An Application of Remote Sensing Imagery for Geological Lin- eaments Extraction over Kaybarkuh Region in East of Iran

Kaybarkuh (Mount Kaybar) consists of intrusive igneous bodies with two age periods, located in North of Dasht-e-Bayaz left-lateral fault terminal. The spatial and structural analysis of fractures and dike networks may allow for the accurate identification of mineralization zones in the area. This study aims to characterize lineament network in the study area by automatic method using multispectral satellite images from Landsat 8 Operational Land Imager (OLI), visual extraction of lineaments from Landsat-8 and SENTINEL-2 images, and extraction of drainage network as lineament based on digital elevation models (DEMs) and their validation, compared with fault network of the area. The results showed that there is a significant relationship between the trend of studied lines in the region by the three methods mentioned and the overall trend is about N3300. This can indicate a tensile regime with a trend perpendicular to the mentioned orientation, which results from the activity of the Dasht-e-Bayaz fault. Finding more evidences requires further studies.


Introduction
In the past years, lineament analysis has become an important analytical technique for delineation of major structural units in mineral prospecting, hydrogeology, and tectonic studies [1]. In remote sensing images, geological lineaments show up as lines or linear structures that are significantly brighter or darker than the background pixels [2]. Genetically, three types of lineaments are separated; (i) geological lineaments, (ii) Geomorphological or topographic lineaments, and (iii) Pseudo, manmade, or non Geological lineaments [3]. Lineaments related to fractures may provide pathways for fluid flow and contribute to the formation of many economically significant oil, geothermal, and water supply reservoirs. Fracture systems control the dispersion of chemical contaminants into and through the subsurface [4]. The technology of geological lineaments extraction is of great significance for the analysis of regional plate movement and ore forming prognosis. However, the traditional methods are mainly based on the semi-automatic or manual visual interpretation, which consuming time and labor for the dependence on the rich professional experience and knowledge of the interpreter experts, and involving less in the special geomorphological regions [5].
The first Landsat satellite, launched in 1972 within the Landsat Data Continuity Mission, has a nearly 42-year global record. Two generations of Landsat satellites have now been launched by the National Aero-nautics and Space Administration and the United States Geological Survey. The first generation (Landsat-1, -2 and -3) operated from 1972 to 1985 and has essentially been replaced by the second generation (Landsat-4, -5 and -7). Landsat-6, launched in 1993, failed to enter orbit [6]. Landsat-8 was launched on 4 February 2013 from Vandenberg Air Force Base in California. It is an American Earth observation satellite and joins Landsat-7 on-orbit, providing increased coverage of the Earth's surface. It is a free-flyer spacecraft carrying two sensors, the Operational Land Imager (OLI) and the Thermal Infrared Sensor (TIRS). These two instruments collect images for nine visible, near-infrared and shortwave infrared bands and two long-wave thermal bands. They have high signal-to-noise radiometer performance, allowing 12-bit quantification of data, thus providing more bits for better landcover characterization. Landsat-8 pro-vides moderate-resolution imagery, from 15 to 100m of the Earth's surface and polar regions [7][8][9]. The Shuttle Radar Topography Mission (SRTM) datasets result from a collaborative effort by the National Aeronautics and Space Administration (NASA) and the National Geospatial-Intelligence Agency (NGA -previously known as the National Imagery and Mapping Agency, or NIMA), as well as the participation of the German and Italian space agencies. Together, this international space collaboration generates a near-global digital elevation model (DEM) of the Earth using radar interferometry.
SRTM was the primary, and virtually only, payload on the STS-99 mission of the Space Shuttle Endeavour, which launched February 11, 2000 and flew for 11 days. Following several hours for instrument deployment, activation, and checkout, systematic interferometric data were collected within a 222.4-hour period. The instrument operated almost flawlessly and imaged 99.96 percent (%) of the targeted landmass at least one time, 94.59% at least twice, and about 50% at least three or more times. The goal was to image each terrain segment at least twice from different angles (on ascending, or north-going, and descending, or south-going, orbit passes) to fill areas shadowed from the radar signal by terrain [10]. 1 Near infrared 2 Short wave infrared 3 Thermal infrared V. Khademi et al.

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The full SENTINEL-2 mission comprises twin polar-orbiting satellites in the same orbit, phased at 180° to each other. The mission will monitor variability in land surface conditions, and its wide swath width and high revisit time (10 days at the equator with one satellite, and 5 days with 2 satellites under cloud-free conditions which results in 2-3 days at mid-latitudes) will support monitoring of changes to vegetation within the growing season. The coverage limits are from between latitudes 56° south and 84° north. SEN-TINEL-2 will carry an optical instrument payload that will sample 13 spectral bands: four bands at 10 m, six bands at 20 m and three bands at 60 m spatial resolution. The orbital swath width will be 290 km. [11]

Study area
The study area is located in the Eastern terminal of sinistral Dasht-e-Bayaz fault with an approximate area of 570 km 2 in East of Iran (Figure 1-a). Geographical range of the area is 34° 0' 0'' -34° 17' 24'' N and 59° 34' 0'' -59° 54' 32'' E. Kaybarkuh consists of two intrusive igneous bodies including granite and granodioritic mass with age of Cretaceous in North, and a Paleocene basalt -andesitic body in South, that southern part is the goal of this study (Figure 1-b). There are plenty of sinistral strike-slip faults and North-South and West-East direction dykes in Southern part. In this part, vein mineralization is visible in boundary and fractures of masses that include two following types: 1. Veins with galena, sphalerite, and barite as primary minerals depending to first generation of mineralization. 2. Veins with pyrite, chalcopyrite, and quartz as primary minerals, and covellite, bornite, chalcosite, malachite, azurite, and iron oxides as secondary minerals from second generation of mineralization. Trend of veins containing ore minerals such as copper is generally N-NW especially in southern part of Kaybarkuh.

