Academic literature on the topic 'Radar Camouflage'

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Journal articles on the topic "Radar Camouflage"

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Huang, Jian. "Research on Gas Gush Smoke Camouflage Device for Transport Vehicle." Applied Mechanics and Materials 685 (October 2014): 178–81. http://dx.doi.org/10.4028/www.scientific.net/amm.685.178.

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Transport vehicle gas gush Smoke camouflage device, By use of its own power system and storage devices, Will be made in advance the size of the different, structure, function of polystyrene particles blown apart, Thus formed around the top of the vehicle and polystyrene particles as the main ingredients of camouflage a Smoke, To cover vehicles and interference against the infrared guidance, the purpose of the millimeter wave radar guidance weapon attacks.
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Kang, Qianlong, Dekui Li, Wei Wang, Kai Guo, and Zhongyi Guo. "Multiband tunable thermal camouflage compatible with laser camouflage based on GST plasmonic metamaterial." Journal of Physics D: Applied Physics 55, no. 6 (November 2, 2021): 065103. http://dx.doi.org/10.1088/1361-6463/ac31f5.

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Abstract In this paper, we propose a simple plasmonic structure based on Ge2Sb2Te5 (GST) to realize tunable multiband camouflage and radiation heat dissipation. In the mid-infrared (MIR) (3–5 μm) range, the proposed structure has average emissivity of 0.18 ∼ 0.76 and can be applied in tunable thermal camouflage as the GST’s crystallization fraction increases from 0 to 1. In the 5–8 μm (safe window) range, radiation heat dissipation of the proposed structure may guarantee thermal stability of the system. In the long-infrared (8–14 μm) range, the designed emitter maintains a relatively stable and low average emissivity of 0.13 ∼ 0.19 when the crystallization fraction of GST changes from 0 to 1. In addition, due to surface lattice resonance of plasmonic metamaterial, our designed emitter can also achieve laser radar camouflage at the wavelength of 10.6 μm. We have also analyzed the dependence of the camouflage performance on the GST’s crystallization fractions, polarization angle and incident angle. Moreover, simulated thermal images demonstrate tunable thermal camouflage for various background temperatures and different ambient backgrounds in the MIR ranges.
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Holovan’, A. V., V. H. Holovan’, and M. O. Drozdov. "Capabilities of passive anti-radar weapons and equipment camouflage." Military Technical Collection, no. 6 (May 4, 2012): 193–98. http://dx.doi.org/10.33577/2312-4458.6.2012.193-198.

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Singh, Jaydeep, and Dharmendra Singh. "An Analytical Approach to Design Camouflage Net for Microwave Absorption." Defence Science Journal 69, no. 5 (September 17, 2019): 469–73. http://dx.doi.org/10.14429/dsj.69.14953.

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Microwave absorption has been the key for reduction of radar cross section in the field of stealth technology. In this field, hiding troop details from reconnaissance systems is taken care by enhancing absorption properties of the material. The demand of masking detectable equipment can be met with the help of a flexible net type structure called camouflage net. Optimising and measuring the absorption of the net, comprising of cloth and coating of the radar absorbing materials over the cloth is very challenging task. The task is being accomplished by using trial and error method, which is very cumbersome process and leads to tremendous waste of potential, material and manpower. Therefore, an attempt to develop an analytical methodology using the permittivity and permeability of the fabric material, to minimise this limitation, has been presented in this paper by critically analysing simulated results for various composites. The approach seems to have good potential for developing the camouflage net, especially in the microwave regime.
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Neel, Matthew S. "Demonstrating acoustic camouflage with ultrasonic sensors in the laboratory." Physics Education 57, no. 4 (April 14, 2022): 045017. http://dx.doi.org/10.1088/1361-6552/ac5cd9.

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Abstract Similar to how stealth materials were developed to reduce the radar wave energy returning from an aircraft, here we explore a low-cost laboratory demonstration that uses similar principles to prevent detection of an object by an ultrasonic sensor. This demonstration setup can be used as a starting point to encourage students to explore the surface properties of materials and the ways in which ultrasonic ranging sensors operate.
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Wysocki, Krzysztof, and Martyna Niewińska. "Counteracting imagery (IMINT), optoelectronic (EOIMINT) and radar (SAR) intelligence." Scientific Journal of the Military University of Land Forces 204, no. 2 (June 15, 2022): 222–44. http://dx.doi.org/10.5604/01.3001.0015.8975.

