Friday, December 16, 2016

Prostate Cancer News - 2016-12

Prostate Cancer News - 2016-12

General News

About prostate cancer research, cases and public awareness:

Case Management

Planning a campaign against prostate cancer:

Life Choices

can influence the odds in your favor:

Diet

can starve the cancer

Exercise

can give you strength to fight the cancer and treatment side effects

Screening and Diagnosis

early detection is important because symptoms appear too late for treatment:

Biopsies and Pathology

Genomics

Tests

Imaging


Treatment

Active Surveillance AS


Surgery RP

frequently the first choice for localized PCa, robotic assist dominates:

Radiation RT

Hormone ADT


Chemo


Immunotherapy

New Techniques

Side Effects


Advanced/Recurrence


Saturday, December 10, 2016

PRN Mixing Radar tracks diode tagged bees

Animal migration tracking: how did we get to bee backpacks? | Alphr
Bee Searching Radar With High Transmit–Receive Isolation Using Pulse Pseudorandom Code - IEEE Xplore Document
M. L. Hsu et al., "Bee Searching Radar With High Transmit–Receive Isolation Using Pulse Pseudorandom Code," in IEEE Transactions on Microwave Theory and Techniques, vol. 64, no. 12, pp. 4324-4335, Dec. 2016.
doi: 10.1109/TMTT.2016.2613531Abstract:
This paper presents an innovative radar architecture to improve the isolation of the harmonic radar between the transmitter and the receiver. The proposed radar transmits two closely located frequencies to the transponder, and the transponder transmits a response signal at a mixed frequency. Because the frequency of the response signal is different from those of the clutter and leakage signals, the isolation is significantly improved. For a traditional harmonic radar, the leakage signals should be suppressed to a sensitivity lower than −106 dBm to avoid interference. The proposed radar requires only attenuation of  leakage signals to a level lower than −8 dBm to avoid low-noise amplifier saturation. Harmonic radar transponders are compatible with the proposed radar system without additional design. This paper also proposes a new method for maintaining the correlation of transmitter and receiver phase noise. Field test results demonstrate that leakage signal interference in the proposed radar is far lower than that in the harmonic radar. The significant improvement in isolation reveals the advantages of applying the frequency mixing concept in the proposed radar.
keywords: {Harmonic analysis; Radar; Receivers; Sensitivity; Transceivers; Transmitters; Transponders; Clutter; harmonic radar; leakage signal; phase noise; pseudorandom (PRN) code; transmitter to receiver isolation},
URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7592458&isnumber=7777000
VII. CONCLUSION
A new technique called mixing radar is proposed to improve the isolation and succeed the PRN code positioning technique. The mixing radar transmits two close fundamental frequencies to a transponder and receives the mixed frequency to distinguish the surrounding clutter and the leakage signals from the transmitter. The transponder used in the harmonic radar is compatible with the mixing radar system without additional design. To keep the transmitter and the receiver correlated, a
new LO architecture was proposed and verified. The performance of the harmonic radar and mixing radar was compared in a field test. Both radar systems could accurately measure the distances of multiple transponders; however, the leakage signal interference in the mixing radar was far lower than that in the harmonic radar. Therefore, the proposed mixing radar was confirmed to significantly improve the isolation between the transmitter and the receiver and retain the advantage of the PRN code positioning technique.

Related/Background:

