Slide 1

MULTI-FREQUENCY, MULTI-POLARIZATION AND ANGULAR MEASUREMENTS OF BARE SOIL, SNOW AND WATER ICE MICROWAVE REFLECTION AND EMISSION BY C-, Ku-, AND Ka-BAND, COMBINED SCATTEROMETER- RADIOMETER SYSTEMS Artashes Arakelyan, Astghik Hambaryan, Vardan Hambaryan, Vanik Karyan, Mushegh Manukyan, Melanya Grigoryan, Gagik Hovhannisyan, Arsen Arakelyan, Marine Simonyan and Mariam Krdyan ECOSERV Remote Observation Centre Co. Ltd. www.ecoservroc.com 2 G. Njdeh Str., #24, Yerevan, 375006, ARMENIA Phone: (374 10) 421 877/425 088; Fax: (374 10) 421 877 emails: arakelyanak@yahoo.com; ecoservroc@yahoo.com Slide 2 Abstract In this presentation the results of simultaneous and spatially coincident, multi-polarization measurements of snow, bare soil and fresh water ice microwave reflective (radar backscattering coefficient) and emissive (brightness temperature) characteristics angular dependences at 5.6GHz, 15GHz and 37GHz will be represented. As well as structural and operational features of ArtAr-5.6 (C-band), ArtAr-15 (Ku-band) and ArtAr-37 (Ka-band), dual-polarization, combined scatterometric-radiometric systems will be discussed. Slide 3 Utilized Devices Multi-polarization, combined scatterometric radiometric systems ArtAr-5.6 ArtAr-15ArtAr-37 Slide 4 C and Ku-band systems has three operational modes for their transmitters, suitable for short (5m-50m), middle (30m-250m) and long distance (150m-2500m and more) applications from flying, moving or stationary fixed measuring platforms. C and Ku-band systems has three operational modes for their transmitters, suitable for short (5m-50m), middle (30m-250m) and long distance (150m-2500m and more) applications from flying, moving or stationary fixed measuring platforms. Ka-band system has only short (5m-50m) range application mode for its transmitter, suitable for low altitude moving or stationary fixed measuring platforms Ka-band system has only short (5m-50m) range application mode for its transmitter, suitable for low altitude moving or stationary fixed measuring platforms Slide 5 Time division channeling is used for each systems scatterometer and radiometer functioning, to provide required electromagnetic decoupling. Time diagrams of the systems operation T P Transmission of a pulse at v or h pol. Radar reception at vv and vh pol. or at hh and hv pol. Radiometric reception at v and h pol. T P u T S T T Time for receivers protection T P r T S T B T T R For a single pulse case t Radar reception at vv and vh pol. T P Transmission of a train of pulses at v or h pol. Radiometric reception at v and h pol. Time for receivers protection T S T R e T P u T P r T B T For a case of a train of N pulses T R t Transmission of a pulse of the train at v or h pol. Slide 6 Artar-5.6 C-Band Artar-15 Ku-Band Artar-37 Ka-Band Central frequency 5.6GHz15GHz37GHz Antenna type / beamwidth Parabolic antenna/~6 0 Parabolic antenna/~7 0 Horn antenna/~9 0 Radar pulses, type and duration for: Short distance application mode Middle distance application mode Long distance application mode a train of 8 a single pulse pulses, 25ns each of 0.1mks of 1mks a train of 8 pulses, 25ns each Radar pulse power Short distance application mode Middle distance application mode Long distance