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The development of military technique and technology forces necessary changes in military reconnaissance using advanced methods of contemporary battlefield imaging. This paper addresses the topic of imagery intelligence as an essential source for gaining information about the deployment and quantity of means and forces of a potential enemy. Currently, armies of the world are equipped with modern imagery intelligence systems that make it possible to collect, process and analyse the collected data on enemy’s troops and the environment in which the enemy operates. The purpose of the study is to present the proper role of camouflage undertakings that make it possible to counteract imagery, optoelectronic and radar intelligence. The increasing capabilities in this problem area mean that in the near future intelligence tasks will be carried out not only by ground, space or naval systems, but primarily by reconnaissance aircraft and unmanned aerial systems. In accordance with the problem indicated in the topic, the paper brings closer the possibilities of counteracting imagery intelligence from the theoretical and practical perspective. In addition, it presents the latest camouflage solutions employed both in the Polish Armed Forces and other selected armies. At the end of the paper, the authors formulate the most important conclusions that constitute a generalisation of the results of studies presented in different parts of the publication.
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Hong, Ic-Pyo. "Analysis of Radar Cross Section Characteristics for Camouflage Net with Stealth." Journal of Korean Institute of Information Technology 13, no. 4 (April 30, 2015): 53. http://dx.doi.org/10.14801/jkiit.2015.13.4.53.

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Zhao, Ziyu, Pibo Ma, Haitao Lin, and Fenglin Xia. "Radar-absorbing Performances of Camouflage Fabrics with 3D Warp-knitted Structures." Fibers and Polymers 21, no. 3 (March 2020): 532–37. http://dx.doi.org/10.1007/s12221-020-9775-1.

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D.N. VLADIMIROV. "Innovative Nanomaterials for Effective Camouflage and Reduced Radar Observability of Military Hardware." Military Thought 25, no. 004 (December 31, 2016): 131–38. http://dx.doi.org/10.21557/mth.48304788.

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Yu, Bin, Lu Qi, Jian-zhong Ye, and Hui Sun. "The Research of Radar Absorbing Property of Bicomponent Fibers with Infrared Camouflage." Journal of Polymer Research 14, no. 2 (November 25, 2006): 107–13. http://dx.doi.org/10.1007/s10965-006-9089-z.

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Dissertations / Theses on the topic "Radar Camouflage"

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Perry, David Robert. "Target detection and scene classification with VNIR/SWIR spectral imagery." Thesis, Monterey, Calif. : Springfield, Va. : Naval Postgraduate School ; Available from National Technical Information Service, 2000. http://handle.dtic.mil/100.2/ADA384999.

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Betancourt, Benjamin. "A fuzzy approach to automatic target recognition applied to bare and camouflaged synthetic aperture targets." To access this resource online via ProQuest Dissertations and Theses @ UTEP, 2007. http://0-proquest.umi.com.lib.utep.edu/login?COPT=REJTPTU0YmImSU5UPTAmVkVSPTI=&clientId=2515.

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Vas, Joseph Vimal. "Electromagnetic Properties of Carbon Based Polymer Nanocomposites for Shielding, Chaffing and Camouflage Applications." Thesis, 2016. http://etd.iisc.ac.in/handle/2005/4332.