  1. V. Melnikov, M. Leskinen and J. Koistinen, "Doppler Velocities at Orthogonal Polarizations in Radar Echoes From Insects and Birds," in IEEE Geoscience and Remote Sensing Letters, vol. 11, no. 3, pp. 592-596, March 2014.
    doi: 10.1109/LGRS.2013.2272011
    Abstract: The differential Doppler velocities (DDVs) measured with weather radar at horizontal and vertical polarizations in echoes from insects and birds are considered. In weather echoes, DDV is usually less than 0.5 ms- 1, whereas in echoes from flying birds and insects, it can reach 5-7 ms- 1. Such large difference can be used as an additional parameter in distinguishing between weather and nonmeteorological echoes. It is shown that large values of DDV pertain to multipeaked Doppler spectra with different spectral differential reflectivity values in the peaks.
    keywords: {Doppler radar;meteorological radar;radar polarimetry;Doppler spectra;Doppler velocitiy;differential Doppler velocities;flying birds;nonmeteorological echo;orthogonal polarizations;radar echoes;spectral differential reflectivity;weather echoes;weather radar;Birds;Doppler effect;Doppler radar;Insects;Meteorology;Radar polarimetry;Differential Doppler velocity (DDV);radar echo from birds and insects;radar polarimetry},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6567947&isnumber=6675037
  2. V. A. Drake, "Signal processing for ZLC-configuration insect-monitoring radars: Yields and sample biases," 2013 International Conference on Radar, Adelaide, SA, 2013, pp. 298-303.
    1. doi: 10.1109/RADAR.2013.6652002
    2. Abstract: A radar design that has proved effective for monitoring insect migratory flights employs a vertical beam in which rotating linear polarization is combined with a very narrow-angle conical scan - the “ZLC configuration”. The rather complicated echo-intensity time series produced when an individual insect traverses the radar's beam contains information about the insect's size, shape, orientation, and trajectory. However, retrieval of the various parameters is not always successful and some types of targets and target traverses are more vulnerable to processing failure than others. Variations in the ability of a profiling radar to detect targets of different sizes and at different heights are understood and can be corrected for if the target sizes and speeds are known (as is the case with a fully analyzed ZLC echo), but differences in processing success rates represent an additional source of bias. This preliminary study identifies height, the peak signal intensity, and target numbers as factors affecting processing yield, and presents some examples to illustrate how they act. These three quantities are available for all detected targets, as is required for use in any scheme for taking account of processing losses when generating profiles of target density (and other measures of insect activity of value to entomologists).
    3. keywords: {radar cross-sections;radar detection;radar signal processing;time series;zoology;ZLC configuration;ZLC echo;ZLC-configuration insect-monitoring radars;echo-intensity time series;entomologists;insect migratory flight monitoring;narrow-angle conical scan;peak signal intensity;profiling radar;radar beam;radar design;rotating linear polarization;signal processing;target density;target detection;vertical beam;Insects;Monitoring;Noise;Radar cross-sections;Receivers;Time series analysis;bias;density profile;insect;processing yield;radar},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6652002&isnumber=6651936
  3. N. Tahir and G. Brooker, "The investigation of millimetre wave optical harmonic transponders and radar for monitoring small insects," 2013 IEEE Topical Conference on Wireless Sensors and Sensor Networks (WiSNet), Austin, TX, 2013, pp. 22-24.
    1. doi: 10.1109/WiSNet.2013.6488621
    2. Abstract: The paper investigates the use of millimetre wave optical harmonic transponders for tracking small insects. Their small dimensions (5.15mm × 2.91mm), low profile, and low weight (~10mg) make them suitable for monitoring small insects. It provides 5dB and 3dB improvement in conversion gain under no illumination when illuminated by red laser without and with 0.9OD neutral density filter respectively. Its associated low power harmonic radar can be portable due to the small size of the millimetre wave components. So far, the prototype radar operating in CW mode has detected optical transponders up to a range of 1m. The detection range, and range resolution can be improved by increasing the radar antenna gains and improving the receiver noise floor by introducing a frequency modulation technique and reducing the receiver bandwidth.
    3. keywords: {CW radar;FM radar;low-power electronics;microstrip antennas;microwave photonics;millimetre wave antennas;millimetre wave radar;monitoring;optical harmonic generation;radar antennas;radar detection;radar receivers;radar resolution;radar tracking;radiofrequency identification;transponders;CW mode operation;conversion gain improvement;detection range improvement;frequency modulation technique;low power harmonic radar;millimetre wave optical harmonic transponders;millimetre wave radar;neutral density filter;radar antenna gain;radiofrequency identification;range resolution improvement;receiver bandwidth reduction;receiver noise floor improvement;red laser;small insects monitoring;small insects tracking;Harmonic analysis;Laser radar;Optical filters;Power harmonic filters;Radar antennas;Transponders;Microstrip antennas;Radiofrequency identification;millimetre wave radar;transponder},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6488621&isnumber=6488600
  4. J. R. Riley, "Angular and temporal variations in the radar cross-sections of insects," in Electrical Engineers, Proceedings of the Institution of, vol. 120, no. 10, pp. 1229-1232, October 1973.
    1. doi: 10.1049/piee.1973.0251
    2. Abstract:
    3. keywords: {radar applications;radar cross-sections;zoology;angular variations;insects;measurements;radar cross sections;temporal variations},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=5251797&isnumber=5250929
  5. D. Psychoudakis, W. Moulder, C. C. Chen, H. Zhu and J. L. Volakis, "A Portable Low-Power Harmonic Radar System and Conformal Tag for Insect Tracking," in IEEE Antennas and Wireless Propagation Letters, vol. 7, no. , pp. 444-447, 2008.
    1. doi: 10.1109/LAWP.2008.2004512
    2. Abstract: Harmonic radar systems provide an effective modality for tracking insect behavior. This letter presents a harmonic radar system proposed to track the migration of the Emerald Ash Borer (EAB). The system offers a unique combination of portability, low power and small tag design. It is comprised of a compact radar unit and a passive RF tag for mounting on the insect. The radar unit transmits a 5.96 GHz signal and detects at the 11.812 GHz band. A prototype of the radar unit was built and tested, and a new small tag was designed for the application. The new tag offers improved harmonic conversion efficiency and much smaller size as compared to previous harmonic radar systems for tracking insects. Unlike RFID detectors whose sensitivity allows detection up to a few meters, the developed radar can detect a tagged insect up to 58 m (190 ft).
    3. keywords: {biological techniques;low-power electronics;radar detection;radar tracking;conformal tag;emerald ash borer;frequency 11.8 GHz to 12.0 GHz;frequency 5.9 GHz to 6.0 GHz;harmonic radar systems;insect behavior tracking;insect tracking;portable low-power harmonic radar system;Harmonic radar;insect tracking;radar;radio frequency identification (RFID)},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=4601472&isnumber=4446029
  6. S. E. Hobbs and A. C. Aldhous, "Insect ventral radar cross-section polarisation dependence measurements for radar entomology," in IEE Proceedings - Radar, Sonar and Navigation, vol. 153, no. 6, pp. 502-508, December 2006.
    1. doi: 10.1049/ip-rsn:20060019
    2. Abstract: Radar entomology has developed such that routine long-term monitoring of insect flight through the atmospheric boundary layer is now practical. Typical entomological radars use X-band (9.4 GHz) marine transceivers with a vertical pencil beam and rotate the plane of polarisation about the beam axis. Ideally, insect species and other parameters (mass etc.) should be estimated from the measured radar cross-section variation with polarisation angle. For this, a library of known insect cross-section polarisation signatures is required. Two models are currently used to parameterise the polarisation signature: the harmonic model and a model using the scattering matrix for symmetric targets (SM3). Data from the literature and a doctoral research project are presented and analysed to obtain parameters for both the harmonic and SM3 models. Knowledge of the measurement errors allows SM3 parameter uncertainties to be quantified in most cases using a maximum likelihood approach. Results for 68 insects representing 24 species are presented. These include several economically significant species (e.g. bees and locusts), with individual insect masses ranging from 9 mg to 3 g
    3. keywords: {S-matrix theory;electromagnetic wave polarisation;harmonic analysis;marine radar;maximum likelihood estimation;measurement errors;radar cross-sections;radar polarimetry;remote sensing by radar;SMS model;X-band marine transceiver;atmospheric boundary layer;harmonic model;insect ventral radar cross-section;maximum likelihood approach;measurement error;polarisation dependence measurement;polarisation signature;radar entomology;scattering matrix;symmetric target;vertical pencil beam},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=4027866&isnumber=4027860
  7. C. R. Vaughn, "Birds and insects as radar targets: A review," in Proceedings of the IEEE, vol. 73, no. 2, pp. 205-227, Feb. 1985.
    1. doi: 10.1109/PROC.1985.13134
    2. Abstract: A review of radar cross-section measurements of birds and insects is presented. A brief discussion of some possible theoretical models is also given and comparisons made with the measurements. The comparisons suggest that most targets are, at present, better modeled by a prolate spheroid having a length-to-width ratio between 3 and 10 than by the often used equivalent weight water sphere. In addition, many targets observed with linear horizontal polarization have maximum cross sections much better estimated by a resonant half-wave dipole than by a water sphere. Also considered are birds and insects in the aggregate as a local radar "clutter" source. Order-of-magnitude estimates are given for many reasonable target number densities. These estimates are then used to predict X-band volume reflectivities. Other topics that are of interest to the radar engineer are discussed, including the doppler bandwidth due to the internal motions of a single bird, the radar cross-section probability densities of single birds and insects, the variability of the functional form of the probability density functions, and the Fourier spectra of single birds and insects.
    3. keywords: {Aggregates;Bandwidth;Birds;Clutter;Doppler radar;Insects;Polarization;Radar cross section;Reflectivity;Resonance},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1457402&isnumber=31346
  8. J. R. Riley, "Radar cross section of insects," in Proceedings of the IEEE, vol. 73, no. 2, pp. 228-232, Feb. 1985.
    1. doi: 10.1109/PROC.1985.13135
    2. Abstract: X-band measurements of radar cross section as a function of the angle between insect body axis and the plane of polarization are presented. A finding of particular interest is that in larger insects, maximum cross section occurs when the E-vector is perpendicular to the body axis. A new range of measurements on small insects (aphids and planthoppers) is also described, and a comprehensive summary of insect cross-section data at X-band is given.
    3. keywords: {Apertures;Calibration;Insects;Polarization;Radar cross section;Radar measurements;Rotation measurement;Shape measurement;Time measurement;Transmission line measurements},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1457403&isnumber=31346
  9. J. H. Richter and D. R. Jensen, "Radar cross-section measurements of insects," in Proceedings of the IEEE, vol. 61, no. 1, pp. 143-144, Jan. 1973.
    1. doi: 10.1109/PROC.1973.8997
    2. Abstract: A simple method to measure backscatter cross sections of live insects at 10-cm wavelength using an ultra-high resolution scanning FM-CW tropospheric radar sounder is described. The technique involves suspending an insect along a line between two metal spheres and comparing insect and sphere cross sections.
    3. keywords: {Delay effects;Dielectrics;Frequency;Insects;Magnetic anisotropy;Magnetic separation;Magnetostatic waves;Perpendicular magnetic anisotropy;Propagation delay;Radar cross section},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1450927&isnumber=31164
  10. B. G. Colpitts and G. Boiteau, "Harmonic radar transceiver design: miniature tags for insect tracking," in IEEE Transactions on Antennas and Propagation, vol. 52, no. 11, pp. 2825-2832, Nov. 2004.
    1. doi: 10.1109/TAP.2004.835166
    2. Abstract: The design and operation along with verifying measurements of a harmonic radar transceiver, or tag, developed for insect tracking are presented. A short length of wire formed the antenna while a beam lead Schottky diode across a resonant loop formed the frequency doubler circuit yielding a total tag mass of less than 3 mg. Simulators using the method-of-moments for the antenna, finite-integral time-domain for the loop, and harmonic balance for the nonlinear diode element were used to predict and optimize the transceiver performance. This performance is compared to the ideal case and to measurements performed using a pulsed magnetron source within an anechoic chamber. A method for analysis of the tag is presented and used to optimize the design by creating the largest possible return signal at the second harmonic frequency for a particular incident power density. These methods were verified through measurement of tags both in isolation and mounted on insects. For excitation at 9.41 GHz the optimum tag in isolation had an antenna length of 12 mm with a loop diameter of 1 mm which yielded a harmonic cross-section of 40 mm2. For tags mounted on Colorado potato beetles, optimum performance was achieved with an 8 mm dipole fed 2 mm from the beetle attached end. A theory is developed that describes harmonic radar in a fashion similar to the conventional radar range equation but with harmonic cross-section replacing the conventional radar cross-section. This method provides a straightforward description of harmonic radar system performance as well as provides a means to describe harmonic radar tag performance.