application mode 50mW 150mw 0.5W 75mW 250mw 1W 35mW Pulse repetition frequency within a train 1.6MHz A train or a single pulse repetition frequency 1KHz Radar receivers noise factor ~2dB Radar receivers bandwidth ~40MHz Radiometer receivers bandwidth ~ 500MHz~ 600MHz~ 800MHz Radar channels sensitivity~-126dB/W Radar channels sensitivity at 1s< 0.1K~0.15K~0.3K The main technical characteristics of the used devices Slide 7 The Experimental Site of ECOSERV ROC Company Slide 8 MEASUREMENT AND CALIBRATION FACILITIES Slide 9 Slide 10 Calibration by Sky Slide 11 Calibration by Sky, a Chart sample, 37GHz The level when the Input Key switched off antenna at v pol. and at h pol. The Observation angle ~ 30 0 The level when the Input Key switched off antenna at v pol. and at h pol. Radiometer Caliber 18K at v and at h pol. Radiometer Calibers 18K at v pol. nd at h pol. Sky Level at v pol. and at h pol. Sky Level at v pol. and at h pol. Sky Level at v pol. and at h pol. Radiometer Caliber 18K at h pol. and at v pol. Change of Polarization from h to v Slide 12 Soil Measurements Chart Sample, 15GHz 14.03.2011, Experiment-4.1, Combed soil Radar channel, vv pol. Radar channel, vh pol. Radiometric channel, v pol. Radiometric channel, h pol. Radar Calibers Radar Channels 0 Level Radiometer Calibers 18K Combed Soil at =80 0 Combed Soil at =20 0 The level when the Input Key switched off antenna Slide 13 Charts Continuation Radar Channels 0 Level Combed Soil at =0 0 Radar channel, pol. vv Radar channel, pol. vh Radiometric channel, pol. v Radiometric channel, pol. h Combed Soil at =0 0 Radiometer Calibers 18K The level when the Input Keys switched off antenna Radar Calibers Combed Soil at =0-5 0 Radiometer Calibers 18K Combed Soil at =80 0 Radar Channels 0 Level Combed Soil at =80 0 Slide 14 THE RESULTS OF MEASUREMENTS Backscattered signals level Radar channels 0 Level Radar caliber signals level Radiometer caliber signals level Surface emission signals level Input Keys emission level The value of radiometric calibers 18K or so Input Keys physical temperature Input Keys emissivity Slide 15 , dB Semi-Dry Snow, thickness ~ 7.5cm t snow ~ -1 0 C, t air ~ 1 0 C Semi-Dry Snow, thickness ~ 7.5cm t snow ~ -1 0 C, t air ~ 1 0 C, K, K 5.6GHz, Feb. 2010 Wet Snow, thickness ~ 7.5cm t snow ~ -0 0 C, t air ~ 2 0 C, dB, K, K Wet Snow, thickness ~ 7.5cm t snow ~ -0 0 C, t air ~ 2 0 C 5.6GHz, March. 2010 Slide 16 , dB Dry Snow, thickness ~ 13.5cm t snow ~ -2 0 C, t air ~ -6 0 C Dry Snow, thickness ~ 13.5cm t snow ~ -2 0 C, t air ~ -6 0 C, K, K 5.6GHz, Feb. 2010, dB Semi-Dry, thickness ~ 14.5cm t snow ~ -0.5 0 C, t air ~ -1 0 C Semi-Dry, thickness ~ 14.5cm t snow ~ -0.5 0 C, t air ~ -1 0 C, K, K 37GHz, 2 Feb. 2011 Slide 17 Dry Snow, thickness ~ 9cm t snow ~ -1 0 C, t air ~ -2 0 C Dry Snow, thickness ~ 9cm t snow ~ -1 0 C, t air ~ -2 0 C, dB, K, K 5.6GHz, Feb. 201037GHz, 4 Feb. 2011 Dry Snow, thickness ~ 8.5cm t snow ~ -1 0 C, t air ~ -5 0 C Dry Snow, thickness ~ 8.5cm t snow ~ -1 0 C, t air ~ -5 0 C, dB, K, K Slide 18 Wet Snow, thickness ~ 7.5cm t snow ~ -0 0 C, t air ~ 2 0 C Wet Snow, thickness ~ 7.5cm t snow ~ -0 0 C, t air ~ 2 0 C, K, K 5.6GHz, Feb. 2010, dB, K, K Wet Snow, thickness ~ 2-3cm t snow ~ -0 0 C, t