Principles Of Mobile Communication Stuber Solution Manual
Kaja Salmons
Principles of Mobile Communication: A Review
If you are looking for a textbook that covers the fundamentals and principles of wireless communication, you might want to check out Principles of Mobile Communication by Gordon L. Stüber. This book is a mathematically rigorous overview of physical layer wireless communications, suitable for university graduate-level courses or in-depth research.
What does the book offer?
The book offers a comprehensive and updated treatment of various topics related to mobile communication, such as:
- Radio propagation modeling
- Co-channel interference
- Modulation and power spectrum
- Detection of known signals in noise
- Multi-antenna techniques
- Time domain equalization and interference cancelation
- Error control coding
- Spread spectrum techniques
- Multi-carrier techniques
- Frequency planning techniques
- CDMA cellular systems
- Radio resource management
- Channel assignment techniques
The book also includes new content on 4G cellular systems, 5G cellular outlook, bandpass signals and systems, and polarization, among many other topics. The book begins with a survey of the field, introducing issues relevant to wireless communications. The book then moves on to cover relevant discrete subjects, with homework problems at the end of each chapter. An appendix provides a tutorial on probability and random processes. The content stresses core principles that are applicable to a broad range of wireless standards.
Why should you read this book?
This book is a valuable resource for anyone who wants to learn more about the theory and practice of mobile communication. The book provides a clear and rigorous exposition of the concepts and techniques involved in wireless communication, with examples and illustrations to help the reader understand the more complex material. The book also covers the latest developments and trends in the field, giving the reader a glimpse of the future of mobile communication. The book is suitable for both novice and advanced students, as well as researchers and practitioners who want to deepen their knowledge and skills in wireless communication.
How can you get this book?
You can get this book from various online platforms, such as SpringerLink, Chegg, or Microsoft Sway. You can also find the solution manual for this book on some websites or forums, such as Reddit. However, you should be careful about the quality and authenticity of the solution manual, as some of them might be incomplete or incorrect. You should always try to solve the problems by yourself first, before consulting the solution manual.
Conclusion
Principles of Mobile Communication by Gordon L. Stüber is a comprehensive and updated textbook that covers the fundamentals and principles of wireless communication. The book is suitable for university graduate-level courses or in-depth research on mobile communication. The book offers a clear and rigorous exposition of various topics related to wireless communication, with examples, illustrations, and homework problems. The book also includes new content on 4G cellular systems, 5G cellular outlook, bandpass signals and systems, and polarization, among many other topics. The book is a valuable resource for anyone who wants to learn more about the theory and practice of mobile communication.
The advantages and disadvantages of different wireless communication techniques
Wireless communication techniques can be classified into different categories, such as modulation, coding, multiple access, multiplexing, diversity, etc. Each technique has its own advantages and disadvantages, depending on the application and the channel conditions. For example:
- Modulation is the process of changing the characteristics of a carrier signal according to the information signal. Modulation can be analog or digital, and can use different schemes, such as amplitude modulation (AM), frequency modulation (FM), phase modulation (PM), quadrature amplitude modulation (QAM), etc. Modulation can improve the efficiency and reliability of wireless communication, but it also introduces complexity and noise.
- Coding is the process of adding redundancy to the information signal to protect it from errors and interference. Coding can be channel coding or source coding. Channel coding adds extra bits to the information signal to enable error detection and correction. Source coding compresses the information signal to reduce its size and bandwidth. Coding can improve the quality and security of wireless communication, but it also introduces delay and overhead.
- Multiple access is the process of allowing multiple users to share the same wireless channel. Multiple access can use different techniques, such as frequency division multiple access (FDMA), time division multiple access (TDMA), code division multiple access (CDMA), orthogonal frequency division multiple access (OFDMA), etc. Multiple access can increase the capacity and flexibility of wireless communication, but it also introduces interference and complexity.
- Multiplexing is the process of combining multiple signals into one signal for transmission over a single channel. Multiplexing can use different techniques, such as frequency division multiplexing (FDM), time division multiplexing (TDM), code division multiplexing (CDM), orthogonal frequency division multiplexing (OFDM), etc. Multiplexing can improve the efficiency and robustness of wireless communication, but it also introduces distortion and synchronization issues.
- Diversity is the process of using multiple paths or sources to transmit or receive the same signal. Diversity can use different techniques, such as spatial diversity, frequency diversity, time diversity, polarization diversity, etc. Diversity can improve the reliability and performance of wireless communication, but it also introduces complexity and cost.
