Hussin Ketout
Lecturer
Department of Computer Engineering
Kate Gleason College of Engineering
585-475-5292
Office Location
Hussin Ketout
Lecturer
Department of Computer Engineering
Kate Gleason College of Engineering
585-475-5292
Currently Teaching
CMPE-460
Interface and Digital Electronics
4 Credits
This course covers various sensors, motors, and signal conditioning circuits, including amplification, filtering, level shifting, ADC, and DAC. Modern tools, such as Arm Keil MDK and PSpice, are used to simulate and debug modern microcontrollers, such as TI Arm-based MSP, analog active filters, and operational amplifier application circuits. Students typically work in teams of two to design a complete data acquisition system from sensors, amplification, filtering, ADC, and DAC to analog signals through either wired or wireless transmission circuits.
CMPE-497
Multidisciplinary Senior Design I
3 Credits
This is the first in a two-course sequence oriented to the solution of real-world engineering design problems. This is a capstone learning experience that integrates engineering theory, principles, and processes within a collaborative environment. Multidisciplinary student teams follow a systems engineering design process, which includes assessing customer needs, developing engineering specifications, generating and evaluating concepts, choosing an approach, developing the details of the design, and implementing the design to the extent feasible, for example by building and testing a prototype or implementing a chosen set of improvements to a process. This first course focuses primarily on defining the problem and developing the design, but may include elements of build/ implementation. The second course may include elements of design, but focuses on build/implementation and communicating information about the final design.
CMPE-498
Multidisciplinary Senior Design II
3 Credits
This is the second in a two-course sequence oriented to the solution of real-world engineering design problems. This is a capstone learning experience that integrates engineering theory, principles, and processes within a collaborative environment. Multidisciplinary student teams follow a systems engineering design process, which includes assessing customer needs, developing engineering specifications, generating and evaluating concepts, choosing an approach, developing the details of the design, and implementing the design to the extent feasible, for example by building and testing a prototype or implementing a chosen set of improvements to a process. The first course focuses primarily on defining the problem and developing the design, but may include elements of build/ implementation. This second course may include elements of design, but focuses on build/implementation and communicating information about the final design.