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High conductivity is a prerequisite for any material for it to be used in the field of electromagnetics. Metals like copper and aluminium are used for a variety of electromagnetic (EM) applications in industries like electronics, communication, avionics as well as in defence owing to their high conductivity. Metals are generally used to either reflect or attenuate the EM fields. For a material to be considered for any EM application, it should have good electrical and mechanical properties and should be economically viable. Along with good electrical conductivity, high permeability and permittivity are also preferable for such materials. The mechanical properties include light weight, good strength to weight ratio, easy to fabricate and resistance to environmental and galvanic corrosion. Polymers present an interesting alternative to metals for EM applications because of their excellent mechanical properties like good strength to weight ratio. They are easily moldable into the required geometry and are cost effective. But most of the commercially available polymers are insulating. Hence the challenge is to develop conducting polymers with good mechanical properties. There are two types of conducting polymers – intrinsically conducting polymers also known as conjugated polymers and conducting polymer composites. In the case of conjugated polymers, the polymers are intrinsically conducting. Some examples of these polymers are polyaniline, polypyrrole, polythiophenes and polyacetylene. The conductivity is achieved by virtue of their conjugated π electrons. The conductivity of these polymers can be varied from semiconducting to metal like by doping. Even though the conductivity of the doped conjugated polymers is attractive for EM applications, they have poor mechanical properties. The electrical and mechanical properties of conducting polymer composites make them suitable for EM applications. Conducting polymer composites is the other option for obtaining polymers with excellent mechanical as well as electrical properties. In this case conducting fillers like carbon, aluminium or silver are added into an insulating polymer like polyethylene, polypropylene or silicone rubber to form a conducting polymer composite. The conductivity achieved in this case is because of a phenomenon known as percolation. The polymer exhibits conductivity only beyond a filler loading called percolation threshold. The percolation threshold of a composite depends on the shape, size and conductivity of the filler, and its interaction with the base polymer. In this study, conducting polymer composites are designed for various applications like shielding, chaffing and camouflage. When a material is exposed to an EM field, three types of losses are incurred namely reflection, absorption and multiple reflection losses. The reflection loss depends primarily on the conductivity of the material; the absorption loss depends on the conductivity and the imaginary permittivity whereas the multiple reflection loss depends primarily on the thickness of the material. For a material to be used as an EM shield, the total attenuation in the material should be high. For chaffing applications, the reflection loss has to be maximum while for camouflage applications, the absorption loss has to be maximum with minimum reflection. For all those applications, the material should possess nominal dc conductivity. Hence the primary objective of this study was to improve the conductivity of the polymer. Once the high conductivity is achieved, the properties of the material can be appropriately tuned for chaffing and camouflage. The objectives of this research work can be summarized as follows. (1) Understand the effect of particle size, shape and conductivity of fillers on the electrical properties of the composites; (2) Develop a mathematical model to predict the conductivity of various types of composites, (3) Synthesize different polymer nanocomposites and measure the shielding effectiveness of the composites using ASTM D4935 method in the frequency range of 30 MHz to 1.5 GHz; (4) Understand the factors limiting the shielding effectiveness of various composites; (5) Design a new type of composite to overcome the limitations of the traditional composites to achieve extremely high shielding effectiveness of more than 60 dB, (6) Propose a new strategy for the measurement of shielding effectiveness of composites in the frequency range up to 18 GHz, (7) Segregate the reflection and absorption loss within the shielding material so as to adapt the material developed for chaffing and camouflage applications. In the present study, carbon-based fillers dispersed in silicone rubber polymer is used. Silicone rubber was used due to its excellent mechanical properties and ease of processing. Carbon makes excellent filler because of its high conductivity and its availability in various shapes and sizes. Carbon nanotubes, carbon nano fibres, spherical nano carbon particles and carbon micro coils are some of the forms of carbon that are commercially available. Micron sized carbon has been used in various industries to improve the mechanical properties of rubber and other polymers. The first step to design a carbon-based conducting composite would be to choose the shape and size of the carbon filler to be used. As stated earlier, the conductivity in the case of polymer composites can be explained by percolation theory. The composites become conducting once the filler loading goes beyond the percolation threshold. Hence to synthesize a conducting polymer, the percolation threshold for different shapes and sizes has to be calculated. Various models are available for predicting the percolation behaviour of composite like statistical, thermodynamic and the geometric percolation models. Of these the statistical models are computationally intensive but they provide the flexibility to study various filler geometries. The thermodynamic percolation models emphasize the interfacial interactions between the polymer and the filler but do not study the effect of filler shape, size and orientation. Geometric models are specifically used for solid mixtures. The advantages of statistical and thermodynamic models are combined and a new Monte Carlo (MC) based method is devised for studying the percolation behaviour of the composite. The MC method was implemented for spherical particles and fibre like particles and the percolation threshold was calculated for particles of different particle sizes. The percolation threshold was then compared with the thermodynamic Mamunya model and there was a good correlation between the two models. The model was then used to study the effect of particle diameter, aspect ratio and the distribution of particle sizes, on the percolation threshold and the conductivity of the composites. When the size of the filler particles was decreased from micron to nano, the percolation threshold is reduced. It was also seen that the percolation threshold of the composite reduced when the distribution of particle size