    3. keywords: {Schottky diodes;dipole antennas;frequency multipliers;method of moments;radar antennas;radar equipment;remote sensing by radar;time-domain analysis;transceivers;wire antennas;zoology;9.41 GHz;antenna measurements;beam lead Schottky diode;dipole antennas;finite-integral time-domain;frequency doubler circuit;harmonic balance;harmonic cross-section;harmonic radar transceiver design;insect tracking;method-of-moments;miniature tags;nonlinear diode element;resonant loop;wire antenna;Antenna measurements;Insects;Pulse measurements;Radar antennas;Radar cross section;Radar measurements;Radar theory;Radar tracking;Schottky diodes;Transceivers;65;Antenna measurements;Schottky diodes;dipole antennas;radar applications;radar theory;radio tracking;transceivers},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1353476&isnumber=29739
  11. R. Hajovsky, A. Deam and A. LaGrone, "Radar reflections from insects in the lower atmosphere," in IEEE Transactions on Antennas and Propagation, vol. 14, no. 2, pp. 224-227, Mar 1966.
    1. doi: 10.1109/TAP.1966.1138665
    2. Abstract: The backscattering characteristics of various types of insects found in the lower atmosphere were measured and the results are reported in this paper. The magnitudes of the insect cross sections and the effects of incident electromagnetic energy polarization are presented along with physical characteristics of the insects. The measuring equipment is described and its capability discussed.
    3. keywords: {Insects;Radar scattering;Antenna measurements;Arm;Atmosphere;Atmospheric measurements;Backscatter;Insects;Laboratories;Radar antennas;Radar cross section;Reflection},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1138665&isnumber=25434
  12. B. Colpitts, D. Luke, G. Boiteau and M. Doyle, "Harmonic radar identification tag for insect tracking," Engineering Solutions for the Next Millennium. 1999 IEEE Canadian Conference on Electrical and Computer Engineering (Cat. No.99TH8411), Edmonton, Alberta, Canada, 1999, pp. 602-605 vol.2.
    1. doi: 10.1109/CCECE.1999.807936
    2. Abstract: Design considerations and simulations are presented for an identification tag to be used in tracking insects through the use of harmonic radar. Radar is used instead of a radio transmitter in order to minimize the loading of the insect which for the Colorado potato beetle under study will require a tag of less than 5 mg mass. Frequency selection, antenna radiation pattern and impedance, as well as the SPICE model are discussed. The tag consists of a thin wire dipole antenna with a low-barrier Schottky diode and tuning inductor located at the feed point. The tag design procedure with limitations is presented.
    3. keywords: {antenna radiation patterns;biological techniques;electric impedance;identification technology;microwave antennas;radar antennas;radar tracking;wire antennas;zoology;Colorado potato beetle;SPICE model;antenna radiation pattern;frequency selection;harmonic radar identification tag;impedance;insect tracking;low-barrier Schottky diode;tag design procedure;thin wire dipole antenna;tuning inductor;Antenna radiation patterns;Dipole antennas;Frequency;Impedance;Insects;Radar antennas;Radar tracking;Radio transmitters;Radiofrequency identification;SPICE},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=807936&isnumber=17499
  13. J. R. Riley, "A millimetric radar to study the flight of small insects," in Electronics & Communication Engineering Journal, vol. 4, no. 1, pp. 43-48, Feb. 1992.
    1. doi: 10.1049/ecej:19920011
    2. Abstract: Conventional 3 cm entomological radars have been successfully used for many years to observe the migratory flight of the larger insect species, but the range at which these radars can detect individual small insects is limited to a few hundred metres. The author outlines the design and application of an 8.8 mm wavelength radar to study the flight of insects weighing only 2 mg. Detection ranges in excess of 1 km were achieved for individual insects, and estimates of aerial density made by the radar were found to be within 50% of those made by an aerial sampling device.<>
    3. keywords: {remote sensing by radar;zoology;1 km;8.8 mm;aerial density;detection range;entomological radars;individual insects;migratory flight;millimetric radar;small insect detection;Radar imaging;Remote sensing},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=129334&isnumber=3613
  14. D. S. Zrnic and A. V. Ryzhkov, "Observations of insects and birds with a polarimetric radar," in IEEE Transactions on Geoscience and Remote Sensing, vol. 36, no. 2, pp. 661-668, Mar 1998.
    1. doi: 10.1109/36.662746
    2. Abstract: The authors present observations of biological scatterers with a polarimetric weather radar. The radar has a pencil beam, a high power, and a wavelength of 10 cm. It transmits horizontally and vertically polarized waves alternately. The available polarimetric variables are differential reflectivity, differential phase, and correlation coefficient between orthogonally polarized returns. Two types of biological scatterers, insects and birds, are contrasted. Observed polarimetric signatures of these are compared and explained with a simple scattering model. Finally, the authors discuss the implications of recognizing the biological scatterers' type and the size of birds
    3. keywords: {atmospheric techniques;backscatter;biological techniques;meteorological radar;radar cross-sections;radar polarimetry;remote sensing by radar;zoology;10 cm;SHF;UHF;atmosphere;biological method;biological scatterer;bird;body size;correlation coefficient;differential phase;differential reflectivity;entomology;high power radar;horizontal polarisation;insect;measurement technique;meteorological radar;microwave radar;observations;ornithology;orthogonally polarized return;pencil beam;polarimetric radar;radar polarimetry;radar remote sensing;radar scattering;scattering model;species;type;vertical polarisation;weather radar;zoology;Birds;Doppler radar;Insects;Meteorological radar;Meteorology;Polarization;Radar polarimetry;Radar scattering;Radar tracking;Wind},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=662746&isnumber=14514
  15. B. G. Colpitts, D. M. Luke and G. Boiteau, "Harmonic radar for insect flight pattern tracking," 2000 Canadian Conference on Electrical and Computer Engineering. Conference Proceedings. Navigating to a New Era (Cat. No.00TH8492), Halifax, NS, 2000, pp. 302-306 vol.1.
    1. doi: 10.1109/CCECE.2000.849718
    2. Abstract: A harmonic radar system is described for use in tracking the movement of flying insects in entomological studies. The objective is to predict the range performance of the system given realistic antenna dimensions, transmit power and receiver performance. A description of the receiver is presented including the noise and signal level calculations. A maximum range of 251 m is shown to be realizable under realistic assumptions
    3. keywords: {agriculture;noise;radar antennas;radar applications;radar receivers;radar tracking;radar transmitters;251 m;Colorado potato beetle;antenna dimensions;entomological studies;flying insects;harmonic radar system;insect flight pattern tracking;noise level;potato industry;range performance prediction;receiver performance;signal level;transmit power;Agriculture;Insects;Niobium;Radar antennas;Radar tracking;Radio transmitters;Receiving antennas;Signal to noise ratio;Transceivers;Transmitting antennas},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=849718&isnumber=18407
  16. U. Olgun, D. Psychoudakis, C. C. Chen and J. L. Volakis, "High gain lightweight array for harmonic portable RFID radar," 2009 IEEE Antennas and Propagation Society International Symposium, Charleston, SC, 2009, pp. 1-4.
    1. doi: 10.1109/APS.2009.5172066
    2. Abstract: Single fed, high gain and lightweight patch arrays of size 12"times9" are designed and proposed for integration with a harmonic portable RFID radar so as to track the behavioral patterns of invasive Emerald Ash Borer insect. Serial interconnections of the array elements are tapered in order to suppress sidelobe level. With these additions, the proposed harmonic insect tracking radar system offers new features like improved portability, cost effectiveness and ease of fabrication as well as inheriting the attributes like low power output and novel tiny tag from. A prototype of the system is built and is expected to detect a tag of size 9.5 mm times 9.5 mm (0.19lambda0 times 0.19lambda0) up to more than 190 feet when the unit transmits 0.1W with newly developed 22 dBi transmit and 21 dBi receive patch antennas operating at 5.9/11.8 GHz, respectively.
    3. keywords: {microstrip antenna arrays;radar tracking;radiofrequency identification;array elements;frequency 11.8 GHz;frequency 5.9 GHz;harmonic insect tracking radar system;harmonic portable RFID radar;high gain lightweight array;invasive Emerald Ash Borer insect;lightweight patch arrays;patch antennas;serial interconnections;sidelobe level suppression;size 9.5 mm;Ash;Costs;Fabrication;Insects;Optical arrays;Power system harmonics;Power system interconnection;Prototypes;Radar tracking;Radiofrequency identification},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=5172066&isnumber=5171433
  17. H. Aniktar, D. Baran, E. Karav, E. Akkaya, Y. S. Birecik and M. Sezgin, "Getting the Bugs Out: A Portable Harmonic Radar System for Electronic Countersurveillance Applications," in IEEE Microwave Magazine, vol. 16, no. 10, pp. 40-52, Nov. 2015.
    1. doi: 10.1109/MMM.2015.2465591
    2. Abstract: The concept of a radar that detects semiconductor and metallic objects by monitoring second and third harmonic reradiations was conceived over 35 years ago. Called harmonic or nonlinear [1], [2], these radars can transmit at one or multiple frequencies and then receive the reflected signals at, or close to, the harmonic frequencies. Recently, harmonic radars have been used in different applications such as insect and bee tracking, vital-sign monitoring, antitheft systems [3], vehicular detection and identification, and countersurveillance [4]-[7]. Important design metrics for harmonic radars include operating frequencies, waveforms, polarizations, power levels, false-alarm rates, and detection sensitivity and range [5].
    3. keywords: {electronic countermeasures;object detection;radar detection;radar polarimetry;search radar;detects semiconductor;electronic counter surveillance application;false alarm rate;harmonic frequencies;metallic object detection;polarization;portable harmonic radar system;Harmonic analysis;Object detection;P-n junctions;Power harmonic filters;Radar detection;Radio frequency;Semiconductor device measurement;Surveillance},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7298555&isnumber=7298500
  18. C. Neumann and H. Senkowski, "Plot based target classification for ATC radars," 2015 16th International Radar Symposium (IRS), Dresden, 2015, pp. 254-259.
    1. doi: 10.1109/IRS.2015.7226248
    2. Abstract: Air Traffic Control (ATC) radars are expected today to provide improved performance in terms of maximum range and spatial coverage, while the huge amount of small unwanted flying objects like birds and insects shall not lead to an increased false plot1 and / or false track2 rate. To accomplish these opposite aspects of radar capabilities, the occurring plots of the ATC primary surveillance radar (PSR) have to be assessed with respect to coming from wanted or unwanted objects. In addition to the various assessments usually implemented inside the ATC radar signal and data processing for this purpose, a new signature based plot classification is introduced to handle this challenging task. The plot classification recognises true air targets and discriminates them against echoes from birds, “angels”, wind turbines and other unwanted plots. The classification results are used to filter out false plots and to improve the plot to track association. Results from measurement campaigns show the benefit of this approach in real operational scenarios.
    3. keywords: {air traffic control;airborne radar;filtering theory;military radar;radar signal processing;search radar;signal classification;ATC primary surveillance radar;ATC radar data processing;ATC radar signal processing;air traffic control radars;false plot filtering;plot based target classification;plot-to-track association improvement;signature based plot classification;small unwanted flying objects;true air target recognition;Aircraft;Birds;Feature extraction;Radar antennas;Radar cross-sections;Radar tracking},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7226248&isnumber=7226207
  19. N. Tahir and G. Brooker, "Toward the Development of Millimeter Wave Harmonic Sensors for Tracking Small Insects," in IEEE Sensors Journal, vol. 15, no. 10, pp. 5669-5676, Oct. 2015.
    1. doi: 10.1109/JSEN.2015.2445933
    2. Abstract: Entomologists need to observe and monitor insects in their natural habitats for various reasons. One of the most common techniques in use today is to attach low-cost harmonic sensor or transponder to insects and to track them using an associated harmonic radar. Existing harmonic transponders based on monopoles, loop-dipoles, and Minkowski loops have been successfully attached to small low-flying insects. However, they offer significant constraints from a mounting perspective, weight and size considerations, aerodynamic drag, and the elevation of the insect center of gravity. This paper addresses these issues by presenting novel design methodologies for millimeter wave harmonic sensors and radar. The sensors address the challenges of ease of design and fabrication, robustness, conversion efficiency, miniaturization, antenna entangling, and attachment problems that are generally encountered with other transponders.