Methodology
Our methodology involves an analysis of geological lineaments of the study area that was performed by using below three methods:

DEM Extraction
Active deformation in tectonically active region has a significant influence on the drainage network behavior [12,13]. Drainage networks are key factors for investigating the regional tectonic activity, and deformational process of active faults [14,15].
To extract drainage, we used DEM tiff image downloaded from SRTM digital elevation data at USGS website. The process of extraction performed in Arcmap environment as shown in (Figure 2). To reduce accidental occurrences and better tectonic-related valleys reveal, extracted lines were divided into separate sections based on the direction by the Polar Plot tool, then sections shorter than 200 meters were removed. The result polyline shapefile was clipped by rocky outcrop border to ignore the streams in the Quaternary units.

Automatic Lineament Extraction
Although visual extraction of lines is the most common method, automatic line detection methods can greatly reduce user error and even identify lines that are not easily recognizable to the naked eye. To extract lineaments of the study area automatically, we used landsat-8 image with applying some of image processing methods to enhance the edge and direction of lineaments.
One of the common problems in remote sensing and high resolution image processing is the need for somehow fusing lower resolution, multispectral (MS) bands such as Red, Green, Infrared, etc., with the single, higher resolution Pan band. Ideally, the MS bands can be up-sampled to the full Pan resolution without altering their spectral properties. Since its publication in 1998, the Gram-Schmidt pan-sharpen method has become one of the most popular algorithms to pan-sharpen multispectral (MS) imagery. It outperforms most other pan-sharpen methods in both maximizing image sharpness and minimizing color distortion [16].
Lineaments were extracted by using sufficient values of PCI Geomatica LINE module parameters software. PCI LINE (PCI Geomatics) offers an alternative, widely applied and robust method to automatically extract lineaments. The basic approach of PCI Line is similar to the object based approach. The only difference is the fact that the PCI line bases on the robust Canny edge detection algorithm. [17]. Classification accuracy evaluation demonstrated that the Canny edge filter gives best results among tested algorithms [18]. The properties of used image are [2021-08-19, 08:39:39, Geometric RMSE model = 3.437]. Automatically extracted lineaments were shown on Gram-Schmidt sharpened true color image (Figure 3-a), and PCI Geomatics processed image (Figure 3-b).

Visual Lineament Extraction
Visual identification of lineaments is mainly based on the experience of the operator [1]. By using visual interpretation in GIS software, all fault lines in the area were extracted on images obtained by applying directional filters, principal component analysis, band ratios, and color composition. In extracting lineaments, several markers were used including displacements of layers, rivers, and alluvial fans, linear vegetation, linear valleys, fault scarps, changes in the lithology, abrupt changes in slope and bed segments, fragmentation along outcrops, joints, and fractures. As shown in (Figure 4), the Sentinel-2 image with V. Khademi et al.

Discussion
After extracting, loading and comparing the lines in GIS software, we conclude that the obtained lines are in most cases compatible with each other (Figure 6). The statistical data of the extracted lineaments by three methods with the fault network of the region, taken from the 1:100,000 scale geological map, were shown in Figure 7. Excessive standard deviation of data in the fault network can be attributed to the small scale of the map used and the very long length of the fault lines. Figure 8 shows rose diagram of the resulting lineaments. Examination of the most numerous lines from DEM data shows that their main direction is East-West, which is probably due to the elongation of the outcrops in the North-South direction and the effect of topography. The second dominant direction in these lines is about N330° which is Aligned with the trend of lines in other methods.

Conclusion
In this paper, we attempted for mapping lineaments and knowledgebase preparation using three methods for south of Kaybarkuh. Throughout this study, pan-sharpened Landsat-8 image was analyzed for automatic lineaments extraction under user suggested parameters values within LINE module of PCI Geomatica software. Also hill shaded images of mentioned satellite with three azimuths and Sentinel-2 image were used to extract lineaments visually. Finally, DEM data helped us to extract drainage network as structural lineaments. As it appears from the results, there is a significant relationship between the trends of structural lineaments resulted from the three methods. As shown in Figure 6, the general trend of lineaments is about N330°. The study area is located in the northeastern part of the left-lateral Dasht-e-Bayaz fault terminal, so it can be concluded that the lines with mentioned trend were formed due to tension mechanism as normal faults, dikes or opened veins and the perpendicular lines, i.e. the trend of about N60° might be of the strike-slip type.