1. Quality Factors of ESA --
1.3. Collin and Rothschild Q Analysis --
1.5. Radian Sphere with Mu and/or Epsilon: TE Modes --
1.6. Radian Sphere with Mu and/or Epsilon: TM Modes --
1.7. Effects of Core Losses --
1.8. Q for Spheroidal Enclosures --
2. Bandwidth and Matching --
2.2. Foster's Reactance Theorem and Smith Chart --
2.3. Fano's Matching Limitations --
2.4. Matching Circuit Loss Magnification --
2.5. Network and Z₀ Matching --
2.6. Non-Foster Matching Circuits --
2.7. Matched and High-Z Preamp Monopoles --
2.7.1. A Short Monopole Matched at One Frequency --
2.7.2. Short Monopole with High-Impedance Amplifier --
3. Electrically Small Antennas: Canonical Types --
3.2. Dipole Basic Characteristics --
3.2.1. Dipole Impedance and Bandwidth --
3.2.2. Resistive and Reactive Loading --
3.2.3. Other Loading Configurations --
3.2.4. Short Flat Resonant Dipoles --
3.2.5. Spherical Helix Antennas --
3.2.6. Multiple Resonance Antennas --
3.2.6.1. Spherical Dipole; Arc Antennas --
3.2.6.2. Multiple Mode Antennas --
3.2.6.3. Q Comparisons --
3.2.7. Evaluation of Moment Method Codes for Electrically Small Antennas --
3.3. Partial Sleeve, PIFA, and Patch --
3.3.3. Patch with Permeable Substrate --
3.4.1. Air Core Loops, Single and Multiple Turns --
3.4.2. Permeable Core Loops --
3.4.3. Receiving Loops --
3.5. Dielectric Resonator Antennas --
4. Clever Physics, But Bad Numbers --
4.1. Contrawound Toroidal Helix Antenna --
4.2. Transmission Line Antennas --
4.3. Halo, Hula Hoop, and DDRR Antennas --
4.4. Dielectric-Loaded Antennas --
4.5. Meanderline Antennas --
5. Pathological Antennas --
5.1. Crossed-Field Antenna --
5.2. Infinite Efficiency Antenna --
5.7. Loop-Coupled Loop --
5.9. Complementary Pair Antenna --
5.10. Integrated Antenna --
5.12. Antenna in a NIM Shell --
5.13. Fractal Antennas --
5.14. Antenna on a Chip --
5.15. Random Segment Antennas --
5.16. Multiple Multipoles --
5.17. Switched Loop Antennas --
5.18. Electrically Small Focal Spots --
6. Superdirective Antennas --
6.1. History and Motivation --
6.2. Maximum Directivity --
6.2.2.1. Broadside Arrays of Fixed Spacing --
6.2.2.2. Endfire Arrays --
6.2.2.3. Minimization Codes --
6.2.2.4. Resonant Endfire Arrays --
6.3. Constrained Superdirectivity --
6.3.1. Dolph-Chebyshev Superdirectivity --
6.3.2. Superdirective Ratio Constraint --
6.3.3. Bandwidth or Q Constraint --
6.3.4. Phase or Position Adjustment --
6.3.5. Tolerance Constraint --
6.4. Bandwidth, Efficiency, and Tolerances --
6.5. Miscellaneous Superdirectivity --
6.6. Superdirective Antenna Summary --
7. Superconducting Antennas --
7.2. Superconductivity Concepts for Antenna Engineers --
7.3. Dipole, Loop, and Patch Antennas --
7.3.1. Loop and Dipole Antennas --
7.3.2. Microstrip Antennas --
7.3.4. Millimeter-Wave Antennas --
7.3.4.1. Waveguide Flat Plane Array --
7.3.4.2. Microstrip Planar Array --
7.3.5. Submillimeter Antennas --
7.3.6. Low-Temperature Superconducting Antennas --
7.4. Phasers and Delay Lines --
7.5. Superconducting Antenna Summary --
Appendix A. A World History of Electrically Small Antennas --
Appendix B. Definitions of Terms Useful to ESA --
Appendix C. Spherical Shell of Eng Metamaterial Surrounding A Dipole Antenna --
Appendix D. Frequency Dispersion Limits Resolution in Veselago Lens --
