. The memory architecture of claim 45 wherein some of the plurality of magnetic layers comprise cobalt.
- 47. The memory architecture of claim 45 wherein some of the plurality of magnetic layers comprises permalloy.
- 48. The memory architecture of claim 45 wherein some of the plurality of access lines comprise copper.
- 49. The memory architecture of claim 45 wherein some of the plurality of access lines comprise multi-layer lines.
- 50. The memory architecture of claim 45 wherein each of the memory cells comprises a dibit memory cell, the plurality of magnetic layers comprising two storage layers.
- 51. The memory architecture of claim 50 wherein the two storage layers and the plurality of access lines are configured to read the bits of information destructively.
- 52. The memory architecture of claim 50 wherein the two storage layers and the plurality of access lines are configured to read the bits of information nondestructively.
- 53. The memory architecture of claim 45 wherein each of the memory cells comprises a three bit memory cell, the plurality of magnetic layers comprising three storage layers.
- 54. The memory architecture of claim 53 wherein the three storage layers and the plurality of access lines are configured to read the bits of information destructively.
- 55. The memory architecture of claim 53 wherein the three storage layers and the plurality of access lines are configured to read the bits of information nondestructively.
- 56. The memory architecture of claim 45 wherein each of the memory cells comprises a four bit memory cell, the plurality of magnetic layers comprising four storage layers.
- 57. The memory architecture of claim 56 wherein the four storage layers and the plurality of access lines are configured to read the bits of information destructively.
- 58. The memory architecture of claim 56 wherein the four storage layers and the plurality of access lines are configured to read the bits of information nondestructively.
- 59. The memory architecture of claim 45 wherein each of the memory cells comprises a single bit memory cell, the plurality of magnetic layers comprising one storage layer.
- 60. The memory architecture of claim 59 wherein the storage layer and the plurality of access lines are configured to read the bit of information destructively.
- 61. The memory architecture of claim 59 wherein the storage layer and the plurality of access lines are configured to read the bit of information nondestructively.
- 62. The memory architecture of claim 31 wherein each of the first and second random access memories further comprises support electronics which comprise multi-layer thin film structures exhibiting giant magnetoresistance.
- 63. The memory architecture of claim 62 wherein the support electronics comprise a plurality of access line selection matrices for selecting access lines associated with the memory cells.
- 64. The memory architecture of claim 63 wherein each selection matrix comprises an array of transpinnors, each transpinnor comprising a network of the multi-layer thin film structures, and at least one access line inductively coupled to at least one of the thin film structures for applying at least one magnetic field thereto, each transpinnor generating an output when the network is resistively unbalanced.
- 65. The memory architecture of claim 62 wherein the support electronics comprise a plurality of transpinnors, each transpinnor comprising a network of the multi-layer thin film structures, and at least one conductor inductively coupled to at least one of its thin film structures for applying at least one magnetic field thereto, each transpinnor generating an output when the network is resistively unbalanced.
- 66. The memory architecture of claim 65 wherein selected ones of the transpinnors are configured as amplifiers for amplifying signals on access lines associated with the first and second arrays.
- 67. The memory architecture of claim 65 wherein selected ones of the transpinnors are configured as differential amplifiers for resistively balancing pairs of access lines associated with the first and second arrays.
- 68. The memory architecture of claim 65 wherein selected subsets of the transpinnors are configured as a selection matrix for facilitating s electio n of access lines associated with the first and second arrays.
- 69. The memory architecture of claim 62 wherein the support electronics comprise a plurality of configurable resistive elements.
- 70. The memory architecture of claim 69 wherein each configurable resistive element comprises at least one high coercivity layer and at least one low coercivity layer, a resistance value associated with each configurable resistive element being configurable by at least partially switching a first magnetization vector associated with the high coercivity layer.
- 71. The memory device of claim 2 further comprising a non-magnetic conductor layer, wherein the plurality of magnetic layers comprises two magnetic layers for storing two bits of information, the two magnetic layers being separated by and in electrical contact with the non-magnetic conductor layer, and wherein the plurality of access lines comprises a first access line from which the two magnetic layers are electrically insulated.
- 72. The memory device of claim 71 wherein the at least one keeper layer is disposed outside of the two magnetic layers and the first access line.
- 73. The memory device of claim 2 further comprising a plurality of non-magnetic conductor layers, wherein the plurality of magnetic layers are configured in two structures, each structure comprising two of the magnetic layers separated by and in electrical contact with one of the non-magnetic conductor layers, and wherein the plurality of access lines comprises a first access line disposed between the two structures and electrically insulated therefrom.
- 74. The memory device of claim 73 wherein the at least one keeper layer is disposed outside of the two structures.
- 75. The memory device of claim 74 further comprising an additional keeper layer in the middle of the insulated non-magnetic conductor layer.
- 76. The memory device of claim 2 wherein the plurality of magnetic layers comprises four magnetic layers and wherein the memory device further comprises three non-magnetic conductor layers separating and in electrical contact with the four magnetic layers, the memory device further comprising a fourth non-magnetic conductor layer electrically insulated from the magnetic layers, wherein the at least one keeper layer is disposed outside the magnetic layers and the non-magnetic conductor layers, and wherein the memory device is operable in a first mode of operation for storage and nondestructive readout of two bits of information, and in a second mode of operation for storage and destructive readout of four bits of information.
- 77. A memory device comprising first and second sense lines, each sense line comprising four magnetic layers separated by and in electrical contact with three non-magnetic conductor layers, the memory device also comprising a fourth non-magnetic conductor layer between the first and second sense lines and electrically insulated therefrom, the memory device also comprising a fifth non-magnetic conductor layer above the first and second sense lines and electrically insulated therefrom, the memory device also comprising at least one keeper layer disposed outside the first and second sense lines and the fourth and fifth non-magnetic conductor layers.
- 78. The memory device of claim 77 wherein the memory device is operable to effect storage and nondestructive readout of four bits of information.
- 79. The memory device of claim 77 further comprising an additional keeper layer in the center of the fourth non-magnetic conductor layer, wherein the memory device is operable to effect storage and destructive readout of eight bits of information.
- 80. The memory device of claim 76 further comprising a fifth non-magnetic conductor layer disposed adjacent one of the at least one keeper layer and operable to pass current substantially perpendicular to the three non-magnetic conductor layers.
- 81. A method of reading information in a structure comprising first and second magnetic layers separated by and in electrical contact with a non-magnetic conductor layer, the method comprising measuring a resistance of the structure, applying via the conductor layer a first current sufficient to switch a first magnetization associated with the first magnetic layer in a first direction and insufficient to switch a second magnetization associated with the second magnetic layer, measuring the resistance a second time, applying via the conductor layer a second current sufficient to switch the first magnetic magnetization in a second direction and insufficient to switch the second magnetization, and measuring the resistance of the structure a third time.
RELATED APPLICATION DATA
[0001] The present application claims priority from U.S. Provisional Patent Applications No. 60/217,338 for ALL-METAL RAM and No. 60/217,781 for SOLID-STATE MASS STORAGE SYSTEM FOR IMPROVED MOBILITY AND LOW EMISSION both filed on Jul. 11, 2000, the entire disclosures of both of which are incorporated herein by reference for all purposes.
Provisional Applications (2)
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Number |
Date |
Country |
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60217338 |
Jul 2000 |
US |
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60217781 |
Jul 2000 |
US |