Abstract: Illustrative embodiments provide a mixed programmable and application-specific integrated circuit, a method of using the mixed programmable and application-specific integrated circuit and a method of making the mixed programmable and application-specific integrated circuit. The mixed programmable and application-specific integrated circuit includes at least a portion of a programmable transistor array that is programed after fabrication. The programmable transistor array can include at least another portion that is mask programed during fabrication.

Abstract: Illustrative embodiments provide a mixed programmable and application-specific integrated circuit, a method of using the mixed programmable and application-specific integrated circuit and a method of making the mixed programmable and application-specific integrated circuit. The mixed programmable and application-specific integrated circuit includes at least a portion of a programmable transistor array that is programed after fabrication. The programmable transistor array can include at least another portion that is mask programed during fabrication.

Abstract: Illustrative embodiments provide a field-programmable transistor array and a method of making an integrated circuit comprising a field-programmable transistor array. The field-programmable transistor array comprises a plurality of logic cells. Each of the plurality of logic cells comprises a plurality of columns of transistors. Each of the plurality of columns of transistors comprises a plurality of first transistors and a plurality of second transistors. Each of the plurality of first transistors are individually programmable to be either always on, always off, or to be controlled by a logic signal to be on or off. Each of the plurality of second transistors are configured to be programmed to be always on or always off.

Abstract: Illustrative embodiments provide a field-programmable transistor array and a method of making an integrated circuit comprising a field-programmable transistor array. The field-programmable transistor array comprises a plurality of logic cells. Each of the plurality of logic cells comprises a plurality of columns of transistors. Each of the plurality of columns of transistors comprises a plurality of first transistors and a plurality of second transistors. Each of the plurality of first transistors are individually programmable to be either always on, always off, or to be controlled by a logic signal to be on or off. Each of the plurality of second transistors are configured to be programmed to be always on or always off.

Abstract: Illustrative embodiments provide a field-programmable transistor array and a method of making an integrated circuit comprising a field-programmable transistor array. The field-programmable transistor array comprises a plurality of logic cells. Each of the plurality of logic cells comprises a plurality of columns of transistors. Each of the plurality of columns of transistors comprises a plurality of first transistors and a plurality of second transistors. Each of the plurality of first transistors are individually programmable to be either always on, always off, or to be controlled by a logic signal to be on or off. Each of the plurality of second transistors are configured to be programmed to be always on or always off.

Abstract: Illustrative embodiments provide a field-programmable transistor array and a method of making an integrated circuit comprising a field-programmable transistor array. The field-programmable transistor array comprises a plurality of logic cells. Each of the plurality of logic cells comprises a plurality of columns of transistors. Each of the plurality of columns of transistors comprises a plurality of first transistors and a plurality of second transistors. Each of the plurality of first transistors are individually programmable to be either always on, always off, or to be controlled by a logic signal to be on or off. Each of the plurality of second transistors are configured to be programmed to be always on or always off.

Abstract: A method for improving the speed of conventional CMOS logic families is disclosed. When applied to static CMOS, OPL retains the restoring character of the logic family, including its high noise margins. Speedups of 2× to 3× over (optimized) conventional static CMOS are demonstrated for a variety of circuits, ranging from chains of gates, to datapath circuits, and to random logic benchmarks. Such speedups are obtained using identical netlists without remapping. When applied to pseudo-nMOS and dynamic families, in combination with remapping to wide-input NORs, OPL yields speedups of 4× to 5× over static CMOS. Since OPL applied to static CMOS is faster than conventional domino logic, and since it has higher noise margins than domino logic, we believe it will scale much better than domino with future processing technologies.