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....
Gespeichert in:
| Hauptverfasser: | , , |
|---|---|
| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Boston, MA :
Artech House,
[2018]
|
| Schriftenreihe: | Artech House microwave library.
|
| Schlagworte: | |
| Online-Zugang: | DE-862 DE-863 |
| Zusammenfassung: | 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. Practitioners also find concrete examples of microwave photonics implementations. The designs and concepts that cover conventional photonic instantaneous frequency measurement (IFM) circuits are explained. This book provides details on new designs for microwave photonic circuits and reconfigurable frequency measurement (RFM) circuits using diodes and MicroElectroMechanical Systems (MEMS).n nThis book explains the many diverse applications of frequency measurement that are used in defense, radar, and communications. The instrumentation used to perform frequency measurements is explained, including the use of block analysis for network and spectrum analyzers and calibration techniques. Readers learn the advantages of using frequency measurement based on microwave/RF techniques, including immunity to electromagnetic interference, low loss, compatibility with fiber signal distribution, and parallel processing signals. Moreover, readers gain insight into the future of frequency measurement receivers. The book examines both the underpinnings and the implementation of frequency measurement receivers using many diverse technological platforms. |
| Beschreibung: | 1 online resource : illustrations |
| Bibliographie: | Includes bibliographical references and index. |
| ISBN: | 9781630815165 1630815160 |
Internformat
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| 100 | 1 | |a Llamas-Garro, Ignacio, |e author. | |
| 245 | 1 | 0 | |a Frequency measurement technology / |c Ignacio Llamas-Garro, Marcos Tavares de Melo, Jung-Mu Kim. |
| 264 | 1 | |a Boston, MA : |b Artech House, |c [2018] | |
| 300 | |a 1 online resource : |b illustrations | ||
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| 588 | 0 | |a Print version record. | |
| 504 | |a Includes bibliographical references and index. | ||
| 520 | 3 | |a 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. Practitioners also find concrete examples of microwave photonics implementations. The designs and concepts that cover conventional photonic instantaneous frequency measurement (IFM) circuits are explained. This book provides details on new designs for microwave photonic circuits and reconfigurable frequency measurement (RFM) circuits using diodes and MicroElectroMechanical Systems (MEMS).n nThis book explains the many diverse applications of frequency measurement that are used in defense, radar, and communications. The instrumentation used to perform frequency measurements is explained, including the use of block analysis for network and spectrum analyzers and calibration techniques. Readers learn the advantages of using frequency measurement based on microwave/RF techniques, including immunity to electromagnetic interference, low loss, compatibility with fiber signal distribution, and parallel processing signals. Moreover, readers gain insight into the future of frequency measurement receivers. The book examines both the underpinnings and the implementation of frequency measurement receivers using many diverse technological platforms. |c Publisher abstract. | |
| 505 | 0 | |a 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. | |
| 505 | 8 | |a 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. | |
| 505 | 8 | |a 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. | |
| 505 | 8 | |a 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. | |
| 505 | 8 | |a 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. | |
| 650 | 0 | |a Microwaves |x Measurement. | |
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| 700 | 1 | |a Kim, Jung-Mu, |e author. | |
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Datensatz im Suchindex
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| _version_ | 1826942175509741568 |
| adam_text | |
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| author | Llamas-Garro, Ignacio Melo, Marcos Tavares de Kim, Jung-Mu |
| author_facet | Llamas-Garro, Ignacio Melo, Marcos Tavares de Kim, Jung-Mu |
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| collection | ZDB-4-EBA |
| contents | 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. |
| ctrlnum | (OCoLC)1027650045 |
| dewey-full | 621.3813 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 621 - Applied physics |
| dewey-raw | 621.3813 |
| dewey-search | 621.3813 |
| dewey-sort | 3621.3813 |
| dewey-tens | 620 - Engineering and allied operations |
| discipline | Elektrotechnik / Elektronik / Nachrichtentechnik |
| format | Electronic eBook |
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The technologies used in frequency measurement interferometry-based on-delay lines and filters are explored in this book. Practitioners also find concrete examples of microwave photonics implementations. The designs and concepts that cover conventional photonic instantaneous frequency measurement (IFM) circuits are explained. This book provides details on new designs for microwave photonic circuits and reconfigurable frequency measurement (RFM) circuits using diodes and MicroElectroMechanical Systems (MEMS).n nThis book explains the many diverse applications of frequency measurement that are used in defense, radar, and communications. The instrumentation used to perform frequency measurements is explained, including the use of block analysis for network and spectrum analyzers and calibration techniques. Readers learn the advantages of using frequency measurement based on microwave/RF techniques, including immunity to electromagnetic interference, low loss, compatibility with fiber signal distribution, and parallel processing signals. Moreover, readers gain insight into the future of frequency measurement receivers. The book examines both the underpinnings and the implementation of frequency measurement receivers using many diverse technological platforms.</subfield><subfield code="c">Publisher abstract.</subfield></datafield><datafield tag="505" ind1="0" ind2=" "><subfield code="a">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.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">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.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">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.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">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.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">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; 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| id | ZDB-4-EBA-on1027650045 |
