Day 1

Rayleigh Fading Channel and Baseband Nyquist Signaling

The course begins with a description of the channel models for mobile wireless and wireline systems. This is followed by discussions of Nyquist baseband signaling, as well as ISI and linear equalization.

• “A Bit of History”
• Discussion of the Challenges Facing the Sixth Generation (6G)
• Introduction to Analog and Digital Communications
• System Model-The Channel
• The Multipath Channel (Rayleigh, Delay Spread and Frequency-Selective Fading)
• Introduction to Diversity Techniques-Antenna Diversity and Coding
• Twisted-Pair Channel

Brief Review of Fourier Transform, Power Spectral Density, White Noise

Nyquist Signaling

• ISI, Optimum Filtering, Square-Root Nyquist Filtering, Linear Equalization
• Partial Response Signals-Why the MLSE and the Viterbi Algorithm?
• What is “faster-than-Nyquist” Signaling?

Day 2

Signal Space, Optimum Detection

The concept of signal space is used to define the classical modulation techniques and derive the optimum detectors.

Signal Space, Optimum Detection

• Signal Space
• BPSK, QPSK, MPSK, QAM, BFSK and MFSK-Definitions
• Optimum Detection of Binary Signals and Probability of Error
• Matched Filter

The Rayleigh Fading Channel and Antenna Diversity-BLAST, MIMO

An in-depth discussion of the performance of modulations, transmitted over Rayleigh fading channels, followed by a discussion of the concept of space diversity (BLAST, MIMO and Massive MIMO), which is used to greatly improve spectral efficiency.

• Detectability Performance of BPSK over Rayleigh Fading Channel (SISO)
• Classic Antenna Diversity (SIMO)
• Space Diversity
• MIMO
• BLAST
• Massive MIMO-What is it? What can be gained?

Day 3

MSK-type Signals

QPSK, SQPSK, and MSK are essentially constant envelope modulations, which are used in many satellite and wireless systems.

• QPSK, SQPSK, pi/4 – QPSK, EDGE “8PSK”, π/2-BPSK
• MSK-type (MSK, SFSK) Signals
• Adjacent Channel Interference (ACI)

M-ary Signals

M-ary signals are used in many systems, e.g., analog modems, ADSL, VDSL, microwave radio, and are the basic modulation of almost all OFDM systems.

• Optimum Detection of M-ary Signals
• MPSK
• Quadrature Amplitude Modulation (QAM)-Nyquist Signaling
• Offset QAM-OQAM- 6G Modulation Proposals
• MFSK

Shannon Information Theory

Shannon information theory is the basis behind much of what we do in communications including, coding, analog modems, ADSL, multitone modulation (DMT), OFDM, and adaptive modulation and coding. OFDM (DMT) is the modulation for 5G-NR, 4G-LTE, IEEE 802.11 (Wi-Fi 6 and 7), as well as ADSL and VDSL. We present an in-depth discussion of multitone modulation, DMT, OFDM, OFDMA, Scalable OFDMA and SC-FDMA. Then we will discuss the Radio Interfaces of 5G-NR, 4G-LTE and IEEE802.11., which are all based on OFDM. 

 Introduction to Shannon Information Theory

• Channel Capacity for Ideal and General Gaussian Channels

Multitone-DMT

• Discrete Multitone (DMT) – Implementation
• The Twisted Pair Channel
• Multitone (DMT) over the Twisted Pair Channel (ADSL and VDSL)

OFDM-Orthogonal Frequency Division Multiplexing

• OFDM – for Broadband Wireless Communications
• Adaptive Modulation and Coding Techniques
• OFDMA as a Multiple Access Technique
• Scalable OFDMA

• SC-FDMA (Single-Carrier FDMA-4G-LTE)
• OFDM-MIMO

Physical Interfaces of IEEE 802.11 (Wi-Fi 6 and 7), 4G-LTE and 5G-NR (including 2ⁿ numerology)

• Wi—Fi 6 and 7
• 3G-LTE, 4G-LTE,5G-NR
• 6G (?)

Day 4

Trellis Coding, Convolutional Coding and The Viterbi Algorithm

We continue with a description of trellis coded modulation concepts and convolutional coding, including a discussion of the Viterbi Algorithm. We also include the topic of interleaving for improving the performance of modulations on Rayleigh fading channels.

• The Viterbi Algorithm (VA)
• Ungerboeck Trellis Coding
• The VA Equalizer
• Interleaving for Rayleigh Fading
• Performance on the Rayleigh Fading Channel
• Convolutional Coding

“Faster-Than-Nyquist (FTN) Signaling” and Other Modulation Proposals for 6G

• What is FTN?
• What is its performance?
• Index Modulation and OTFS

Turbo-Coding-Introduction

A topic of increasing importance is the turbo-coding (iterative decoding) concept and its use in areas such as antenna diversity, equalization and OFDM.

• Turbo Coding
• Iterative Decoding Techniques
• Turbo-Equalization
• Introduction to LDPC Codes

Capacity of Rayleigh Fading Channels

Shannon’s work has been updated to include bounds on the performance of Rayleigh fading channels. This work led to the concept of MIMO and space-time (Alamouti) coding.

• Bounds on Communications for Fading Channels
• OFDM-MIMO-Coding
• Space-Time Coding
• Alamouti Coding
• Multi-User Diversity Techniques

Day 5

Continuous Phase Modulations (CPM)

CPM signals (e.g., GMSK) are constant envelope, bandwidth efficient modulations, suitable for use with nonlinear power efficient, transmitting power amplifiers. These modulations are used in GSM and deep space communications, as well as Bluetooth.

• Continuous Phase Modulation (CPM)
• Gaussian MSK (GMSK)
• Tamed FM (TFM)
• Generalized TFM (GTFM)
• Constant Envelope OFDM
• Adjacent Channel Crosstalk in CPM Signals

Non-Coherent Detection

• DPSK
• FM Detection of CPM Signals-Bluetooth, DECT

CDMA and WCDMA

We continue with a discussion of CDMA and WCDMA, and describe the radio interfaces of the IMT-2000 WCDMA system, as well as the physical interface of IS-95.

• The RAKE Receiver
• Pseudo-Random Sequences
• Power Control
• Intra and Inter-Cell Interference and Capacity
• IS-95 Physical Interface
• IMT-2000 WCDMA Physical Interface: Walsh and OVSF Functions

 Summary and the Future