had larger standard deviation. This could be one of the reasons for the discrepancy between the percolation values obtained experimentally and those calculated using statistical models. It was also seen that there was not much variation in composite conductivity beyond the percolation threshold for a given filler. The conductivity of the composite can be increased further if the interparticle distance between the fillers is reduced or by increasing the filler conductivity. In the case of composites with fiber like fillers it was seen that the percolation threshold of fibres was less than that of spherical particles with the same diameter. This was because for the same filler loading, the interparticle distance is significantly reduced in fibers. The conductivity behaviour obtained using fibres was comparable to those of the spherical particles beyond the percolation threshold. The quantum tunneling of electrons was responsible for facilitating the composite conductivity. Hence from the MC studies it was concluded that, by using fibres instead of spherical particles the filler loading required to attain conductivity in composites can be significantly reduced. Increasing the filler loading beyond the percolation threshold would not be advantageous. The polymer nanocomposites were synthesized using silicone rubber (SR) as the base polymer and multiwalled carbon nanotubes (MWCNT) or carbon nanofibers (CNF) as fillers. The size and shape of the fillers used were studied by Scanning Electron Microscopy (SEM). The mixing methodology employed included ultrasonication of the polymer- filler mixture and high temperature curing to obtain samples of different shapes and geometries. Samples with up to 4% filler loading of either MWCNT or CNF filled SR were made. The dispersion of fillers within the polymer matrix is important for a predictable performance of the nano composites. This was measured by studying the variation of filler content in different cross sections of the polymers using the Energy Dispersive X-ray (EDX). It was seen that there was not much variation in filler distribution and hence the mixing methodology was adequate to produce samples of good dispersion. Direct methods of conductivity measurement are difficult due to the nature of the composites. The composite samples have high surface resistance which can lead to problems regarding improper contact with the electrodes. The conductivity of different composites was measured using a 4 probe van der Pauw method. It was seen that both the MWCNT and CNF filled SR samples became conducting with 4% filler loading. The percolation threshold in the case of MWNCT filled SR is found to be 1.5% whereas for the CNF filled SR it becomes conducting beyond 1%. This was because of the higher aspect ratio of the CNF. Beyond the percolation threshold, both the MWCNT and CNF filled SR showed similar conductivity. The shielding effectiveness (SE) of the samples was measured using the ASTM D4935 -2010 method. As the method is meant for samples of high surface resistance, the measurement is done as a comparison between a test sample and a reference sample made of the same material but different geometry. The frequency range of this measurement was from 30 MHz to 1.5 GHz. It was seen that the maximum shielding effectiveness was of the order of 6 dB. In the frequency range specified, the shielding effectiveness is due to the surface conductivity of the sample. The dimensions of the filler particles (< 200 μm) were much smaller than the wavelength (0.2 – 10 m) in use. The shielding effectiveness is expected to improve in the X and Ku band. Thus, the shielding effectiveness of these traditional composites is limited. This was insufficient for producing shielding materials and hence a different approach is required From the MC studies, it was evident that the limitation in the composite conductivities was due to the interparticle distance between the fillers. The conductivity of the materials could therefore be improved if better electrical contact between different filler particles is achieved. Thus, a new method was developed for producing a new type of polymer composite namely polymer composite layered with CNF wafers. Ag- S nanoparticles were developed in the lab to bind the different CNF particles at the nano level. The CNF fibers bound by the Ag-S nanoparticles were converted into a wafer and the wafers were used for sandwiching the SR polymer filled with CNF. The SEM studies conducted on the CNF wafer produced showed that its structure was a collection of Ag- S nodes binding different CNF particles. There were lot of voids within the CNF wafer. The interaction between Ag-S nanoparticles and CNFs were due to π-π interactions. When the polymer was poured on to the CNF wafer surface, the polymer percolated into the CNF wafer matrix. This resulted in the expansion of the CNF wafer and helped in a good binding between the polymer and the CNF wafer. The shielding effectiveness of the SR composites layered with CNF wafers was studied. It was seen that these layered composites had high SE of 60 dB, in the 30 MHz to 1.5 GHz frequency range. The SE of these composites could be improved by increasing wafer thickness or adding more number of layers or increasing the CNF loading in the composite. The SE of the composites was improved by sandwiching 2% CNF filled SR with two CNF wafers. Beyond this filler loading, the SE did not improve. When an unfilled SR is sandwiched between two CNF wafers, these wafers expand due to the percolation of SR. When 2% CNF filled SR is used, the CNF fillers in SR act as an electrical contact between wafers, but the expansion is reduced due to increased viscosity. Adding more fillers ceases the expansion and hence the SE does not improve further. The high SE of the SR composites sandwiched with CNF wafers along with the good mechanical properties make them good alternatives for shielding applications. The shielding effectiveness of the conventional CNF and MWCNT composites, and the SR composites layered with CNF wafers were measured in the frequency range up 18 GHz. There is no standard method for measuring the SE of materials beyond 1.5 GHz. Hence a new method is devised. The measurements are based on IEEE-299 method which is actually meant for measuring the SE of enclosures in the frequency range of up to 100 GHz. The sample to be studied for SE performance is mounted in a circular hole in the cable penetration panel of an anechoic chamber. The measurements were conducted by illuminating the sample using a ridged horn antenna and SE was calculated as the difference in transmitted field in the absence and in the presence of the sample. It was seen that the shielding effectiveness of CNF and MWCNT filled SR composites as less when compared to the SR composites sandwiched with CNF wafers. The SR composite sandwiched with CNF wafers showed shielding effectiveness of more than 80 dB which make them appropriate for all shielding applications.
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Conference papers on the topic "Radar Camouflage"

