Jeanne Christman
Associate Professor
Department of Electrical and Computer Engineering Technology
College of Engineering Technology
585-475-6609
Office Hours
Monday 10-11am, Tuesday 11am-1pm (Zoom only), Wednesday 3-4 pm Thursday 10-11am or by appointment. Zoom links are in MyCourses
Office Location
Office Mailing Address
ENT-2134 78 Lomb Memorial Dr. Rochester, NY 14623-5604
Jeanne Christman
Associate Professor
Department of Electrical and Computer Engineering Technology
College of Engineering Technology
Education
BS, Clarkson University; MS, University of Texas at Dallas; Ph.D., University at Buffalo
Bio
Dr. Jeanne Christman is an Associate Professor and Associate Department Chair in the Department of Electrical, Computer and Telecommunications Engineering Technology. She holds a BS in Electrical Engineering, an MS in Computer Science and a PhD in Curriculum, Instruction and the Science of Learning. Utilizing her educational background, her teaching specialty is digital and embedded system design and her research areas include engineering education culture, equity in engineering education and increasing diversity in STEM through transformation of traditional teaching methods.
During her 14 years at RIT, Dr. Christman has been co-PI on several grants focused on increasing the recruitment and retention of women in Engineering Technology, including a previous NSF SSTEM grant upon whose success the SD-CoMETS program is modelled. Additionally, she was a founding member of the College of Engineering’s Women in Technology program, which provides social, academic and professional support to underrepresented students in the college. In addition to the SD-CoMETS program, Dr. Christman is currently part of a project funded by the Kern Entrepreneurial Engineering Network to improve student learning through reflective story-telling and also her college’s representative to RIT’s Council for the Representation and Engagement of Women Faculty.
Select Scholarship
Published Conference Proceedings
Christman, Jeanne and Randy Yerrick. "“She\'s more like a guy”: The Legacy of Gender Inequity Passed on to Undergraduate Engineering Students." Proceedings of the American Society for Engineering Education Annual Conference, July 21, virtual. Ed. ASEE. Wsshington, DC: American Society for Engineering Education, 2021. Web.
Christman, Jeanne W., Mark Indelicato, and George Zion. "Assessment of discrete concept knowledge and integrated understanding in introductory networking courses." Proceedings of the 2018 American Society for Engineering Education Annual Conference and Exposition. Ed. ASEE. Salt Lake City, UT: n.p., 2018. Web.
Christman, Jeanne and Antonio Mondragon-Torres. "Embedded Systems Design Curriculum Conversion from Quarters to Semesters." Proceedings of the IEEE Frontiers in Education. Ed. IEEE. Oklahoma City, OK: IEEE, 2013. Web.
Christman, Jeanne and Antonio Mondragon. "A Comprehensive Embedded Systems Design Course and Laboratory." Proceedings of the IEEE International Conference on Microelectronic Systems Education. Ed. IEEE. Austin, TX: IEEE, 2013. Web.
Christman, Jeanne and Antonio Mondragon. "Hard Core vs. Soft Core: A Debate." Proceedings of the ASEE Annual Conference and Exposition. Ed. American Society For Engineering Education. San Antonio, TX: n.p., 2012. Web.
Journal Paper
Christman, Jeanne W., et al. "Using Self Determination Theory to Build Communities of Support and Improve the Learning Environment for Women in Engineering." European Journal of Engineering Education. (2017): 1-16. Web.
Christman, Jeanne W., et al. "To Educate Engineers or Engineer Educators." Journal of Research in Science Teaching 54. 7 (2017): 884-913. Print.
Christman, Jeanne. "The Case of the Burning Laptops." Journal of Case Studies 30. 1 (2012): 88-97. Web.
Invited Keynote/Presentation
Christman, Jeanne. "A Hands-on Approach to Demonstrating Hardware/Software Tradeoffs in an Embedded System Design." 118th American Society for Engineering Education Conference & Exposition. ASEE. Vancouver Convention Center, Vancouver, BC. 26-29 Jun. 2011. Conference Presentation.
Published Article
Christman, Jeanne, Elizabeth Dell, and Robert Garrick. “Increasing Girls Interest in Engineering byMaking It Fun.” ASEE Annual Conference and Exposition, 2010. n.p. Web.
Currently Teaching
CPET-121
Computational Problem Solving I
3 Credits
This is the first course in a two-course sequence in computational problem solving of engineering and scientific problems. The problems solved will stress the application of sequence, selection, repetitive, invocation operations, and arrays. The development of proper testing procedures to ensure computational accuracy will be stressed. Students, upon successful completion of this course, will be able to analyze introductory engineering and scientific problems, design, code, test, and document procedural software solutions.
CPET-133
Introduction to Digital and Microcontroller Systems
3 Credits
This course introduces students to the underlying building blocks of digital system and microcontroller design. Digital systems topics that are covered include: number systems, truth tables, Boolean algebra, combinational and sequential logic, and finite state machines. A microcontroller is used to teach register programming, reading and writing digital I/O, bitwise operations and bit-masking and microprocessor architecture. Laboratory exercises are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics.
CPET-233
Digital Systems Design
3 Credits
This course covers the design and simulation of digital circuits using modern digital design techniques. Using a hardware description language, students will design, synthesize, and analyze finite state machines and combinational, sequential, and arithmetic logic circuits. Topics will include design for synthesis, verification techniques, memory circuits, programmable logic devices, and implementation technologies.
The laboratories are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics.
CPET-253
Microcontroller Systems
3 Credits
This course presents typical structures and applications of microcontroller systems. Emphasis will be on: hardware, programming, input/output methods, typical peripherals/interfacing (including Timers, ADC and micro to micro communications), interrupt handling and small system design and applications using high level programming languages. Microprocessor architecture and assembly programming will be introduced to provide a base for more advanced digital designs. Laboratory exercises are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics.
CPET-499
Cooperative Education – Computer Engineering Technology
0 Credits
One semester or summer block of appropriate work experience in a related industry. Students are required to complete a poster and presentation and participate in the ECTET co-op presentation evening at the completion of each co-op experience. Department permission is required.
EEET-499
Cooperative Education – Electrical Engineering Technology
0 Credits
One semester or summer block of appropriate work experience in a related industry. Students are required to complete a poster and presentation and participate in the ECT-ET Co-op presentation evening at the completion of each co-op experience.