About

Kenneth Short is a Professor at the Department of Electrical and Computer Engineering at Stony Brook University. His research focuses on digital system design, embedded microprocessor systems, and instrumentation. He is involved in advancing the development of digital systems and their applications, contributing to the fields of embedded systems and instrumentation within electrical engineering.

Research topics

• Computer science
• Computer architecture
• Engineering
• Engineering management
• Software engineering

Selected publications

• VHDL for Engineers

  Medical Entomology and Zoology · 2009-01-01 · 8 citations

  book1st authorCorresponding
  Publisher

• Embedded Microprocessor Systems Design: An Introduction Using the 80c188eb

  Simon & Schuster Trade eBooks · 1998-03-01 · 2 citations

  book1st authorCorresponding

  From the Publisher: FEATURES: Extensively covers the topics of hardware and software and includes numerous examples. Uses 80C188EB microprocessor as instructional example. Provides thorough introduction to the use of assembly language in embedded systems. Discusses a large number of the ICs commonly used in embedded systems. Contains coverage of digital-to-analog and analog-to-digital conversion. Explores the development of a complete example system. Includes over 400 End-of-Chapter problems.

  Publisher

• Microprocessor-based robotic system for control of fluid connections in the cardiac catheterization laboratory

  IEEE Transactions on Biomedical Engineering · 1988-01-01 · 1 citations

  article

  The authors have developed a microprocessor-based robotic system which fully automates routine catheter flushing, and allows the system user, from a remote location, to flush the catheters intermittently, to calibrate the pressure transducers, to inhibit routine during pressure transducers, to inhibit routine functions during pressure waveform recording, and to set valve positions so the user may flush the transducer dome. The time required to execute four tasks ((1) routine catheter flushing, (2) intermittent catheter flushing, (3) pressure measurement, and (4) flushing the transducer dome) with and without the use of the control system was compared by two subjects with similar results. For the first subject, significant time was saved (p<0.005) for each routine flush (15.1+or-0.14 s), intermittent flush (8.9+or-0.19 s), and pressure recording (15.5+or-0.24 s).< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

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• Microprocessors and programmed logic (2nd ed.)

  Prentice-Hall, Inc eBooks · 1987-03-30

  book1st authorCorresponding
  Publisher

• An Innovative Program of University/Industry Cooperation in Microprocessor Education

  IEEE Transactions on Education · 1986-05-01 · 15 citations

  article1st authorCorresponding

  The need for a university to provide high quality microprocessor education to a constituency consisting of undergraduate and graduate students, university faculty and staff, and engineers in industry requires substantial resources in the form of state-of-the-art equipment and experienced instructors. This paper describes a unique, ongoing, joint effort between the Department of Electrical Engineering at Stony Brook and Intel Corporation that has allowed both Stony Brook and Intel to accomplish their goals in the area of microprocessor education.

  PublisherDOI

• Digital Systems Design with Programmed Logic

  IEEE Transactions on Education · 1977-02-01 · 4 citations

  article1st authorCorresponding

  New design techniques resulting from the tremendous impact of programmable LSI devices have revolutionized the field of digital systems design. It is incumbent upon departments of electrical engineering and computer science to keep their undergraduates abreast of these new techniques. "Microprocessors and Programmed Logic," a lecture-laboratory course covering both the hardware and software aspects of designing systems using programmed logic is described in detail in this paper.

  PublisherDOI

Frequent coauthors

• Lloyd A. Marks

  Temple University

  4 shared

• Stephen D. Shapiro

  Stony Brook University

  4 shared

• Emil J. Sarpa

  Intel (United States)

  4 shared

• Allan S. Lew

  2 shared

• D. Hoffmann

  Centre de physique des particules de Marseille

  2 shared

Labs

• Electrical and Computer EngineeringPI