air ~ 5.5 0 C Wet Snow, thickness ~ 2-3cm t snow ~ -0 0 C, t air ~ 5.5 0 C 37GHz, 9 Feb. 2011 Slide 19 37GHz, 11 Feb. 2011, dB Soil and dry stems of vegetation, soil moisture m m=21%, t air ~ 5 0 C, t soil ~ 3-4 0 C Soil and dry stems of vegetation, soil moisture m m=17%, t air ~ 3 0 C, t soil ~ 2 0 C, K, K, K, K Soil and dry stems of vegetation, soil moisture m m=17%, t air ~ 3 0 C, t soil ~ 2 0 C Soil and dry stems of vegetation, soil moisture m m=21%, t air ~ 5 0 C, t soil ~ 3-4 0 C 37GHz, 16 Feb. 2011 Slide 20 , dB, K, K Soil and dry stems of vegetation, soil moisture m m=11%, t air ~ 8 0 C, t soil ~ 5 0 C 37GHz, 23 Feb. 2011 Soil and dry stems of vegetation, soil moisture m m=11%, t air ~ 8 0 C, t soil ~ 5 0 C Soil and dry stems of vegetation, soil moisture m m=21%, t air ~ 2 0 C, t soil ~ 2 0 C, dB, K, K Soil and dry stems of vegetation, soil moisture m m=21%, t air ~ 2 0 C, t soil ~ 2 0 C 37GHz, 28 Feb. 2011 Slide 21 , dB, K, K Soil and dry stems of vegetation, soil moisture m m=17%, t air ~ 3 0 C, t soil ~ 4 0 C Soil and dry stems of vegetation, soil moisture m m=17%, t air ~ 3 0 C, t soil ~ 4 0 C, dB Soil and dry stems of vegetation, soil moisture m m=17%, t air ~ 3 0 C, t soil ~ 4 0 C Soil and dry stems of vegetation, soil moisture m m=17%, t air ~ 3 0 C, t soil ~ 4 0 C 37GHz, 7 March 201115GHz, 7 March 2011, K, K Slide 22 , dB, K, K 37GHz, 14 March 201115GHz, 14 March 2011 Uncombed and combed soils, soil moisture m m=23.9%, t air ~ 12 0 C, t soil ~ 8 0 C, dB, K, K Uncombed and combed soils, soil moisture m m=23.9%, t air ~ 12 0 C, t soil ~ 8 0 C Slide 23 , dB Combed soil, soil moisture m m=16.7%, t air ~ 18 0 C, t soil ~ 14 0 C, K, K, K, K 37GHz, 20 March 201115GHz, 20 March 2011 Slide 24 , dB, K, K, K, K Dug soil, soil moisture m m=16.7%, t air ~ 16 0 C, t soil ~ 14 0 C Dug soil, soil moisture m m=16.7%, t air ~ 16 0 C, t soil ~ 14 0 C Dug soil, soil moisture m m=16.7%, t air ~ 16 0 C, t soil ~ 14 0 C Dug soil, soil moisture m m=16.7%, t air ~ 16 0 C, t soil ~ 14 0 C 37GHz, 20 March 201115GHz, 20 March 2011 Slide 25 , dB, K, K Fresh water ice, thickness ~13.5cm t ice ~ -4 0 C, t air ~ -13 0 C, t water ~ 0-1 0 C 5.6GHz, Feb. 2010, dB, K, K Fresh water ice, thickness ~17cm t ice ~ -2 0 C, t air ~ -3 0 C, t water ~ 0-1 0 C Fresh water ice, thickness ~17cm t ice ~ -2 0 C, t air ~ -3 0 C, t water ~ 0-1 0 C 5.6GHz, Feb. 2010 Slide 26 , dB, K, K Fresh water ice, thickness ~10cm t ice ~ -1 0 C, t air ~ -3 0 C, t water ~ 1-2 0 C Fresh water ice, thickness ~10cm t ice ~ -1 0 C, t air ~ -3 0 C, t water ~ 1-2 0 C 5.6GHz, Feb. 2010, dB, K, K Fresh water ice, thickness ~7.5cm t ice ~ -1 0 C, t air ~ 9 0 C, t water ~ 3 0 C Fresh water ice, thickness ~7.5cm t ice ~ -1 0 C, t air ~ 9 0 C, t water ~ 3 0 C 5.6GHz, Feb. 2010 Slide 27 , dB Fresh water ice, thickness ~3-4cm t ice ~ -1 0 C, t air ~ -5.5 0 C, t water ~ 2 0 C Fresh water ice, thickness ~3-4cm t ice ~ -1 0 C, t air ~ -5.5 0 C, t water ~ 2 0 C, K, K 37GHz, 4 Feb. 2011 Fresh water ice, thickness ~ 2cm t ice ~ -0.5 0 C, t air ~ 8 0 C, t water ~ 2 0 C Fresh water ice, thickness ~ 2cm t ice ~ -0.5 0 C, t air ~ 8 0 C, t water ~ 2 0 C, dB, K, K 37GHz, 9 Feb. 2011 Slide 28 37GHz, 28 Feb. 2011 Pool water surface t air ~ 2 0 C, t water ~ 4 0 C Pool water surface t air ~ 2 0 C, t water ~ 4 0 C Sky temperature, cloudy t air ~ 2 0 C,, dB, K, K, K, K, K, K 37GHz, 28 Feb. 2011 Clear Sky temperature, t air ~ 2 0 C, Pool water surface t air ~ 2 0 C, t water ~ 4 0 C Soil and dry stems of vegetation, soil moisture m m=17%, t air ~ 2 0 C, t soil ~ 2 0 C Slide 29 CONCLUSION Thus, simultaneous and spatially coincident multi-frequency and multi-polarization measurements are an actual and significant tool to improve existed reflective and radiative transfer models of soil, snow, ice, soil vegetation and sea surface. Thus, simultaneous and spatially coincident multi-frequency and multi-polarization measurements are an actual and significant tool to improve existed reflective and radiative transfer models of soil, snow, ice, soil vegetation and sea surface. Slide 30 Such measurements are an effective way: forsolution of the problems applied to soil and snow moistures and temperatures precise and unambiguous retrievals. for solution of the problems applied to soil and snow moistures and temperatures precise and unambiguous retrievals. for sea surface wind and wave fields parameters, sea temperature and salinity precise and unambiguous retrievals. for sea surface wind and wave fields parameters, sea temperature and salinity precise and unambiguous retrievals. for detection and classification of soil and sea surface and sub-surface (underground) signatures and targets. for soil vegetation classification and parameters evaluation, etc. Slide 31 This presentation has an aim as well to attract the attention of interested researchers to the existed experimental site and microwave devices (scatterometer- radiometer systems of S, C, Ku, K and Ka-band of frequencies), and to invite them to use these devices in their field campaigns or to perform joint researches using available devices, measuring and calibration facilities of our Company. This presentation has an aim as well to attract the attention of interested researchers to the existed experimental site and microwave devices (scatterometer- radiometer systems of S, C, Ku, K and Ka-band of frequencies), and to invite them to use these devices in their field campaigns or to perform joint researches using available devices, measuring and calibration facilities of our Company. Slide 32 Acknowledgements Combined radar-radiometer systems and the experimental site were developed and built due to the finances provided by International Science and Technology Center of Moscow (ISTC) and by the US Civilian Research and Development Foundation (CRDF) in collaboration with Cortana Corporation. Combined radar-radiometer systems and the experimental site were developed and built due to the finances provided by International Science and Technology Center of Moscow (ISTC) and by the US Civilian Research and Development Foundation (CRDF) in collaboration with Cortana Corporation. Authors express their gratitude to both foundations and to Cortana Corporation for their financial maintenance in planned works fulfillment. Authors express their gratitude to both foundations and to Cortana Corporation for their financial maintenance in planned works fulfillment. Slide 33 Thank you ! Thank you ! Slide 34