Preface; Contents; 1 Introduction; Introduction; Spectrum Allocation Policies; Static Spectrum Allocation; Dynamic Spectrum Allocation; Cognitive Radio Technology; Cognitive Network Architecture; Network Architecture; Network Heterogeneity; Spectrum Management in CRNs; Spectrum Sensing; Challenges in Spectrum Sensing; Spectrum Allocation and Sharing; Spectrum Mobility; CR Applications; Conclusion; References; Spectrum Sensing for Half and Full-Duplex Cognitive Radio; Introduction; Performance Analysis; Energy Detector; Autocorrelation Detector; Cyclostationary Detector

Half and Full Duplex Cognitive RadioWork Objectives; Approaches Based on Cumulative Power Spectral Density; Introduction to the Power Spectral Density; Cumulative Power Spectral Density-Based Detector; Proposed Cooperative Detectors; Performance Evaluation; Gaussian Channel; Sensing Time; Rayleigh Channel; Complexity Analysis; Robustness of Our Proposed Detectors Under Noise Uncertainty; Spectrum Sensing Based on Self Normalized CPSD; Spectrum Sensing for Full-Duplex Cognitive Radio; System Model; Residual Self Interference Effect; Numerical Results; Conclusion; References

3 Dynamic Spectrum Access Algorithms Without Common Control ChannelsIntroduction for Dynamic Spectrum Access Algorithm; Background; A Channel Hopping System; Quorum System; Basic Theorems; Symmetric Available Channel Model; Homogeneous Role Algorithms; Asymmetric Available Channel Model; Heterogeneous Role Algorithms; Homogeneous Role Algorithms; Summary; References; Quantified Dynamic Spectrum Access Paradigm; Introduction; Motivation; MUSE: Characterizing and Quantifying the Use of Spectrum; How Is Spectrum Consumed?; System Model; MUSE: Definitions; Quantifying Spectrum Consumption

Quantifying a Spectrum Consumption SpaceCharacterizing and Quantifying Performance of the Spectrum Management Functions; MUSE: Illustration and Discussion; Quantification of a Spectrum Consumption Space; Quantification of a Spectrum-Management Space; Considerations While Applying MUSE; Applying MUSE: Maximizing the Use of Spectrum; Maximizing the Available Spectrum-Space; Maximizing the Exploitation of the Available Spectrum-Space; Dealing with RF-Environment Dynamicity; Quantified Dynamic Spectrum Access Paradigm; Primitives for Quantified Dynamic Spectrum Access

Defining and Regulating a Quantified Dynamic Spectrum-Access PolicyAn Example Spectrum Management Infrastructure for Quantified Dynamic Spectrum Sharing; Quantified Dynamic Spectrum Management; Towards Real-Time Quantified Dynamic Spectrum-Access; Estimating the Use of the Spectrum; Estimating the Transmitter Spectrum-Access Attributes; Characterizing the Propagation Environment; Estimating Spectrum Occupancy and Spectrum Opportunity; Illustration; Defining and Enforcing a Quantified Spectrum Access Policy; Benefits of the Quantified Dynamic Spectrum Sharing Paradigm