A one-time programmable (OTP) memory device includes a memory array having multiple memory elements. The memory array includes a plurality of anti-fuse FinFETs and a plurality of access FinFETs. Each anti-fuse device has a first terminal for receiving a programming voltage and a second terminal. The anti-fuse FinFETs are located in a first region of an integrated circuit. At least one anti-fuse FinFET of the plurality of anti-fuse FinFETs and at least one access FinFET of the plurality of access FinFETs form a memory element of the plurality of memory elements of the memory array. Each access FinFET is configured to selectively couple one of a program inhibit voltage and a program enable voltage to the second terminal of a corresponding anti-fuse FinFET in a programming operation. The access FinFETs are located in a second region of the integrated circuit, different than the first region of the integrated circuit.

A one-time programmable (OTP) memory device includes a memory array having multiple memory elements. The memory array includes a plurality of anti-fuse FinFETs and a plurality of access FinFETs. Each anti-fuse device has a first terminal for receiving a programming voltage and a second terminal. The anti-fuse FinFETs are located in a first region of an integrated circuit. At least one anti-fuse FinFET of the plurality of anti-fuse FinFETs and at least one access FinFET of the plurality of access FinFETs form a memory element of the plurality of memory elements of the memory array. Each access FinFET is configured to selectively couple one of a program inhibit voltage and a program enable voltage to the second terminal of a corresponding anti-fuse FinFET in a programming operation. The access FinFETs are located in a second region of the integrated circuit, different than the first region of the integrated circuit.

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 signal processing circuit is provided that generates output signals to be output from spatially different output ports based on bit combinations of an input word consisting of a plurality of bit signals. A distributed memory, a ROM and a DAC in which the signal processing circuit is used are also provided. A recognition circuit includes a serial port to which a bit signal is input and 2.sup.N output ports recognizing an input N-bit word and corresponding uniquely to 2.sup.N bit combinations. Output ports of the recognition circuit are connected to 2.sup.N input ports of an electric circuit. With no signal input to the recognition circuit, all outputs are constantly in a Low level state. In a case where a bit signal is input to the serial port of the recognition circuit, only one of the output ports corresponding to the bit combinations turns to a High level state.

A signal processing circuit is provided that generates output signals to be output from spatially different output ports based on bit combinations of an input word consisting of a plurality of bit signals. A distributed memory, a ROM and a DAC in which the signal processing circuit is used are also provided. A recognition circuit includes a serial port to which a bit signal is input and 2.sup.N output ports recognizing an input N-bit word and corresponding uniquely to 2.sup.N bit combinations. Output ports of the recognition circuit are connected to 2.sup.N input ports of an electric circuit. With no signal input to the recognition circuit, all outputs are constantly in a Low level state. In a case where a bit signal is input to the serial port of the recognition circuit, only one of the output ports corresponding to the bit combinations turns to a High level state.

A phase-change memory cell includes, in at least a first portion, a stack of at least one germanium layer covered by at least one layer made of a first alloy of germanium, antimony, and tellurium. In a programmed state, resulting from heating a portion of the stack to a sufficient temperature, portions of layers of germanium and of the first alloy form a second alloy made up of germanium, antimony, and tellurium, where the second alloy has a higher germanium concentration than the first alloy.

A phase-change memory cell includes, in at least a first portion, a stack of at least one germanium layer covered by at least one layer made of a first alloy of germanium, antimony, and tellurium. In a programmed state, resulting from heating a portion of the stack to a sufficient temperature, portions of layers of germanium and of the first alloy form a second alloy made up of germanium, antimony, and tellurium, where the second alloy has a higher germanium concentration than the first alloy.

A one-time programmable (OTP) memory device includes a memory array having multiple memory elements. The memory array includes a plurality of anti-fuse FinFETs and a plurality of access FinFETs. Each anti-fuse device has a first terminal for receiving a programming voltage and a second terminal. The anti-fuse FinFETs are located in a first region of an integrated circuit. At least one anti-fuse FinFET of the plurality of anti-fuse FinFETs and at least one access FinFET of the plurality of access FinFETs form a memory element of the plurality of memory elements of the memory array. Each access FinFET is configured to selectively couple one of a program inhibit voltage and a program enable voltage to the second terminal of a corresponding anti-fuse FinFET in a programming operation. The access FinFETs are located in a second region of the integrated circuit, different than the first region of the integrated circuit.

A one-time programmable (OTP) memory device includes a memory array having multiple memory elements. The memory array includes a plurality of anti-fuse FinFETs and a plurality of access FinFETs. Each anti-fuse device has a first terminal for receiving a programming voltage and a second terminal. The anti-fuse FinFETs are located in a first region of an integrated circuit. At least one anti-fuse FinFET of the plurality of anti-fuse FinFETs and at least one access FinFET of the plurality of access FinFETs form a memory element of the plurality of memory elements of the memory array. Each access FinFET is configured to selectively couple one of a program inhibit voltage and a program enable voltage to the second terminal of a corresponding anti-fuse FinFET in a programming operation. The access FinFETs are located in a second region of the integrated circuit, different than the first region of the integrated circuit.

The present invention discloses a processor for enhancing network 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 rule/virus patterns and a pattern-processing circuit for performing pattern processing on an incoming network packet against said rule/virus patterns. The 3D-M array is stacked above the pattern-processing circuit.