    3. keywords: {biological techniques;microstrip antennas;millimetre wave detectors;transponders;antenna entangling;conversion efficiency;microstrip antennas;millimeter wave harmonic sensors;miniaturization;small insect tracking;transponders;Antenna measurements;Harmonic analysis;Insects;Loss measurement;Optical sensors;Schottky diodes;Microstrip antennas;millimeter wave radar;radio frequency identification;remote monitoring;transponder;wearable sensor},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7124457&isnumber=7181761
  20. S. Z. Gürbüz et al., "Exploring the skies: Technological challenges in radar aeroecology," 2015 IEEE Radar Conference (RadarCon), Arlington, VA, 2015, pp. 0817-0822.
    1. doi: 10.1109/RADAR.2015.7131108
    2. Abstract: Aeroecology is an emerging interdisciplinary science focused on the study of airborne organisms with the aim of deepening understanding about the ecological functions of the aerosphere and the bio-organisms that move through it. In addition to having important applications to the understanding of animal migration and foraging movements, global pest and disease control, biodiversity and conservation issues, and monitoring of the effects of climate change, aeroecology has also been critical in ensuring the safety of military and civilian aircraft from bird strikes. Although the capability of radar to observe bioscatter has been known for nearly 70 years, radar aeroecology has now entered an exciting new phase, with the prospect of continent-wide monitoring of flying animals by means of networks of operational weather radars. In this work, the technological challenges of using radar for the detection, characterization, and monitoring of birds, bats, and insects is discussed in detail. Current efforts to further develop radar signal processing algorithms for aeroecology is discussed in light of a multi-national European research initiative, ENRAM.
    3. keywords: {airborne radar;ecology;meteorological radar;radar detection;radar signal processing;ENRAM;aerosphere;airborne organism;animal migration;biodiversity;bioorganism;bioscattering;civilian aircraft;climate change;continent-wide monitoring;disease control;ecological function;foraging movement;global pest;military aircraft;multinational European research initiative;radar aeroecology;radar detection;radar signal processing algorithm;safety;weather radar;Birds;Doppler radar;Europe;Insects;Meteorological radar;Meteorology},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7131108&isnumber=7130933
  21. D. Lange, F. Rocadenbosch, J. Tiana-Alsina and S. Frasier, "Atmospheric Boundary Layer Height Estimation Using a Kalman Filter and a Frequency‐Modulated Continuous‐Wave Radar," in IEEE Transactions on Geoscience and Remote Sensing, vol. 53, no. 6, pp. 3338-3349, June 2015.
    1. doi: 10.1109/TGRS.2014.2374233
    2. Abstract: An adaptive solution based on an extended Kalman filter (EKF) is proposed to estimate the atmospheric boundarylayer height (ABLH) from frequency-modulated continuous-wave S-band weather-radar returns. The EKF estimator departs from previous works, in which the transition interface between the mixing layer (ML) and the free troposphere (FT) is modeled by means of an erf-like parametric function. In contrast to lidar remote sensing, where aerosols give strong backscatter returns over the whole ML, clear-air radar reflectivity returns (Bragg scattering from refractive turbulence) shows strongest returns from the ML-FT interface. In addition, they are corrupted by “insect” noise (impulsive noise associated with Rayleigh scattering from insects and birds), all of which requires a specific treatment of the problem and the measurement noise for the clear-air radar case. The proposed radar-ABLH estimation method uses: 1) a first preprocessing of the reflectivity returns based on median filtering and threshold-limited decision to obtain “clean” reflectivity signal; 2) a modified EKF with adaptive range intervals as time tracking estimator; and 3) ad hoc modeling of the observation noise covariance. The method has successfully been implemented in clear-air, single-layer, and convective boundary-layer conditions. ABLH estimates from the proposed radar-EKF method have been cross examined with those from a collocated lidar ceilometer yielding a correlation coefficient as high as ρ = 0.93 (mean signal-to-noise ratio, SNR = 18 (linear units), at the ABLH) and in relation to the classic THM.
    3. keywords: {atmospheric boundary layer;atmospheric optics;atmospheric techniques;atmospheric turbulence;remote sensing by laser beam;remote sensing by radar;troposphere;Bragg scattering;EKF estimator;ML-FT interface;adaptive solution;atmospheric boundary layer height estimation;clear-air radar case;clear-air radar reflectivity returns;collocated lidar ceilometer;convective boundary-layer conditions;correlation coefficient;erf-like parametric function;extended Kalman filter;free troposphere;frequency-modulated continuous-wave S-band weather-radar returns;lidar remote sensing;radar-ABLH estimation method;refractive turbulence;Adaptation models;Estimation;Insects;Laser radar;Noise;Scattering;Adaptive kalman filtering;laser radar;remote sensing;signal processing},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6998066&isnumber=7032018
  22. P. H. Jau et al., "Signal processing for harmonic pulse radar based on spread spectrum technology," in IET Radar, Sonar & Navigation, vol. 8, no. 3, pp. 242-250, March 2014.
    1. doi: 10.1049/iet-rsn.2013.0024
    2. Abstract: This study presents the signal processing techniques applied on a 9.4/18.8 GHz harmonic radar, which is used to investigate behaviours of small insects such as bees, beetles and butterflies. It is still a challenge to achieve high accuracy and long detection range simultaneously in a harmonic pulse radar system. The authors combine the spread spectrum technology with the classic pulse harmonic radar system to overcome the dilemma between accuracy and detection range. The processing gain of the pseudo-random code from the spread spectrum technology is used to increase the sensitivity and makes the system able to detect the signal with the weak power strength below the system noise level. To eliminate the effect caused by the local leakage, the signal-processing method provided to cancel the leakage through applying the symmetric property of the autocorrelation function of the pseudo-random code. In the field tests, the proposed system achieves a 60 m detection range within 1 m ranging accuracy by using 1.75 W transmitting power corresponding to 40.430 dBW equivalent-isotropically radiated power (EIRP). It is estimated to extend to at least 900 m detection range by using a 3 kW transmitting power corresponding to 72.771 dBW EIRP.
    3. keywords: {radar signal processing;radiofrequency power transmission;random sequences;signal detection;spread spectrum radar;EIRP;autocorrelation function;equivalent-isotropically radiated power;frequency 18.8 GHz;frequency 9.4 GHz;gain processing;harmonic radar;power 1.75 W;power 3 kW;power transmission;pseudorandom code;signal detection;signal processing;spread spectrum technology-based harmonic pulse radar;system noise level;weak power strength},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6750818&isnumber=6750808
  23. H. Aumann, E. Kus, B. Cline and N. W. Emanetoglu, "An asymmetrical dipole tag with optimum harmonic conversion efficiency," Proceedings of the 2012 IEEE International Symposium on Antennas and Propagation, Chicago, IL, 2012, pp. 1-2.
    1. doi: 10.1109/APS.2012.6348447
    2. Abstract: Extremely small passive dipole tags have been used for tracking insects with a harmonic radar. It will be shown that by adjusting the dipole feed point location, the conversion efficiency, and hence the maximum detection range, can be optimized. Analysis, simulations and measurements on X-band tags confirm that the best tag efficiency is achieved with a half-wavelength dipole and asymmetric 1:2 dipole arm lengths.
    3. keywords: {Schottky diodes;dipole antennas;inductors;radar antennas;Schottky diode junction capacitance;X-band tags;asymmetric 1:2 dipole arm lengths;asymmetrical dipole tag;chip inductor;dipole feed point location;half-wavelength dipole;harmonic radar;maximum detection range;optimum harmonic conversion efficiency;tracking insects;Artificial intelligence;Barium;Iron},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6348447&isnumber=6347935
  24. N. Tahir and G. Brooker, "Recent developments and recommendations for improving harmonic radar tracking systems," Proceedings of the 5th European Conference on Antennas and Propagation (EUCAP), Rome, 2011, pp. 1531-1535.
    1. Abstract: The paper presents some recent developments in harmonic radar tracking systems. These are widely used for monitoring and tracking of low flying insects like honey bees, butterflies, snail and carabid beetles, and come under the category of individual marking techniques and use harmonic range detection or range finding for tracking insects tagged with harmonic transponders. In most cases the transponder is, however, a vertical rod or trailing wire both of which hinder insect movement. This paper presents recommendations for improving the harmonic radar, detectable range and minimizing the weight and size of transponder. It presents externally biased microstrip antenna based prototype harmonic transponder.
    2. keywords: {distance measurement;radar tracking;transponders;externally biased microstrip antenna;harmonic radar tracking systems;harmonic range detection;harmonic transponders;insect movement;prototype harmonic transponder;range finding;Harmonic analysis;Insects;Microstrip antennas;Radar tracking;Schottky diodes;Transponders;Microstrip antennas;Radiofrequency identification;millimeter wave radar;transponder},
    3. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=5781806&isnumber=5780481
  25. N. Behdad, M. Al-Joumayly and M. Li, "Biomimetic electrically small antennas," in Electronics Letters, vol. 46, no. 25, pp. 1650-1651, December 9 2010.
    1. doi: 10.1049/el.2010.8034
    2. Abstract: Many insects possess acute directional hearing capabilities and are able to localise a sound source of interest with a good degree of precision. An analogy can be drawn between the hearing mechanisms of such insects and a two-element, electrically small antenna array. Presented is a biomimetic electrically small antenna array that mimics the hearing mechanism of an insect with hyperacute directional hearing capability. A prototype of such an antenna has been fabricated and its simulated and measured results are presented. Such biomimetic antenna arrays could be used in numerous applications ranging from miniaturised RF sensors and direction finding systems to small aperture, high-resolution microwave imaging systems and radars.
    3. keywords: {antenna arrays;biocommunications;biomimetics;hearing;biomimetic electrically small antenna array;direction finding systems;hearing mechanism;highresolution microwave imaging systems;hyperacute directional hearing capability;microwave radars;miniaturised RF sensors;sound source},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=5665812&isnumber=5665802
  26. V. Lakshmanan and J. Zhang, "Censoring Biological Echoes in Weather Radar Images," 2009 Sixth International Conference on Fuzzy Systems and Knowledge Discovery, Tianjin, 2009, pp. 491-495.
    1. doi: 10.1109/FSKD.2009.640
    2. Abstract: Weather radar data is susceptible to several artifacts due to anamalous propagation, ground clutter, electronic interference, sun angle, second-trip echoes and biological contaminants such as insects, bats and birds. Several methods of censoring radar reflectivity data have been devised and described in the literature. However, they all rely on analyzing the local texture and vertical profile of reflectivity fields. The local texture of reflectivity fields suffices to remove most artifacts, except for biological echoes. Biological echoes have proved difficult to remove because they can have the same returned power and vertical profile as stratiform rain or snow. In this paper, we describe a soft-computing technique based on clustering, segmentation and a two-stage neural network to censor all non-precipitating artifacts in weather radar reflectivity data. We demonstrate that the technique is capable of discrimination between light snow, stratiform rain and deep biological ¿bloom¿.
    3. keywords: {environmental science computing;radar imaging;weather forecasting;anamalous propagation;biological contaminants;biological echoes censoring;electronic interference;ground clutter;second-trip echoes;sun angle;weather radar images;Birds;Clutter;Echo interference;Insects;Meteorological radar;Radar imaging;Rain;Reflectivity;Snow;Sun;clustering;neural network;segmentation;weather radar},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=5360572&isnumber=5360535
  27. G. L. Charvat, E. J. Rothwell and L. C. Kempel, "Harmonic radar tag measurement and characterization," IEEE Antennas and Propagation Society International Symposium. Digest. Held in conjunction with: USNC/CNC/URSI North American Radio Sci. Meeting (Cat. No.03CH37450), Columbus, OH, USA, 2003, pp. 696-699 vol.2.
    1. doi: 10.1109/APS.2003.1219331
    2. Abstract: Conventional radar systems transmit and receive at a single, fundamental frequency. It is sometimes challenging to identify a small object against a large background with these radars due to the relatively large return from the background. In effect, the background represents a clutter environment. Harmonic radar tags can be attached to an item, such as insects, and then used to track that item against the background. To do so, the radar must transmit a signal at the fundamental frequency but receive at twice that frequency. Since the clutter return is at the fundamental frequency, the radar is able to discriminate the return from the tag. This paper describes equipment constructed at Michigan State University to conduct research on harmonic tags.
    3. keywords: {UHF antennas;dipole antennas;frequency multipliers;radar clutter;radar tracking;target tracking;917 MHz;antenna connected frequency doubler;background return;clutter environment;dipole harmonic radar tag;insect tagging;radar fundamental frequency;radar single transmit/receive frequency;target tracking;Dynamic range;Frequency measurement;Power harmonic filters;Radar antennas;Radar clutter;Radar measurements;Radar tracking;Schottky diodes;Target tracking;Technical Activities Guide -TAG},
    4. URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1219331&isnumber=27400

