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2024 Faculty Courses School of Engineering Undergraduate major in Information and Communications Engineering

Communication Systems

Academic unit or major
Undergraduate major in Information and Communications Engineering
Instructor(s)
Kazuhiko Fukawa
Class Format
Lecture (Face-to-face)
Media-enhanced courses
-
Day of week/Period
(Classrooms)
3-4 Mon / 3-4 Thu
Class
-
Course Code
ICT.C214
Number of credits
200
Course offered
2024
Offered quarter
4Q
Syllabus updated
Mar 17, 2025
Language
Japanese

Syllabus

Course overview and goals

The main aim of this lecture is to make students understand fundamentals of physical layers of electronic communication systems. Especially, students are expected to learn principles of some modulation and demodulation schemes and to understand how these schemes are applied to real communication systems.

Course description and aims

At the end of this course, students will be able to:
1) regard channels as abstract mathematical models,
2) explain how modulation schemes transform baseband signals into bandpass signals,
3) explain how demodulation schemes derive baseband signals from bandpass signals.

Keywords

baseband signal, bandpass signal, amplitude modulation, frequency modulation, phase modulation, coherent detection, non-coherent detection, sampling theorem, digital modulation

Competencies

  • Specialist skills
  • Intercultural skills
  • Communication skills
  • Critical thinking skills
  • Practical and/or problem-solving skills

Class flow

Students are provided with exercise problems about items explained in each class.

Course schedule/Objectives

Course schedule Objectives
Class 1 Overview of electronic communication systems Learn an overview of electronic communication systems.
Class 2 Fourier series and Fourier transform Review Fourier series and Fourier transform.
Class 3 Equivalent lowpass representation Understand the equivalent lowpass representation as an important basic of communications.
Class 4 Stochastic process I Review probability distributions and probability density functions.
Class 5 Stochastic process II Understand stochastic processes and their bandpass signals.
Class 6 Sampling and quantization Understand principles of sampling and quantization.
Class 7 Baseband pulse transmission Learn baseband pulse transmission schemes as baseband digital transmission schemes.
Class 8 Review of the first half and midterm exam Check whether examinees understand contents of the first half.
Class 9 Modulation and demodulation Understand principles of modulation and demodulation schemes.
Class 10 Amplitude modulation I Understand DSB and AM as amplitude modulation schemes.
Class 11 Amplitude modulation II Understand SSB as an amplitude modulation scheme besides principles of QAM.
Class 12 Angel modulation Understand the angle modulation including phase and frequency modulation.
Class 13 Digital modulation I Understand OOK as a digital modulation scheme and analyses of its coherent and envelope detection.
Class 14 Digital modulation II Understand FSK and PSK as digital modulation schemes.

Study advice (preparation and review)

To enhance effective learning, students are encouraged to spend approximately 100 minutes preparing for class and another 100 minutes reviewing class content afterwards (including assignments) for each class.
They should do so by referring to textbooks and other course material.

Textbook(s)

None.

Reference books, course materials, etc.

Hiroshi Suzuki, Fundamentals of Digital Communications, Science Inc., 2012.

Evaluation methods and criteria

Student achievements are assessed based on the middle and final examinations. In some cases, reports for every lecture can be considered.

Related courses

  • ICT.S206 : Signal and System Analysis
  • ICT.M202 : Probability and Statistics (ICT)
  • ICT.C205 : Communication Theory (ICT)
  • ICT.S210 : Digital Signal Processing
  • ICT.C209 : Algebraic Systems and Coding Theory
  • ICT.C301 : Foundations of Communication Network

Prerequisites

None