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Dec 22, 2024
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EE 4240 - Software-Defined Radio2 lecture hours 2 lab hours 3 credits Course Description This course introduces students to fundamental topics involving software-defined radio and their application to modern wireless systems. Software-defined radios provide a flexible hardware platform in which a wide range of wireless systems can be prototyped and implemented in software. Course topics include an overview of transceiver architectures, underlying analog and digital subsystems, and digital signal processing algorithms typically used in software-defined radios. Hands-on laboratory experiences will utilize modern software radio hardware and will examine solutions to practical issues that impact the feasibility and performance a wireless digital communication system. At the conclusion of the course, students will have constructed a fully functional software-based digital transceiver. (prereq: EE 3221 , EE 4022 ) Course Learning Outcomes Upon successful completion of this course, the student will be able to:
- Identify the architecture of a modern software-defined radio system
- Explain the advantages, limitations, and design trade-offs of the underlying analog and digital subsystems of a software-defined radio
- Perform link budget calculations for a software defined radio system given parameters of the communication link
- Analyze communication signals and systems using I/Q and complex-baseband models
- Explain the design challenges associated with building digital wireless communication links
- Implement the optimum receiver structure for digital transmission through an additive white Gaussian noise channel
- Implement software-based solutions for non-ideal phenomena impacting digital wireless communication systems such as multi-path propagation, synchronization, and channel equalization
- Implement an end-to-end wireless data transceiver capable of performing over-the-air digital transmission
Prerequisites by Topic
- Linear-Time Invariant system analysis
- Fourier transforms
- Sampling theorem, sampled spectra, and aliasing
- Amplitude, frequency and phase modulation
- Basic digital communications
- Students should be comfortable with MATLAB/Simulink
Course Topics
- Introduction to software-defined radio
- SDR system architectures
- Multi-rate signal processing
- Link budgets for digital communication systems
- Elements of a digital communication transceiver
- Non-ideal effects and software-based solutions
Laboratory Topics
- SDR hardware and software support package installation
- I/Q signaling and complex-baseband
- Efficient downconversion and sampling rate conversion
- Signal to noise ratio, spectrum plots, link budget
- Channel fading
- Carrier recovery
- Pulse shaping, eye diagrams, matched ltering
- Fully functional digital transceiver
Coordinator Dr. Cory J. Prust
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