A method for programming a one-time programmable structure is disclosed. The method comprises producing an electrical circuit having the one-time programmable structure. The method furthermore comprises severing the one-time programmable structure by etching the one-time programmable structure in a separating region.

A method for programming a one-time programmable structure is disclosed. The method comprises producing an electrical circuit having the one-time programmable structure. The method furthermore comprises severing the one-time programmable structure by etching the one-time programmable structure in a separating region.

To achieve a better overall performance, a preferred pattern processor offsets large latency with massive parallelism. It comprises a plurality of storage-processing units (SPU's), each of which comprises a single pattern-processing circuit, at least a three-dimensional memory (3D-M) array and a plurality of inter-storage-processor (ISP) connections. The ISP-connections do not penetrate through any semiconductor substrate.

To achieve a better overall performance, a preferred pattern processor offsets large latency with massive parallelism. It comprises a plurality of storage-processing units (SPU's), each of which comprises a single pattern-processing circuit, at least a three-dimensional memory (3D-M) array and a plurality of inter-storage-processor (ISP) connections. The ISP-connections do not penetrate through any semiconductor substrate.

A nanostructured cross-wire memory architecture is provided that can interface with conventional semiconductor technologies and be electrically accessed and read. The architecture links lower and upper sets of generally parallel nanowires oriented crosswise, with a memory element that has a characteristic conductance. Each nanowire end is attached to an electrode. Conductance of the linkages in the gap between the wires encodes the information. The nanowires may be highly-conductive, self-assembled, nucleic acid-based nanowires enhanced with dopants including metal ions, carbon, metal nanoparticles and intercalators. Conductance of the memory elements can be controlled by sequence, length, conformation, doping, and number of pathways between nanowires. A diode can also be connected in series with each of the memory elements. Linkers may also be redox or electroactive switching molecules or nanoparticles where the charge state changes the resistance of the memory element.

The present invention discloses a processor for enhancing computer security, i.e. a three-dimensional (3-D) security processor. It is a monolithic integrated circuit comprising a plurality of storage-processing units (SPU). Each SPU comprises at least a three-dimensional memory (3D-M) array for permanently storing virus patterns and a pattern-processing circuit for performing pattern processing on a scanned computer data against said virus patterns. The 3D-M array is stacked above the pattern-processing circuit.

The present invention discloses a first preferred processor comprising a fixed look-up table circuit (LTC) and a writable LTC. The fixed LTC realizes at least a common function while the writable LTC realizes at least a non-common function. The present invention further discloses a second preferred processor comprising a two-dimensional (2-D) LTC and a three-dimensional (3-D) LTC. The 2-D LTC realizes at least a fast function while the 3-D LTC realizes at least a non-fast function.

The present invention discloses a first preferred processor comprising a fixed look-up table circuit (LTC) and a writable LTC. The fixed LTC realizes at least a common function while the writable LTC realizes at least a non-common function. The present invention further discloses a second preferred processor comprising a two-dimensional (2-D) LTC and a three-dimensional (3-D) LTC. The 2-D LTC realizes at least a fast function while the 3-D LTC realizes at least a non-fast function.

A bi-sided pattern processor comprises a plurality of storage-processing units (SPU's). Each of the SPU's comprises at least a memory array and a pattern-processing circuit. The preferred pattern processor further comprises a semiconductor substrate with opposing first and second surfaces. The memory array is disposed on the first surface, whereas the pattern-processing circuit is disposed on the second surface. The memory array stores patterns; the pattern-processing circuit processes these patterns; and, they are communicatively coupled by a plurality of inter-surface connections.

A multi-level distributed pattern processor comprises a plurality of storage-processing units (SPU's). Each of the SPU's comprises at least a non-volatile memory (NVM) array and a pattern-processing circuit. The NVM array and the pattern-processing circuit are disposed on different physical levels.