Company Filing History:
Years Active: 1983
Title: James D. Howard: Innovator in Microprocessor Technology
Introduction
James D. Howard is a notable inventor based in Beaverton, OR (US). He has made significant contributions to the field of microprocessor technology, particularly through his innovative patent that enhances the functionality of general-purpose microprocessors. His work has implications for the efficiency and performance of computing systems.
Latest Patents
James D. Howard holds a patent for a "Microinstruction execution unit for use in a microprocessor." This invention involves an execution unit that is partitioned between two integrated circuit chips, with the execution unit on one chip and an instruction unit on another. The execution unit serves as the interface for accessing main memory, allowing for the fetching of data and macroinstructions as requested by the instruction unit. It processes arithmetic microinstructions to perform various arithmetic operations and develops memory references from logical addresses received from the instruction unit. The design includes a data manipulation unit and a reference-generation unit, both controlled by sequencers to enhance performance.
Career Highlights
James D. Howard has had a distinguished career at Intel Corporation, where he has been instrumental in advancing microprocessor technology. His innovative approach to microinstruction execution has contributed to the development of more efficient computing systems. His expertise in this area has positioned him as a key figure in the field of microprocessor design.
Collaborations
Throughout his career, James has collaborated with notable colleagues, including David L. Budde and Stephen R. Colley. These collaborations have fostered an environment of innovation and have led to advancements in microprocessor technology.
Conclusion
James D. Howard's contributions to microprocessor technology through his patent and work at Intel Corporation highlight his role as an influential inventor in the field. His innovative designs continue to impact the efficiency and performance of modern computing systems.