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Rubežienė, Vitalija, Julija Baltušnikaitė-Guzaitienė, Audronė Sankauskaitė, Hans M. Kariis, and Rolf Jonsson. "Radar camouflage for the soldier." In Target and Background Signatures VII, edited by Karin U. Stein and Ric Schleijpen. SPIE, 2021. http://dx.doi.org/10.1117/12.2599906.

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PRZYBYŁ, W. "Radar Recognition: Paint Coatings with Absorption Properties in the Microwave Range." In Quality Production Improvement and System Safety. Materials Research Forum LLC, 2023. http://dx.doi.org/10.21741/9781644902691-21.

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Abstract. The article presents the characteristics of modern reconnaissance systems in the radar range and camouflage methods for this range. Two absorbers of electromagnetic radiation in the 4-18 GHz range were tested, measuring their attenuation properties. Carbonyl iron and thin-walled hollow microspheres based on soda-lime-borosilicate glass were tested, on the basis of which paint coatings with different shares of absorbers and different coating thicknesses were produced. The attenuation properties of both absorbers were determined and attention was paid to the maximum values and frequencies for which they occur. Further directions of research were also proposed in order to obtain varnish coatings that are an effective camouflage agent in radiolocation.
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Huang, Minling, Weijie Xia, Linlin Huang, Ying Zhou, and Yanjun Pan. "Passive ground camouflage target recognition based on gray feature and texture feature in SAR images." In 2016 CIE International Conference on Radar (RADAR). IEEE, 2016. http://dx.doi.org/10.1109/radar.2016.8059196.

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Steinvall, Ove, Hakan Larsson, Frank Gustafsson, Dietmar Letalick, Tomas Chevalier, Asa Persson, and Pierre Andersson. "Performance of 3D laser radar through vegetation and camouflage." In Defense and Security, edited by Gary L. Wood. SPIE, 2005. http://dx.doi.org/10.1117/12.603546.

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Zhu, Yonggeng, Xinyu Fang, Mengmeng Li, and Dazhi Ding. "Analytical Design of Time-Modulated Metasurface for Multistatic Radar Camouflage." In 2022 International Conference on Microwave and Millimeter Wave Technology (ICMMT). IEEE, 2022. http://dx.doi.org/10.1109/icmmt55580.2022.10022932.

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Conway, Thomas G., James C. Carroll, and Grayson W. Walker. "Correlation Between Material Characteristics And Field Effectiveness Of Radar Scattering Camouflage Screens." In 1988 Technical Symposium on Optics, Electro-Optics, and Sensors, edited by Norman S. Kopeika and Walter B. Miller. SPIE, 1988. http://dx.doi.org/10.1117/12.945769.

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Phillips, Mark W., Stephen M. Hannon, Peter G. Wanninger, Paul J. M. Suni, J. Alex L. Thomson, and Richard D. Richmond. "Range/Doppler Imaging with a Coherent Laser Radar based on Optical Fiber Amplifiers." In Coherent Laser Radar. Washington, D.C.: Optica Publishing Group, 1995. http://dx.doi.org/10.1364/clr.1995.tha2.

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Coherent Technologies, Inc., under funding from a Wright Laboratory SBIR contract, has developed a coherent laser radar based on waveform amplification in single mode erbium-doped fiber amplifiers. The transceiver emits a waveform with a large time-bandwidth product that allows imaging with simultaneous high resolution in both range and velocity for enhanced hard target recognition. The ladar is designed for range-resolved measurement rather than range- precise measurement in order to overcome military imaging countermeasures such as camouflage netting. A number of mechanisms are capable of generating wideband signals, such as amplitude mode-locking and intracavity phase modulation (frequency chirping). For the purposes of coherent ladar, most of these approaches require the injection-locking of the ladar transmitter to the master/local oscillator frequency and are therefore sensitive to transmitter perturbations. A more rugged approach adopted by CTI is to use frequency-shifted feedback (FSF) in a multi-pass amplifier to generate a wideband frequency comb on one side of the input master oscillator frequency. The amplifier can be operated in cw mode (below laser threshold) or in quasi Q- switched mode (above laser threshold) without resonator frequency-pulling effects since the axial mode structure of the laser/amplifier resonator is eliminated by FSF. This allows simple and controlled frequency generation which is insensitive to transmitter perturbations.
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