 

Thursday, December 8, 2016

DDG1000 USS Zumwalt comes to Home Port in San Diego

An SH-60R assigned to Air Test and Evaluation Squadron (HX) 21
flies near USS Zumwalt (DDG 1000) as the ship travels to its
new home port of San Diego, California
Photo by Elizabeth A Wolter  Navy Media Content Services





Navy's high-tech destroyer Zumwalt arrives Thursday - The San Diego Union-Tribune
The Navy’s $4 billion guided-missile destroyer Zumwalt is slated to dock in San Diego on Thursday morning, following a slew of mechanical glitches that sidelined it for weeks in Virginia and Panama.

The most expensive and revolutionary destroyer ever built, the Zumwalt will homeport at the San Diego Naval Base.

Scheduled to undergo further modifications and testing, the Navy predicts it will be fully prepped for overseas deployments within a year.

Navy's newest surface ship, the USS Zumwalt, arrives in San Diego today - 10News.com KGTV ABC10 San Diego

Navy's newest high-tech destroyer arrives in San Diego - CBS News 8 - San Diego, CA News Station - KFMB Channel 8

Navy’s most technologically advanced ship to arrive in San Diego | fox5sandiego.com

The arrival will come a little more than two weeks after the $4.4 billion ship's propulsion system broke down in the Panama Canal. The 610-foot- long vessel had to pull into port in Panama to make repairs before continuing the voyage to San Diego, which will serve as its home port.

Commissioned in October in Baltimore, the Zumwalt has an angular appearance vastly different from current destroyers of the Arleigh Burke class in order to lower its radar signature. Navy officials said it was the "lead ship of a class of next-generation multimission destroyers."

The destroyer will be capable of performing a range of deterrence, power projection, sea control, and command and control missions while allowing the Navy to evolve with new systems and missions, Navy officials said.


BAE Systems Wins $192M USS Zumwalt Combat System Award
On arrival in San Diego, BAE Systems San Diego Ship Repair will begin installation of combat systems, while the crew will conduct testing and evaluation, and operational integration with the fleet.

Related/Background

Thursday, December 1, 2016

JHU - Testosterone whipsaw may knock out castration-resistant prostate cancer

Fig. 3. Evaluation of clinical response.
(A) Waterfall plot showing maximum PSA change relative to baseline in 14 patients completing at least three cycles of BAT plus etoposide. The number at the end of each bar indicates the number of treatment cycles received. The number in parentheses indicates the percent PSA change in a case where the bar was truncated.
(B) Patterns of PSA response observed in patients on study.
(C) PSA response in an individual patient (patient 9) receiving a total of 16 cycles of BAT.
(D) Computed tomography (CT) scans obtained before treatment and after three cycles of therapy in two patients on study, demonstrating complete response (CR) (patient 16, upper panels) and partial response (PR) (patient 15, lower panels) in abdominal lymph nodes. Red circles outline disease burden.
Fig. 2. Clinical trial of BAT plus etoposide.
(A) Schematic of study design.
(B) Baseline characteristics of patients on study.
(C) Mean serum testosterone levels at indicated time points for patients on study.
Effect of bipolar androgen therapy for asymptomatic men with castration-resistant prostate cancer: Results from a pilot clinical study | Science Translational Medicine

Man 'cured' of prostate cancer after doctors shock tumour to death with testosterone
A man with advanced prostate cancer is believed to be cured after doctors 'shocked' his tumour to death with huge amounts of testosterone.

The result has been described as 'unexpected' and 'exciting' because most prostate cancer therapies work by depriving tumours of testosterone, because cancer uses it as a fuel. Other seriously ill men taking part in the same trial showed responses that astounded scientists, with tumours shrinking and the progress of their disease halted.

Levels of Prostate Specific Antigen (PSA), a blood marker used to monitor prostate cancer, also fell in the majority of the 47 participants.

One individual whose PSA levels dropped to zero after three months and shows no remaining trace of the disease after 22 cycles of treatment appears to be cured, said the researchers.

Sam Denmeade, M.D.
Professor Sam Denmeade, M.D., from Johns Hopkins University School of Medicine in Baltimore, US, who led the study, said: ""Our goal is to shock the cancer cells by exposing them rapidly to very high followed by very low levels of testosterone in the blood. The results are unexpected and exciting.


