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Frequency measurement technology /
This unique first-of-its-kind resource provides practical coverage of the design and implementation of frequency measurement receivers, which aid in identifying unknown signals. The technologies used in frequency measurement interferometry-based on-delay lines and filters are explored in this book....
| Clasificación: | Libro Electrónico |
|---|---|
| Autores principales: | , , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Boston, MA :
Artech House,
[2018]
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| Colección: | Artech House microwave library.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Frequency Measurement Technology; Contents; Preface; Chapter 1 Frequency Measurement Fundamentals; 1.1 OVERVIEW; 1.2 INTRODUCTION TO RF/MICROWAVE FREQUENCY MEASUREMENT; 1.2.1 RF/microwave Measurement Theory; 1.2.2 Frequency Measurement Instrumentation; 1.2.3 Frequency Detection Architectures; References; Chapter 2 Instantaneous Frequency Measurement; 2.1 OVERVIEW; 2.2 INTRODUCTION TO INSTANTANEOUS FREQUENCY MEASUREMENT; 2.3 IFM RECEIVERS; 2.3.1 Analog Frequency Discriminators; 2.3.2 Digital Frequency Discriminators; 2.4 IFM DESIGNS; 2.4.1 IFM Using Interferometers Based on Delay Lines.
- 2.4.2 IFM Using Multiband-stop Filters2.5 CONCLUSIONS AND FUTURE WORK; References; Chapter 3 Reconfigurable Frequency Measurement; 3.1 OVERVIEW; 3.2 INTRODUCTION TO RFM; 3.3 RFM RECEIVER ARCHITECTURES; 3.3.1 Block Diagrams and Components of an RFM Receiver; 3.3.2 A Comparison between IFM and RFM; 3.3.3 Elements for Reconfiguration; 3.4 RFM DESIGNS; 3.4.1 RFM Using PIN Diodes with 2 Bits for Frequency Identification; 3.4.2 RFM Using PIN Diodes with 4 Bits for Frequency Identification; 3.5 CONCLUSIONS; References; Chapter 4 Photonic Instantaneous Frequency Measurement; 4.1 OVERVIEW.
- 4.2 INTRODUCTION TO RF/MICROWAVE FREQUENCY MEASUREMENT4.3 IFM PRINCIPLE; 4.3.1 Electronic IFM; 4.3.2 Photonic IFM; 4.4 IFM BASED ON OPTICAL INTERFEROMETRY; 4.4.1 IFM Based on Noncoherent Optical Delays; 4.4.2 IFM Based on Coherent Optical Delays; 4.5 IFM BASED ON POLARIZATION EFFECTS; 4.5.1 IFM Based on Measurement of Stokes Parameters; 4.5.2 IFM Based on Polarization Interferometers; 4.5.3 IFM Based on Polarization Modulator and Polarization Adjustments; 4.5.4 IFM Based on Polarization Modulators and Modulation Bias Adjustments; 4.5.5 IFM Based on Polarization Modulator and Dispersion.
- 4.5.6 IFM Based on Polarization Microwave Photonic Filter Pairs4.6 IFM BASED ON OPTICAL FILTERING; 4.6.1 IFM Based on Mach-Zehnder Interferometer Optical Filters; 4.6.2 IFM Based on Ring-resonator Optical Filters; 4.6.3 IFM Based on the Bragg Grating Optical Filters; 4.7 IFM BASED ON FREQUENCY TO TIME MAPPING; 4.7.1 Single RF Signal Measurement; 4.7.2 Multiple RF Signal Measurement; 4.8 IFM BASED ON OPTICAL MIXING; 4.8.1 IFM Based on Optoelectrical Mixing; 4.8.2 IFM Based on All Optical Mixing; 4.9 IFM BASED ON STIMULATED BRILLOUIN SCATTERING.
- 4.9.1 Stimulated Brillouin Scattering in Optical Fibers4.9.2 IFM Based on SBS Resonance Shift; 4.9.3 IFM Based on SBS Resonance and Channelizing Probe Array; 4.9.4 IFM Based on SBS Resonance Channelizers; 4.10 OTHER PHOTONIC IFM APPROACHES; 4.10.1 IFM Based on Microwave Photonic Filters; 4.10.2 IFM Based on Quadrature Optical Filter Pairs; 4.10.3 IFM Based on a Bank of Offset Optical Filters; 4.10.4 IFM Based on Phase to Intensity Modulation Conversions; 4.10.5 IFM Based on Photonic Assisted Samplings and Downconversions; 4.11 DISCUSSION; 4.12 CONCLUSION; References; About the Authors; Index.