|
|
|
|
|
|
|
Course Criteria
Add courses to your favorites to save, share, and find your best transfer school.
-
4.00 Credits
An introduction to theoretical and experimental solidstate physics. Wave mechanics in the perfect crystal. X-rays, electrons, and phonons. Electrical properties of metals and semiconductors. Qualitative treatment of lattice defects. Prerequisites/Corequisites: Prerequisites: PHYS 2100 and PHYS 2510 or equivalent. When Offered: Fall term annually. Cross Listed: Cross-listed as PHYS 4720. Students cannot receive credit for both this course and PHYS 4720. Credit Hours: 4
-
3.00 Credits
Introduction to Interactive Computer Graphics, with an emphasis on applications programming. Objects and viewers, and the synthetic camera model. Graphics architectures, the graphics pipeline, clipping, rasterization, and programmable shaders. Input and interaction. Geometric objects, homogeneous coordinates, and transformations. Viewing, hidden surface removal, frame and depth buffers, compositing, and anti-aliasing. Shading, light and materials, texture mapping, ray tracing, and radiosity. Intellectual property concerns. Extensive programming with the OpenGL API and C++. Prerequisites/Corequisites: Prerequisite: ECSE 2610 or equivalent. When Offered: Fall term annually. Credit Hours: 3
-
3.00 Credits
Experiments and lectures demonstrate the design and use of microcomputers as both decision tools and on-line real-time system components in control and communications. Topics include the basic operations of microcomputers, data I/O, analog and digital process control, voice processing, digital filter design, digital communication, and optimal LQR control. Prerequisites/Corequisites: Prerequisites: ECSE 4510. Co-requisite: ECSE 4520 or ECSE 4440 recommended. When Offered: Spring term annually. Credit Hours: 3 Contact, Lecture or Lab Hours: 5 contact hours
-
3.00 Credits
Digital design methodologies including timing chain and counter based "hardwired" microprogram design, modules, and modular design. The course bridges LSI and MSI design treating microprocessors, and I/O interfacing. Bus protocol standards, interrupts, direct memory access, priority arbitration, asynchronous timing, and overlap or double buffering. Specific examples of design include controllers for disks, cassettes, video systems, and stepping motors. Course includes a laboratory with access to FPGAs and microprocessors.Prerequisites/Corequisites: Prerequisite: ECSE 2610; ENGR 2350 desirable. When Offered: Fall term annually. Credit Hours: 3 Contact, Lecture or Lab Hours: 5 contact hours
-
4.00 Credits
A capstone design course. Design methodologies include register transfer modules and firmware microprogrammed design. "Bit-slice" philosophy of design. LSI microprocessors as design elements in larger digital systems such as high-speed channels and special purpose computers. Detailed discussion of the structure of several computers at the chip and board level. Specification of custom IC digital systems. FPGA based design implementation using VHDL. Students cannot receive credit for both this course and ECSE 6700.Prerequisites/Corequisites: Prerequisites: ECSE 4770. Corequisites: ECSE 2660, ENGR 4010 and senior standing. When Offered: Spring term annually. Credit Hours: 4
-
3.00 Credits
Hardware and software for real-time microprocessor-based digital systems. Basic concepts and operations of on-chip components related to digital system functionality. Architectures, instructions sets, and interfacing with peripherals through serial or parallel ports. Introduction to 32-bit machines with in-depth treatment of 16- and 8- bit machines. Emphasis on C language cross-compilers. Laboratory exercises are included to demonstrate hardware and software development techniques practiced in industry. Prerequisites/Corequisites: Prerequisites: ECSE 2610 and ENGR 2350. Corequisites: ENGR 4010 and senior standing. When Offered: Fall term annually. Credit Hours: 3 Contact, Lecture or Lab Hours: 6 contact hours
-
3.00 Credits
An introduction to the basics of subsurface sensing and imaging: Properties of probes such as optical beams, X-rays, ultrasonic waves, and electromagnetic waves. Physical interaction of probes with various media-transmission, reflection, attenuation, scattering, diffusion, fluorescence. Contrast agents and molecular sensing/imaging systems. Biomedical and security applications. Extracting information from subsurface signals using multi-view tomography (MVT), localized probing and mosaicing (LPM), and multi-spectral discrimination (MSD). Prerequisites/Corequisites: Prerequisites: ECSE 2410 and ECSE 2100. ECSE 2800 or BMED 2800 or permission of instructor also required. When Offered: Spring term annually Cross Listed: Cross-listed as BMED 4800. Students cannot receive credit for both this course and BMED 4800. Credit Hours: 3
-
3.00 Credits
A capstone design course. Provides all ECSE majors senior design experience by engaging them in clientsponsored projects. The students work in multidisciplinary teams, jointly responsible to the faculty, the client liaison, and to each other for project management, execution and reporting. Contemporary design tools and practices are emphasized. Senior standing required. Prerequisites/Corequisites: Corequisites: ECSE 4010 and senior standing. When Offered: Fall and spring terms. Credit Hours: 3
-
1.00 - 3.00 Credits
Supervised reading and research. Credit Hours: 1 to 3
-
3.00 Credits
Credit Hours: 3
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Privacy Statement
|
Terms of Use
|
Institutional Membership Information
|
About AcademyOne
Copyright 2006 - 2024 AcademyOne, Inc.
|
|
|