Effect of bipolar androgen therapy for asymptomatic men with castration-resistant prostate cancer: Results from a pilot clinical study | Science Translational Medicine
Abstract: Targeting androgen receptor (AR) axis signaling by disrupting androgen-AR interactions remains the primary treatment for metastatic prostate cancer. Unfortunately, all men develop resistance to primary castrating therapy and secondary androgen deprivation therapies (ADTs). Resistance develops in part because castration-resistant prostate cancer (CRPC) cells adaptively up-regulate AR levels through overexpression, amplification, and expression of ligand-independent variants in response to chronic exposure to a low-testosterone environment. However, preclinical models suggest that AR overexpression represents a therapeutic liability that can be exploited via exposure to supraphysiologic testosterone to promote CRPC cell death. Preclinical data supported a pilot study in which 16 asymptomatic CRPC patients with low to moderate metastatic burden were treated with testosterone cypionate (400 mg intramuscular; day 1 of 28) and etoposide (100 mg oral daily; days 1 to 14 of 28). After three cycles, those with a declining prostate-specific antigen (PSA) continued on intermittent testosterone therapy monotherapy. Castrating therapy was continued to suppress endogenous testosterone production, allowing for rapid cycling from supraphysiologic to near-castrate serum testosterone levels, a strategy termed bipolar androgen therapy (BAT). BAT was well tolerated and resulted in high rates of PSA (7 of 14 evaluable patients) and radiographic responses (5 of 10 evaluable patients). Although all men showed eventual PSA progression, four men remained on BAT for ≥1 year. All patients (10 of 10) demonstrated PSA reductions upon receiving androgen-ablative therapies after BAT, suggesting that BAT may also restore sensitivity to ADTs. BAT shows promise as treatment for CRPC and should be further evaluated in larger trials.

Related/Background:

Sunday, November 27, 2016

NASA Sets SpaceX to Launch SWOT Mission RADAR Satellite

Thales Alenia Space Nabs $94M Contract for SWOT Satellite
SWOT Satellite Artist Rendering
SpaceX Falcon 9 Rocket

SWOT: Technology - Ka-Band Radar Interferometer 
Artists concept of SWOT KaRIN instrument.
Both the surface water hydrology and ocean surface topography communities recognize the importance of wide-swath altimetry for its capability of acquiring high-resolution elevation measurements. The technology for WATER and HM is a Ka-band Radar INterferometer (KaRIN, 0.86 cm wavelength) that has been developed from the efforts of the Wide Swath Ocean Altimeter (WSOA; Fu, 2003; Fu and Rodriguez, 2004). KaRIN is essentially a smaller version of SRTM with two Ka-band SAR antennae at opposite ends of a 10 m boom and both antennae transmitting and receiving the emitted radar pulses along both sides of the orbital track. Look angles are limited to 4.5° providing a 120 km wide swath. The 200 MHz bandwidth achieves cross-track ground resolutions varying from about 10 m in the far swath to about 60 m in the near swath. A resolution of about 2 m in the along track direction is derived by means of synthetic aperture processing.
Altimeter System


Orbit HeightOrbit TypeSwathFrequencyHeight PrecisionSpatial Resolution
SWOT857-
890 km
22-day repeat
78 Deg Inclination
120 kmKa-band~1 cm @ 1 km resolution

SWOT: Home Page
 
NASA Sets Launch for Global Surface Water Survey (SWOT) Mission
NASA has selected Space Exploration Technologies (SpaceX) of Hawthorne, California, to provide launch services for the agency's Surface Water and Ocean Topography (SWOT) mission. Launch is targeted for April 2021 on a SpaceX Falcon 9 rocket from Space Launch Complex 4E at Vandenberg Air Force Base in California.

The total cost for NASA to launch SWOT is approximately $112 million, which includes the launch service; spacecraft processing; payload integration; and tracking, data and telemetry support.

Designed to make the first-ever global survey of Earth's surface water, in addition to high-resolution ocean measurements, the SWOT mission will collect detailed measurements of how water bodies on Earth change over time. The satellite will survey at least 90 percent of the globe, studying Earth's lakes, rivers, reservoirs and oceans, at least twice every 21 days; aid in freshwater management around the world; and improve ocean circulation models and weather and climate predictions. The SWOT spacecraft will be jointly developed and managed by NASA and the French space agency Centre National d'Etudes Spatiales (CNES).

NASA's Launch Services Program at Kennedy Space Center in Florida will manage the SpaceX launch service. The SWOT project office at NASA's Jet Propulsion Laboratory in Pasadena, California, manages spacecraft development for the agency's Science Mission Directorate in Washington.

For more information on SWOT, visit: http://swot.jpl.nasa.gov/
For more information about NASA programs and missions, visit: http://www.nasa.gov

SpaceX wins NASA contract to launch ocean-surveying satellite - The Verge
It marks yet another critical science mission that SpaceX will be launching for NASA. The company launched the Jason-3 ocean-monitoring satellite for the space agency in January, and in 2017 SpaceX is supposed to launch NASA’s Transiting Exoplanet Survey Satellite, or TESS, designed to look for small planets around bright stars outside our Solar System.

“We’re excited to carry this critical science payload into orbit for NASA, the nation, and the international community,” SpaceX president Gwynne Shotwell said in a statement. “We appreciate NASA’s partnership and confidence in SpaceX as a launch provider.”

The total cost of launching SWOT is valued at $112 million, according to NASA, which seems a little pricey given SpaceX’s Falcon 9 rockets supposedly start at $62 million. Plus, it’s a much higher value than previous launch contracts NASA has awarded to SpaceX; the cost of launching the Jason-3 satellite was valued at $82 million, and the cost of launching TESS is $87 million.

Well according to NASA, the $112 million doesn’t just cover the cost of launching the Falcon 9 rocket; it’s the total cost of launching SWOT overall. So some of that money is going to SpaceX while the rest is going to other organizations that will provide “additional support” needed to get SWOT into space. However, NASA declined to go into specifics about what that added support entails. “The specific launch service price is considered competition and procurement sensitive information,” NASA spokesperson Cheryl Warner said in a statement.

Meanwhile, SpaceX is still grounded from spaceflight after one of its Falcon 9 rockets exploded on a Florida launchpad in September. After months of investigation, CEO Elon Musk said the company finally figured out what caused the failure, noting it was the most complicated problem SpaceX has ever had to solve. Musk said they are targeting a return-to-flight mission before the end of the year, but an official launch date has yet to be announced.


References/Background:

  1. SpaceX to Build Spacecraft for NASA's New Mission SWOT | Digital Trends
  2. NASA Selects Launch Services for Global Surface Water Survey Mission
  3. Advances in interferometric synthetic aperture radar (InSAR) in earth system scienceAbstract: During recent years, synthetic aperture radar (SAR) interferometry (InSAR) has become an important tool for precise measurements of the earth’s surface topography and deformation. This paper presents an overview on recent developments in InSAR applications, with emphasis on the use of satellite-borne sensors for applications in geoscience, topographic mapping, natural hazard monitoring and environmental research. InSAR measurement principles are briefly introduced. Recent results on the use of repeat-pass interferometry for mapping seismic and volcanic deformation, monitoring landslides and subsidence, and mapping glacier motion are described. Other InSAR applications introduced in the paper are: topographic mapping, retrieval of biogeophysical parameters on land surfaces, and measurements of water currents. Examples of interferometric products are shown for satellite-borne SAR systems operating at X-band, C-band and L-band radar frequencies. An outlook is provided on upcoming SAR systems which will spur further advances in InSAR techniques and applications. 
  4. Characterization of complex fluvial systems using remote sensing of spatial and temporal water level variations in the Amazon, Congo, and Brahmaputra Rivers - Jung - 2010 - Earth Surface Processes and Landforms - Wiley Online Library Abstract: The Surface Water and Ocean Topography (SWOT) satellite mission will provide global, space-based estimates of water elevation, its temporal change, and its spatial slope in fluvial environments, as well as across lakes, reservoirs, wetlands, and floodplains. This paper illustrates the utility of existing remote sensing measurements of water temporal changes and spatial slope to characterize two complex fluvial environments. First, repeat-pass interferometric SAR measurements from the Japanese Earth Resources Satellite are used to compare and contrast floodplain processes in the Amazon and Congo River basins. Measurements of temporal water level changes over the two areas reveal clearly different hydraulic processes at work. The Amazon is highly interconnected by floodplain channels, resulting in complex flow patterns. In contrast, the Congo does not show similar floodplain channels and the flow patterns are not well defined and have diffuse boundaries. During inundation, the Amazon floodplain often shows sharp hydraulic changes across floodplain channels. The Congo, however, does not show similar sharp changes during either infilling or evacuation. Second, Shuttle Radar Topography Mission measurements of water elevation are used to derive water slope over the braided Brahmaputra river system. In combination with in situ bathymetry measurements, water elevation and slope allow one to calculate discharge estimates within 2.3% accuracy. These two studies illustrate the utility of satellite-based measurements of water elevation for characterizing complex fluvial environments, and highlight the potential of SWOT measurements for fluvial hydrology. Copyright © 2010 John Wiley & Sons, Ltd.
  5. Observing Global Surface Water Flood Dynamics | SpringerLink
    Abstract: Flood waves moving along river systems are both a key determinant of globally important biogeochemical and ecological processes and, at particular times and particular places, a major environmental hazard. In developed countries, sophisticated observing networks and ancillary data, such as channel bathymetry and floodplain terrain, exist with which to understand and model floods. However, at global scales, satellite data currently provide the only means of undertaking such studies. At present, there is no satellite mission dedicated to observing surface water dynamics and, therefore, surface water scientists make use of a range of sensors developed for other purposes that are distinctly sub-optimal for the task in hand. Nevertheless, by careful combination of the data available from topographic mapping, oceanographic, cryospheric and geodetic satellites, progress in understanding some of the world’s major river, floodplain and wetland systems can be made. This paper reviews the surface water data sets available to hydrologists on a global scale and the recent progress made in the field. Further, the paper looks forward to the proposed NASA/CNES Surface Water Ocean Topography satellite mission that may for the first time provide an instrument that meets the needs of the hydrology community.
    Keywords: Floods Surface water Flood plains RiversWetlands Remote sensing Surface water ocean topography (SWOT) mission
  6. D. Moller, G. Farquharson and D. Esteban-Fernandez, "Assessment of near-nadir correlation characteristics over water bodies using interferometric SAR: Implications for the swot mission," 2016 IEEE International Geoscience and Remote Sensing Symposium (IGARSS), Beijing, China, 2016, pp. 3219-3222.
    doi: 10.1109/IGARSS.2016.7729833
    Abstract: This paper introduces the use of an airborne interferometric synthetic aperture radar (InSAR) to estimate water surface decorrelation times at Ka-Band. Such an assessment is directly relevant to the upcoming Surface Water and Ocean Topography mission, especially for surface water bodies such as lakes and rivers since the surface decorrelation may limit the spatial resolution achievable by the mission to delineate water spatial boundaries. Initial assessments indicate decorrelation times consistent with limited published observations for the ocean and fresh water bodies (several milliseconds). However, there are challenges both in terms of the phenomenology and in the instrument sensitivity to longer decorrelations.
    keywords: {Decorrelation;Lakes;Sea measurements;Sea surface;Surface topography;Synthetic aperture radar;Interferometry;Ka-band;SWOT},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7729833&isnumber=7728980
  7. Measuring surface water from space - Alsdorf - 2007 - Reviews of Geophysics - Wiley Online Library Abstract: [1] Surface fresh water is essential for life, yet we have surprisingly poor knowledge of the spatial and temporal dynamics of surface freshwater discharge and changes in storage globally. For example, we are unable to answer such basic questions as “What is the spatial and temporal variability of water stored on and near the surface of all continents?” Furthermore, key societal issues, such as the susceptibility of life to flood hazards, cannot be answered with the current global, in situ networks designed to observe river discharge at points but not flood events. The measurements required to answer these hydrologic questions are surface water area, the elevation of the water surface (h), its slope (∂h/∂x), and temporal change (∂h/∂t). Advances in remote sensing hydrology, particularly over the past 10 years and even more recently, have demonstrated that these hydraulic variables can be measured reliably from orbiting platforms. Measurements of inundated area have been used to varying degrees of accuracy as proxies for discharge but are successful only when in situ data are available for calibration; they fail to indicate the dynamic topography of water surfaces. Radar altimeters have a rich, multidecadal history of successfully measuring elevations of the ocean surface and are now also accepted as capable tools for measuring h along orbital profiles crossing freshwater bodies. However, altimeters are profiling tools, which, because of their orbital spacings, miss too many freshwater bodies to be useful hydrologically. High spatial resolution images of ∂h/∂t have been observed with interferometric synthetic aperture radar, but the method requires emergent vegetation to scatter radar pulses back to the receiving antenna. Essentially, existing spaceborne methods have been used to measure components of surface water hydraulics, but none of the technologies can singularly supply the water volume and hydraulic measurements that are needed to accurately model the water cycle and to guide water management practices. Instead, a combined imaging and elevation-measuring approach is ideal as demonstrated by the Shuttle Radar Topography Mission (SRTM), which collected images of h at a high spatial resolution (∼90 m) thus permitting the calculation of ∂h/∂x. We suggest that a future satellite concept, the Water and Terrestrial Elevation Recovery mission, will improve upon the SRTM design to permit multitemporal mappings of h across the world's wetlands, floodplains, lakes, reservoirs, and rivers.
     