The challenges and opportunities of 5G cellular systems
5G cellular systems are the next generation of mobile communication systems that aim to provide higher data rates, lower latency, higher reliability, lower power consumption, and more connectivity than 4G cellular systems. 5G cellular systems are expected to support various applications and services, such as enhanced mobile broadband (eMBB), massive machine type communication (mMTC), ultra-reliable low-latency communication (URLLC), etc. 5G cellular systems face many challenges and opportunities, such as:
- Spectrum scarcity: The demand for wireless spectrum is increasing rapidly due to the growth of mobile devices and applications. However, the available spectrum is limited and expensive. 5G cellular systems need to use more spectrum efficiently and flexibly, by exploiting new frequency bands (such as millimeter wave and terahertz), new waveforms (such as filter bank multicarrier and non-orthogonal multiple access), new architectures (such as heterogeneous networks and cloud radio access networks), etc.
- Energy efficiency: The energy consumption of wireless devices and networks is increasing due to the higher data rates and complexity of 5G cellular systems. However, the battery life and power supply of wireless devices are limited and costly. 5G cellular systems need to reduce energy consumption and increase energy efficiency, by using new techniques (such as green communications and networking, energy harvesting and transfer, device-to-device communication, etc.), new protocols (such as cooperative communication and network coding), new standards (such as IEEE 802.11ax and IEEE 802.15.4z), etc.
- Security and privacy: The security and privacy of wireless users and data are becoming more important due to the proliferation of mobile devices and applications. However, the wireless channel is vulnerable to various attacks and threats, such as eavesdropping, jamming, spoofing, etc. 5G cellular systems need to enhance security and privacy by using new techniques (such as physical layer security, quantum cryptography, blockchain technology, etc.), new protocols (such as authentication, encryption, key management, etc.), new regulations (such as General Data Protection Regulation (GDPR) and California Consumer Privacy Act (CCPA)), etc.
The applications and implications of mobile communication for various domains
Mobile communication has revolutionized various domains, such as health, education, business, entertainment, etc. Mobile communication enables new applications and services that improve the quality of life and productivity of people. For example:
- Health: Mobile communication enables remote health monitoring and diagnosis, telemedicine and telehealth, wearable and implantable devices, mobile health apps, etc. Mobile communication can improve the accessibility and affordability of health care, as well as the prevention and treatment of diseases.
- Education: Mobile communication enables online learning and education, massive open online courses (MOOCs), mobile learning apps, augmented and virtual reality, etc. Mobile communication can enhance the availability and effectiveness of education, as well as the collaboration and interaction of learners and educators.
- Business: Mobile communication enables e-commerce and m-commerce, mobile banking and payment, mobile marketing and advertising, mobile workforce and management, etc. Mobile communication can increase the efficiency and profitability of business, as well as the customer satisfaction and loyalty.
- Entertainment: Mobile communication enables social media and networking, online gaming and gambling, streaming media and video on demand, mobile music and video, etc. Mobile communication can enrich the diversity and enjoyment of entertainment, as well as the creativity and expression of users.
However, mobile communication also poses some challenges and risks for various domains, such as ethical issues, legal issues, social issues, environmental issues, etc. Mobile communication can affect the privacy and security of users and data, the quality and reliability of services and products, the fairness and equality of access and opportunities, the sustainability and responsibility of resources and consumption, etc.
The comparison and contrast of different wireless communication standards
Wireless communication standards are sets of specifications that define the protocols and parameters for wireless communication systems. Wireless communication standards can be classified into different categories, such as cellular standards, local area network (LAN) standards, personal area network (PAN) standards, etc. Each standard has its own advantages and disadvantages, depending on the application and the environment. For example:
- Cellular standards: Cellular standards are wireless communication standards that provide wide area coverage and mobility for mobile devices. Cellular standards include 2G (such as GSM), 3G (such as UMTS), 4G (such as LTE), 5G (such as NR), etc. Cellular standards can provide high data rates, low latency, high reliability, low power consumption, and more connectivity than other wireless communication standards. However, cellular standards also require complex infrastructure, expensive spectrum licenses, high energy consumption, and strict regulations.
- LAN standards: LAN standards are wireless communication standards that provide local area coverage and connectivity for fixed or portable devices. LAN standards include IEEE 802.11 (such as Wi-Fi), IEEE 802.16 (such as WiMAX), IEEE 802.22 (such as WRAN), etc. LAN standards can provide higher data rates, lower latency, lower cost, and more flexibility than cellular standards. However, LAN standards also have limited coverage range, limited mobility support, limited security features, and interference issues.
- PAN standards: PAN standards are wireless communication standards that provide personal area coverage and connectivity for wearable or handheld devices. PAN standards include IEEE 802.15 (such as Bluetooth), IEEE 802.15.4 (such as ZigBee), IEEE 802.15.6 (such as WBAN), etc. PAN standards can provide lower data rates, lower power consumption, lower cost, and more compatibility than other wireless communication standards. However, PAN standards also have very limited coverage range, very limited data capacity,