EXPERIMENTATION DESCRIPTION

0243-EX-PL-2009 Text Documents

ARTEMIS, Inc.

2009-07-08ELS_99696

EXHIBIT #1 as part of FCC FORM 442 – APPLICATION FOR NEW RADIO STATION UNDER PART 5 OF FCC RULES – EXPERIMENTAL RADIO SERVICE (OTHER THAN BROADCAST) submitted by ARTEMIS, INC. File # 0243-EX-PL-2009 This exhibit addresses: FORM 442 QUESTION 7: EXPERIMENTATION DESCRIPTION The proposed radiating device is a synthetic aperture radar (SAR) system being developed by ARTEMIS, INC. For the remainder of this document, it will be referred to as “SlimSAR-X,” which is an ARTEMIS, INC. internal designation for this project. SlimSAR-X is an imaging radar designed to be mounted on a small manned aircraft or unmanned aircraft system (UAS) and flown over an area of interest. The radar system transmits a frequency modulated, continuous wave signal, and records any signals reflected by targets on the ground. Description of Equipment and Theory of Operation SAR works in much the same way as traditional surveillance radar systems. A modulated pulse is transmitted, and echoes from targets in the field of view of the radar are recorded. In order to create high-resolution images of the observed area, signal processing techniques are used to coherently average consecutive radar pulses collected from a moving platform. Each of these radar pulses encounters a given target from a slightly different angle, and provides non-redundant information about the target being imaged. When properly processed, SAR images have a much finer resolution in the direction of platform travel than is provided by the antenna footprint alone. SAR images are useful for surveillance and reconnaissance as well as geological, oceanographic, and other scientific observations. Targets and features which may be difficult to detect at IR or optical wavelengths are often quite prominent in SAR images because the illumination source is in the radio frequencies. Man made structures and metal objects, for instance, stand out particularly well. Unlike optical images, the coherent nature of radar transmissions allows the received signals to be aligned to within a fraction of the wavelength of the transmitted signal. This means that two SAR images of a certain area can be compared coherently to reveal even very small changes that have occurred between the two image collections. Thus, for example, footprints or tire tracks may leave an indentation that is only one or two centimeters deep. In a traditional optical image, this may be impossible to distinguish, but if those features are absent in one SAR image and present in a subsequent one, coherent change detection (CCD) will reveal small aberrations such as these. The range resolution of a SAR system is inversely proportional to the bandwidth of the signal being transmitted. It is governed by the relation c0  r= 2B where  r is the range resolution, c 0 is the speed of light in free space, and B is the bandwidth of the transmitted signal. In order to form a high-resolution SAR image, therefore, it is necessary to transmit a high-bandwidth signal. The proposed bandwidth of 740 MHz in one sub-band and 586.6 MHz in a second sub-band gives SlimSAR-X a resolution of approximately 20.3 cm and 27.75 cm, respectively. Experimental methods allow the coherent combination of images created in both sub- bands resulting in a resolution of approximately 16.5 cm. If coherent change detection is to be successful in highlighting small changes in a scene, a very fine resolution image is necessary. (A

Illustration 1: Block diagram showing the transmit signal generation path for SlimSAR-X. detailed description of the SlimSAR-X transmitted waveform is found in Exhibit #3 – MODULATING SIGNAL DESCRIPTION). SAR systems can be classified as either pulsed or continuous wave. A pulsed radar transmits a short radar pulse, and then waits to receive echoes. A continuous wave radar transmits longer pulses with no break between them. SlimSAR-X is a continuous wave SAR system. Because it is constantly transmitting, SlimSAR-X is capable of maintaining a high SNR while operating at a much lower peak transmit power than comparable pulsed SAR systems. SlimSAR-X is designed to transmit a continuous wave signal of only 4 W peak power. A block diagram of the SlimSAR-X transmitter is shown in Illustration 1 . A 370 MHz linear frequency modulated (LFM) signal is generated by a direct digital synthesizer (DDS). This signal is mixed with a 979.4 MHz LO, then the lower sideband is doubled to produce a 740 MHz wide signal. This signal is mixed with either a 7835.2 MHz LO or an 8814.6 MHz LO. This produces two possible transmit signals. The first is 740 MHz and extends from 8934 MHz to 9674 MHz. The second is filtered to 586.6 MHz and extends from 9913.4 MHz to 10500 MHz in order to stay within bands already allocated to the Amateur Radio Service or radiolocation. The signal is transmitted through a directional antenna mounted so that it points at a 45º angle to one side of the aircraft. (A detailed description of the antenna mounting and pattern is found in Exhibit #2 – DIRECTIONAL ANTENNA INFORMATION). Proposed Program of Research The SlimSAR-X system is currently under development and will be ready for testing beginning in September of 2009. Flight tests will be performed on an ARTEMIS Inc. owned, manned aircraft. It is expected that weekly or fortnightly tests of a few hours duration will be adequate to gather necessary data. The data gathered from these tests will be used to verify proper operation of the SlimSAR-X hardware and develop signal processing algorithms which will accomplish the program objectives. These objectives include: – processing of raw SlimSAR-X data into high-resolution images, – combining data from multiple passes for coherent change detection, – developing signal processing algorithms which enhance the utility of the processed data. Algorithm development will be ongoing during the period of flight testing, allowing developers to

request SAR data containing certain test conditions. These conditions can be created during the next scheduled flight test and the data used immediately for rapid development of robust, fully-tested processing algorithms. Contribution to the Advancement of Radar Technology SAR systems have been developed and built for decades, but supporting technologies such as digital processors and storage devices have only recently advanced to the point that small, lightweight, SAR systems are practical and cost-effective. SlimSAR-X's unique design puts it on the cutting edge of small SAR systems designed for operation on an unmanned aircraft system. UAS based surveillance and intelligence-gathering solutions are in high demand, and SlimSAR-X fills a need which has not yet been satisfactorily addressed. The system uses very little power (4 W peak transmit power), but is capable of generating high-quality SAR images which can be used for a number of applications. Of particular interest is the system's capability to generate high-resolution images which can be used for coherent change detection. The data gathered during this program will be instrumental in advancing UAS-based SAR systems.


Document Created: 2019-05-09 07:16:24
Document Modified: 2019-05-09 07:16:24
© 2025 FCC.report
This site is not affiliated with or endorsed by the FCC