  8. D. Desroches, R. Fjørtoft, D. Massonnet, J. Duro, J. M. Gaudin and N. Pourthie, "Inland Water Height Estimation Without Ground Control Points for Near-Nadir InSAR Data," in IEEE Geoscience and Remote Sensing Letters, vol. 13, no. 9, pp. 1354-1358, Sept. 2016.
    doi: 10.1109/LGRS.2016.2585858
    Abstract: Surface Water and Ocean Topography (SWOT) is a future wide-swath radar altimetry mission. The main instrument is the Ka-band radar interferometer (KaRIn). It provides interferometric radar images that will be processed to obtain water elevation estimates worldwide. Due to the specific geometric and radiometric characteristics of KaRIn/SWOT, the phase-to-height conversion is one of the most critical processing steps. We propose methods to estimate water heights without using classical approaches based on spatial phase unwrapping and control points. Results obtained on the simulated SWOT data are shown.
    keywords: {oceanographic techniques;radar imaging;radar interferometry;synthetic aperture radar;Ka-band radar interferometer;KaRIn-SWOT geometric characteristics;KaRIn-SWOT radiometric characteristics;Surface Water and Ocean Topography;ground control points;inland water height estimation;interferometric radar images;near-Nadir InSAR data;simulated SWOT data;water elevation estimates;wide-swath radar altimetry mission;Estimation;Geometry;Rivers;Spaceborne radar;Synthetic aperture radar;Thermal noise;Altimetry;hydrology;interferometry;phase unwrapping;synthetic aperture radar (SAR)},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7518606&isnumber=7534955
  9. R. Fjørtoft, P. Callahan, E. Rodriguez and D. Desroches, "Processing of proposed KARIN/SWOT data," 2013 IEEE International Geoscience and Remote Sensing Symposium - IGARSS, Melbourne, VIC, 2013, pp. 4515-4518.
    doi: 10.1109/IGARSS.2013.6723839
    Abstract: This article summarizes the data processing of the proposed wide-swath altimetry mission Surface Water and Ocean Topography (SWOT), and more specifically the processing steps up to level 2 for the Ka-band Radar Interferometer (KaRIn), which is a near-nadir viewing bistatic SAR system. A general overview of the proposed processing chains and data products is given, and some particularly challenging processing steps are commented on.
    keywords: {remote sensing by radar;synthetic aperture radar;KARIN-SWOT data;Ka-band Radar Interferometer;SWOT wide-swath altimetry mission;Surface Water and Ocean Topography;bistatic SAR system;Abstracts;Extraterrestrial measurements;Hydrology;Interferometry;Oceans;Orbits;Sea measurements;Altimetry;hydrology;interferometry;oceanography;synthetic aperture radar},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6723839&isnumber=6721065
     
  10. M. Ludwig, E. Daganzo-Eusebio and M. Davidson, "Ka-Band radar missions for earth observation," 2013 IEEE International Geoscience and Remote Sensing Symposium - IGARSS, Melbourne, VIC, 2013, pp. 2289-2292.
    doi: 10.1109/IGARSS.2013.6723275
    Abstract: The use of Ka-Band in remote sensing creates new opportunities in Earth observation for science and civil security applications due to the unique characteristics of this higher frequency range. Several Ka-Band satellite missions and instruments are currently under development or close to launch (e.g. ALTIKA altimeter, SWOT satellite, etc). In addition, studies into future interferometric SAR missions are on-going and there is an increasing interest in the capabilities offered by radar systems at higher frequencies. This paper reports on major trends as derived from the 1st International Workshop on Ka-band Earth Observation Radar Missions (KEO'12), which was organized by the European Space Agency at ESA/ESTEC (The Netherlands) in November 2012.
    keywords: {remote sensing by radar;AD 2012 11;ESA-ESTEC;European Space Agency;Ka-band Earth Observation Radar Missions;Ka-band radar missions;Ka-band satellite missions;The Netherlands;civil security application;interferometric SAR missions;remote sensing;science application;Conferences;Earth;Instruments;Interferometry;Spaceborne radar;Synthetic aperture radar;Ka-band;interferometry;radar},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6723275&isnumber=6721065
  11. R. Fjørtoft et al., "KaRIn on SWOT: Characteristics of Near-Nadir Ka-Band Interferometric SAR Imagery," in IEEE Transactions on Geoscience and Remote Sensing, vol. 52, no. 4, pp. 2172-2185, April 2014.
    doi: 10.1109/TGRS.2013.2258402
    Abstract: The principal instrument of the NASA/CNES wide-swath altimetry mission Surface Water and Ocean Topography (SWOT) is the Ka-band Radar Interferometer (KaRIn), a bistatic synthetic aperture radar (SAR) system operating on near-nadir swaths on both sides of the satellite track. There are limited reports on backscattering from natural surfaces at this short wavelength and particular observation geometry. Near-field backscattering measurements on water, as well as the first interferometric airborne SAR acquisitions at Ka-band covering the 0.6 °-3.9 ° incidence range of KaRIn, were therefore conducted. The experimental results confirm expected characteristics of near-nadir Ka-band interferometric SAR imagery, such as strong water/land radiometric contrast (typically in the order of 10 dB) and very high interferometric coherence on water.
    keywords: {backscatter;hydrological techniques;oceanographic techniques;radar imaging;radar interferometry;radiometry;remote sensing by radar;spaceborne radar;synthetic aperture radar;KaRIn;NASA-CNES wide-swath altimetry mission;SAR system;SWOT;Surface Water and Ocean Topography;bistatic synthetic aperture radar system;interferometric airborne SAR acquisition;interferometric coherence;natural surfaces;near-field backscattering measurement;near-nadir Ka-band interferometric SAR imagery;near-nadir swath;observation geometry;satellite track;water-land radiometric contrast;Backscatter;Land surface;Rough surfaces;Sea measurements;Sea surface;Surface waves;Synthetic aperture radar;Altimetry;hydrology;interferometry;millimeter wave radar;oceanography;synthetic aperture radar},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6553583&isnumber=6695798
     