| illustrated | Illustrated |
| indexdate | 2025-03-18T14:23:50Z |
| institution | BVB |
| isbn | 9781630815165 1630815160 |
| language | English |
| oclc_num | 1027650045 |
| open_access_boolean | |
| owner | MAIN DE-862 DE-BY-FWS DE-863 DE-BY-FWS |
| owner_facet | MAIN DE-862 DE-BY-FWS DE-863 DE-BY-FWS |
| physical | 1 online resource : illustrations |
| psigel | ZDB-4-EBA FWS_PDA_EBA ZDB-4-EBA |
| publishDate | 2018 |
| publishDateSearch | 2018 |
| publishDateSort | 2018 |
| publisher | Artech House, |
| record_format | marc |
| series | Artech House microwave library. |
| series2 | Artech microwave library |
| spelling | Llamas-Garro, Ignacio, author. Frequency measurement technology / Ignacio Llamas-Garro, Marcos Tavares de Melo, Jung-Mu Kim. Boston, MA : Artech House, [2018] 1 online resource : illustrations text txt rdacontent computer c rdamedia online resource cr rdacarrier Artech microwave library Print version record. Includes bibliographical references and index. 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. Practitioners also find concrete examples of microwave photonics implementations. The designs and concepts that cover conventional photonic instantaneous frequency measurement (IFM) circuits are explained. This book provides details on new designs for microwave photonic circuits and reconfigurable frequency measurement (RFM) circuits using diodes and MicroElectroMechanical Systems (MEMS).n nThis book explains the many diverse applications of frequency measurement that are used in defense, radar, and communications. The instrumentation used to perform frequency measurements is explained, including the use of block analysis for network and spectrum analyzers and calibration techniques. Readers learn the advantages of using frequency measurement based on microwave/RF techniques, including immunity to electromagnetic interference, low loss, compatibility with fiber signal distribution, and parallel processing signals. Moreover, readers gain insight into the future of frequency measurement receivers. The book examines both the underpinnings and the implementation of frequency measurement receivers using many diverse technological platforms. Publisher abstract. 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. Microwaves Measurement. Microwave devices. http://id.loc.gov/authorities/subjects/sh85084958 Frequency response (Electrical engineering) http://id.loc.gov/authorities/subjects/sh85051932 Dispositifs à micro-ondes. Réponse en fréquence (Génie électrique) TECHNOLOGY & ENGINEERING Mechanical. bisacsh Frequency response (Electrical engineering) fast Microwave devices fast Melo, Marcos Tavares de, author. Kim, Jung-Mu, author. has work: Frequency measurement technology (Text) https://id.oclc.org/worldcat/entity/E39PCGQjhb8PGdKJPWwmKm64mb https://id.oclc.org/worldcat/ontology/hasWork Print version: Llamas-Garro, Ignacio. Frequency measurement technology. Boston, MA : Artech House, [2018] 9781630811716 1630811718 (OCoLC)1021057371 Artech House microwave library. http://id.loc.gov/authorities/names/n42002465 |
| spellingShingle | Llamas-Garro, Ignacio Melo, Marcos Tavares de Kim, Jung-Mu Frequency measurement technology / Artech House microwave library. 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. Microwaves Measurement. Microwave devices. http://id.loc.gov/authorities/subjects/sh85084958 Frequency response (Electrical engineering) http://id.loc.gov/authorities/subjects/sh85051932 Dispositifs à micro-ondes. Réponse en fréquence (Génie électrique) TECHNOLOGY & ENGINEERING Mechanical. bisacsh Frequency response (Electrical engineering) fast Microwave devices fast |
| subject_GND | http://id.loc.gov/authorities/subjects/sh85084958 http://id.loc.gov/authorities/subjects/sh85051932 |
| title | Frequency measurement technology / |
| title_auth | Frequency measurement technology / |
| title_exact_search | Frequency measurement technology / |
| title_full | Frequency measurement technology / Ignacio Llamas-Garro, Marcos Tavares de Melo, Jung-Mu Kim. |
| title_fullStr | Frequency measurement technology / Ignacio Llamas-Garro, Marcos Tavares de Melo, Jung-Mu Kim. |
| title_full_unstemmed | Frequency measurement technology / Ignacio Llamas-Garro, Marcos Tavares de Melo, Jung-Mu Kim. |
| title_short | Frequency measurement technology / |
| title_sort | frequency measurement technology |
| topic | Microwaves Measurement. Microwave devices. http://id.loc.gov/authorities/subjects/sh85084958 Frequency response (Electrical engineering) http://id.loc.gov/authorities/subjects/sh85051932 Dispositifs à micro-ondes. Réponse en fréquence (Génie électrique) TECHNOLOGY & ENGINEERING Mechanical. bisacsh Frequency response (Electrical engineering) fast Microwave devices fast |
| topic_facet | Microwaves Measurement. Microwave devices. Frequency response (Electrical engineering) Dispositifs à micro-ondes. Réponse en fréquence (Génie électrique) TECHNOLOGY & ENGINEERING Mechanical. Microwave devices |
| work_keys_str_mv | AT llamasgarroignacio frequencymeasurementtechnology AT melomarcostavaresde frequencymeasurementtechnology AT kimjungmu frequencymeasurementtechnology |