Digital Communications: From Beginner to Expert

A Course Given in Most Universities to Teach Digital Communication Systems to Electrical & Computer Engineering Students

Learn the exact generic meaning of modulation and why we must have it in most telecom systems

Gain the ability to apply digital theorems for communication systems

Understand most common transmission techniques in digital communication systems

Identification of signals and modulation types in digital communication systems

Calculation of digital communication system performance

Design and analysis of efficient digital communication systems

Design of channel equalization and symbol synchronization systems

Interpret the results of numerical communication coding techniques according to performance analysis

The course gives a comprehensive and detailed view of the general structure of digital communication systems including transmitter and receiver designs as well as the different types of wireless channels that may be encountered in communication systems. In particular, it covers topics like real and complex random vectors, signal space representations, and advanced digital modulation/demodulation techniques such as ASK, PSK, FSK, BPSK, M-ASK, M-PSK, M-FSK, QPSK, QAM, OFDM, OFDM-IM, OFDM-SNM, OFDM-SPM, and MIMO-SM. In addition, the course will cover digital data transmission over noisy and fading channels, as well as the design of ideal transceivers for recovering the received data. Moreover, the calculation of key performance metrics in digital communication systems such as bit error probability, data rate, and throughput will also be explained and discussed in this course.

More specifically, the covered topics in the course are listed as follows:

  • Lesson  1: Introduction to the basic processing blocks in digital transceivers systems (source coding, channel coding, modulation, pulse selection, synchronization, detection, demodulation, decoding, equalization).
  • Lesson 2 – More details about basic processing blocks + Quantization and Analog to digital conversion (ADC).
  • Lesson 3 – Quantization Noise and its probability distribution function (PDF) in pulse code modulation (PCM).
  • Lesson 4 – Nonuniform Quantization + Advantages of PCM + Line codes & D-encoding.
  • Lesson 5 – Time Division Multiplexing (TDM).
  • Lesson 6 – Digital Multiplexers and their different types.
  • Lesson 7 – Delta modulation: Concept, Advantages, Disadvantages, and Solutions.
  • Lesson 8 – Linear Prediction Filters (LPC).
  • Lesson 9 – Base-band Pulse Transmission: Matched Filters.
  • Lesson 10 – Probability of Error over AWGN Channel.
  • Lesson 11 – Inter-Symbol Interference (ISI) and Raised Cosine Pulse Shaping Filter.
  • Lesson 12 – Correlative level (duo binary) coding for doubling channel capacity.
  • Lesson 13 – Addressing the drawbacks of Correlative level (duo binary) Coding.
  • Lesson 14 – Passband Data Transmission and Basic Concepts of Digital Modulation.
  • Lesson 15 – New types of carriers & features for digital modulation (IM, NM, SM).
  • Lesson 16 – Binary phase-shift keying (BPSK).
  • Lesson 17 – Quadrature phase-shift keying (QPSK).
  • Lesson 18 – Offset and Shifted Quadrature Phase-Shift Keying (OQPSK).
  • Lesson 19 – M-array phase-shift keying (MPSK) & M-array quadrature amplitude (MQAM).
  • Lesson 20 – Non-coherent modulation: Transmission & detection of non-coherent BFSK.
  • Lesson 21 – Non-coherent differential binary phase-shift keying (DBPSK) & detection.
  • Spatial Modulation and Index Modulation in MIMO Systems
  • Subcarrier Power Modulation in OFDM Systems

So, the course basically covers the general structure of Digital Communication systems, real and complex random vectors, signal space representations, digital modulation/demodulation techniques, digital data transmission over noisy channels and ideal receiver design, the bit error probability in digital data communication, techniques, and basic limits of data communication, entropy, channel capacity, and coding methods.

We are very excited to have you with us on this journey and look forward to seeing you enroll in this unique and interesting course.

For exploring related trainings given by the instructor, you may search for “Researcherstore” on Google or Bing.

======== About the Insturctor ===========

Jehad M. HAMAMREH (jehad.hamamreh@researcherstore.com) is the Founder and Director of WISLABi/com, Editor at Researcherstore/com & RS-OJICT journal, as well as A. Professor with the Electrical and Computer Engineering Department, Antalya International (Bilim) University. He earned his Ph.D. degree in Telecommunication Engineering and Cyber-Systems from Medipol University. Previously, he worked as a Researcher at the Department of Electrical and Computer Engineering at Texas A&M University. He is the inventor of more than 20 Patents and has authored more than 90 peer-reviewed scientific papers along with several book chapters. His innovative patented works won the gold, silver, and bronze medals in numerous international invention contests and fairs.

His current research interests include Wireless Communication, Wireless Security, Wireless Sensing, O-RAN, 5G/6G, IoT, AI/ML, wireless physical and MAC layers security, orthogonal frequency-division multiplexing (OFDM), multiple-input multiple-output systems (MIMO), advanced waveforms design, multidimensional modulation techniques, and orthogonal/non-orthogonal multiple access schemes for future wireless systems. He is a regular investigator and a referee for various scientific journals as well as a TPC member for several international conferences. He is an Editor at RS-OJICT and Frontiers in Communications and Networks.

Key Research Topics: Wireless Communication, Wireless Security, Wireless Sensing, Open RAN, 5G/6G, IoT-AI

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