  12. X. Wu, S. Hensley, E. Rodriguez, D. Moller, R. Muellerschoen and T. Michel, "Near nadir Ka-band sar interferometry: SWOT airborne experiment," 2011 IEEE International Geoscience and Remote Sensing Symposium, Vancouver, BC, 2011, pp. 2681-2684.
    doi: 10.1109/IGARSS.2011.6049755
    Abstract: To better prepare data processing system of the Ka-band Radar Interferometer (KaRIn) for the Surface Water and Ocean Topography (SWOT) [1] mission, we opportunistically collected data over several diverse fresh-water targets in the Van Hook Arm areas of North Dakota, USA, using a Ka-band interferometric radar [2] developed at JPL. To make the collection relevant to SWOT, the aircraft was rolled to direct the antenna boresight toward nadir to mimic the SWOT geometry. Using a modified airborne interferometric SAR processor [3] developed at JPL, we were able to process the collected Ka-band airborne data and produced the height and magnitude image products. These results are the first of the kind for Ka-band interferometric synthethic aperture radar over water surfaces with near nadir looking geometry. These initial results will help to characterize the power returns from water surface and land, and provide guidance for the design of post-processing algorithms including methods for water and land classification. The height accuracy we get from the water surface height images can be used to project the water surface height accuracy we would get from SWOT mission. This airborne experiment will help us verify the SWOT data processing chain and make us better prepared for SWOT data processing task.
    keywords: {airborne radar;data analysis;geophysical image processing;hydrological techniques;image classification;radar antennas;radar interferometry;synthetic aperture radar;Ka-band airborne data;Ka-band interferometric synthethic aperture radar;Ka-band radar interferometer;North Dakota;SWOT airborne experiment;SWOT geometry;Surface Water and Ocean Topography mission;data processing system;diverse freshwater target analysis;land classification method;modified airborne interferometric SAR processor;nadir Ka-band SAR interferometry;postprocessing algorithm;water classification method;water surface height image analysis;Antennas;Data processing;Land surface;Radar;Sea surface;Surface topography;Surface treatment;KaBand radar interferometry;SAR;SWOT},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6049755&isnumber=6048881
     
  13. R. Fjørtoft et al., "Validation of radiometric models and simulated KaRIn/SWOT data based on ground and airborne acquisitions," 2011 IEEE International Geoscience and Remote Sensing Symposium, Vancouver, BC, 2011, pp. 2685-2688.
    doi: 10.1109/IGARSS.2011.6049756
    Abstract: The principal instrument of the wide-swath altimetry mission SWOT is KaRIn, a Ka-band interferometric SAR system operating on near-nadir swaths on both sides of the satellite track. Due to the short wavelength and particular observation geometry, there are very limited reports on the backscattering from natural surfaces. Models and simulators that cover radiometric and geometric aspects have therefore been developed. This article describes airborne acquisitions and ground measurements that are used to validate the models and simulators, and shows some preliminary results.
    keywords: {data acquisition;geophysical image processing;geophysical techniques;radar imaging;radar interferometry;radiometry;synthetic aperture radar;Ka-band interferometric SAR system;airborne acquisition;backscattering model;ground measurement method;near-nadir swath analysis;radiometric model;simulated KaRIn/SWOT data;wide-swath altimetry mission SWOT;Antenna measurements;Atmospheric modeling;Extraterrestrial measurements;Land surface;Sea measurements;Sea surface;Surface topography;Altimetry;Ka-band;interferometry},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6049756&isnumber=6048881 
  14. F. Cao, F. Tupin, J. M. Nicolas, R. Fjørtoft and N. Pourthié, "Extraction of water surfaces in simulated Ka-band SAR images of KaRIn on swot," 2011 IEEE International Geoscience and Remote Sensing Symposium, Vancouver, BC, 2011, pp. 3562-3565.
    doi: 10.1109/IGARSS.2011.6049991
    Abstract: The future spatial SWOT mission will use a new altimetric sensor "KaRIn", which is a Ka-band interfero metric SAR system operating on near-nadir swaths on both sides of the satellite track [1]. The objective is to study the height of the earth's water surfaces, mainly oceans, but also continental water surfaces such as lakes and rivers. This article dedicated to water surface detection methods, presents a multi-scale line extraction approach that has been adapted to the specificities of the KaRIn instrument, and gives some preliminary results obtained on simulated SAR images.
    keywords: {hydrological techniques;lakes;oceanographic techniques;oceanography;radar altimetry;radar imaging;radar interferometry;rivers;sea level;synthetic aperture radar;Earth water surface height;Ka-band interferometric SAR system;KaRIn altimetric sensor;continental water surfaces;lakes;multiscale line extraction approach;near-nadir swaths;oceans;rivers;satellite track;simulated Ka-band SAR images;spatial SWOT mission;water surface detection methods;water surface extraction;Detectors;Feature extraction;Image segmentation;Rivers;Roads;Sea surface;Shape;Hydrological network extraction;SWOT KaRIn images},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6049991&isnumber=6048881 
  15. J. F. Nouvel, J. Martinot-Lagarde, H. Oriot and R. Fjortoft, "Near-Nadir Ka-band radar backscattering measurements over wate surfaces, in preparation of the swot mission," OCEANS 2011 IEEE - Spain, Santander, 2011, pp. 1-4.
    doi: 10.1109/Oceans-Spain.2011.6003394
    Abstract: In order to support future altimetry space missions in Ka-band, an airborne campaign has been realized with the ONERA BUSARD platform and its DRIVE radar. The particularity of this campaign is the line of sight geometry, with very steep incidence angles, using a Ka-band SAR interferometer instrument. The area of interest was the Camargue region in south of France. Five flights were planned on dry and wet land surface and sea surface with different wind conditions. In this paper, we describe the context of the campaign, and the sensor configuration that has been used. We then present the areas that have been measured and show an example of aircraft trajectory. Finally, we present some images and interferometry products that have been acquired and produced at very steep angles (0-15° of incidence). In addition we expose some extracted backscattering coefficient profiles, as a function of the incidence angle. Nadir backscattered levels are close to values found in literature, and specular behavior is found on pond surfaces while more diffuse returns are observed over sea and ground surfaces.
    keywords: {airborne radar;backscatter;radar interferometry;synthetic aperture radar;DRIVE radar;Ka-band SAR interferometer instrument;ONERA BUSARD;SWOT mission;airborne campaign;interferometry;near-Nadir Ka-band radar backscattering measurements;Backscatter;Calibration;Land surface;Radar;Sea measurements;Sea surface;Surface topography;Ka-band;SAR;altimetry mode;interferometry;radar sensor},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6003394&isnumber=6003381
     
  16. R. Fjørtoft et al., "KaRIn - the Ka-band radar interferometer on SWOT: Measurement principle, processing and data specificities," 2010 IEEE International Geoscience and Remote Sensing Symposium, Honolulu, HI, 2010, pp. 4823-4826.
    doi: 10.1109/IGARSS.2010.5650601
    Abstract: The principal instrument of the SWOT (Surface Water and Ocean Topography) altimetry mission is KaRIn, a Ka-band interferometric SAR system operating on near-nadir swaths on both sides of the satellite track. This article briefly describes the measurement principle, the processing steps and the specificities of the interferometric SAR data of KaRIn as compared to conventional spaceborne SAR systems.
    keywords: {airborne radar;height measurement;oceanographic techniques;radar interferometry;surface topography measurement;synthetic aperture radar;Ka-band radar interferometer;KaRIn;SWOT;altimetry mission;ocean topography;sapaceborne SAR;satellite track;surface water topography;Extraterrestrial measurements;Interferometry;Land surface;Satellites;Sea measurements;Sea surface;Surface treatment;Ka-band;KaRIn;SAR;SWOT;altimetry;hydrology;interferometry;near-nadir;oceanography},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=5650601&isnumber=5648802
  17. D. Esteban-Fernandez, L. L. Fu, E. Rodriguez, S. Brown and R. Hodges, "Ka-band SAR interferometry studies for the SWOT mission," 2010 IEEE International Geoscience and Remote Sensing Symposium, Honolulu, HI, 2010, pp. 4401-4402.
    doi: 10.1109/IGARSS.2010.5652302
    Abstract: The primary objective of the National Research Council (NRC) Decadal Survey recommended SWOT (Surface Water and Ocean Topography) Mission is to measure the water elevation of the global oceans, as well as terrestrial water bodies (such as rivers, lakes, reservoirs, and wetlands), to answer key scientific questions on the kinetic energy of ocean circulation, the spatial and temporal variability of the world's surface freshwater storage and discharge, and to provide societal benefits on predicting climate change, coastal zone management, flood prediction, and water resources management. In this paper, we present the overall concept of the SWOT mission, as well as the scientific rational, objectives and development status of the technology items currently under development.
    keywords: {interferometry;oceanographic techniques;synthetic aperture radar;Ka-band SAR interferometry;SWOT mission;climate change prediction;coastal zone management;flood prediction;global ocean;kinetic energy;ocean circulation;ocean topography;surface freshwater storage;synthetic aperture radar;terrestrial water body;water resource management;Radar;Radar antennas;Sea measurements;Sea surface;Surface topography;Altimetry;Synthetic Aperture Radar},
    URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=5652302&isnumber=5648802

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