Abstract: A system and method are described for secure data transfer over a network. According to an exemplary embodiment a system for secure data transfer over a network includes memory and a memory controller configured to transfer data received from the network to the memory. The system includes a processor, having logic configured to retrieve a portion of the data from the memory using the memory controller. The processor also includes logic configured to perform security operations on the retrieved portion of the data, and logic configured to store the operated-on portion of the data in the memory using the memory controller. The memory controller is further configured to transfer the operated-on portion of the data from the memory to the network.

Abstract: A system and method are described for performing security operations on network data. According to an exemplary embodiment, a system for performing security operations on network data includes memory and a data coprocessor configured to transfer data into and out of the memory. A plurality of processors are coupled to the memory and to the data coprocessor. Each processor is configured to perform, in parallel to one another, security operations on a portion of the data. The system includes a plurality of security coprocessors coupled to the memory. Each security coprocessor is coupled to a respective one of the processors and configured to assist the respective processor in performing security operations on the portion of the data.

Abstract: A method is disclosed for fabricating a small area, self aligned guard ring in a Schottky barrier diode. A vertically-walled hole is anisotropically etched completely through a dielectric layer on a silicon substrate. A layer of doped polycrystalline silicon is deposited over the apertured dielectric layer. The polycrystalline silicon is reactively ion etched away to leave only a lining about the perimeter of the hole in the dielectric layer. The structure is heated to diffuse the dopant from the lining into the substrate. Schottky diode metal is deposited on the substrate exposed through the lined aperture in the dielectric layer.

Abstract: A method is disclosed for fabricating a small area, self aligned guard ring in a Schottky barrier diode. A vertically-walled hole is anisotropically etched completely through a dielectric layer on a silicon substrate. A layer of doped polycrystalline silicon is deposited over the apertured dielectric layer. The polycrystalline silicon is reactively ion etched away to leave only a lining about the perimeter of the hole in the dielectric layer. The structure is heated to diffuse the dopant from the lining into the substrate. Schottky diode metal is deposited on the substrate exposed through the lined aperture in the dielectric layer.

Abstract: A process is described which permits the fabrication of very narrow base width bipolar transistors in selected areas of an integrated circuit chip and bipolar transistors of wider base width on other selected areas of the same integrated circuit chip. The ability to selectively vary the transistor characteristics from one region of an integrated circuit chip to another provides a degree of freedom for design of integrated circuits which is valuable. The bipolar transistors on an integrated circuit chip are processed up to the point of emitter formation using conventional techniques. But, prior to the emitter formation, the base area which is to be the emitters of the selected region having the very narrow base transistors is dry etched using reactive ion etching. The existing silicon nitride/silicon dioxide layers with the emitter opening therein are used as the etching mask for this reactive ion etching procedure.

Abstract: A method for making a lateral PNP transistor simultaneously with an NPN transistor and the resultant device wherein a first mask defines a base-width by the resistor implant for a P-type resistor and a second mask is overlaid asymmetrically on said first mask to partially cover the collector. At the same time that the NPN extrinsic base contact is made, P-type dopants are introduced in the areas exposed by the first and second masks to provide an emitter and a collector contact for the PNP transistor.

Abstract: A process is described which permits the fabrication of very narrow base width bipolar transistors. The ability to selectively vary the transistor characteristics provides a degree of freedom for design of integrated circuits. The bipolar transistor is processed up to the point of emitter formation using conventional techniques. But, prior to the emitter formation, the base area which is to be the emitter is dry etched using reactive ion etching. The existing silicon nitride/silicon dioxide layers with the emitter opening therein are used as the etching mask for this reactive ion etching procedure. Once the etching is completed to the desired depth, the normal processing is resumed to form the emitter and rest of the metallization. Since the intrinsic base under the emitter is etched. and the normal emitter is formed afterwards, the etching reduces the base width by an amount approximately equal to the etched depth.

Abstract: A dynamic memory cell has a P+ injector region surrounded by an N+ region in an N- layer on an N+ layer. The injector region is placed between N+ source and drain regions. Holes injected into the N-layer are trapped by the high-low junctions at the N+, N- interfaces and are detected by sensing the source-drain current. Current levels are used to establish binary one and zero levels in the cell. Four masks in an aligned procedure simplify fabrication.

Abstract: A dynamic memory cell uses a low barrier Schottky contact at a drain region to eliminate the need for an external gating diode. The drain is separated from source and injector regions by a heavily doped N+ reach through region extending to a heavily doped N+ blanket semiconductor. Holes injected into one of the separated regions are trapped by high-low junctions and are detected by sensing the source-drain current.

Abstract: Lateral PNP or NPN devices in isolated monocrystalline silicon pockets wherein silicon dioxide isolation surrounds the pocket and partially, below the surface, within the isolated monocrystalline region are described. The P emitter or N emitter diffusion is made over the portion of the silicon dioxide that partially extends into the monocrystalline isolated pocket. This structure reduces the vertical current injection which will give relatively high (beta) gain even at low base to emitter voltages.