Aerial photographic and satellite image interpretation
Aerial photographic and satellite image interpretation, or just image interpretation when in context, is the act of examining photographic images, particularly airborne and spaceborne, to identify objects and judging their significance. This is commonly used in military aerial reconnaissance, using photographs taken from reconnaissance aircraft and reconnaissance satellites.
The principles of image interpretation have been developed empirically for more than 150 years. The most basic are the elements of image interpretation: location, size, shape, shadow, tone/color, texture, pattern, height/depth and site/situation/association. They are routinely used when interpreting aerial photos and analyzing photo-like images. An experienced image interpreter uses many of these elements intuitively. However, a beginner may not only have to consciously evaluate an unknown object according to these elements, but also analyze each element's significance in relation to the image's other objects and phenomena.
Angle of view
Vertical imagery and photographs
Vertical aerial photographs represent more than 95% of all captured aerial images. The principles of capturing vertical photographs are shown in Figure 2. Two major axes which originate from the camera lens are included. One is the vertical axis which is always at 90° to the study area. Another one is the camera axis which changes with the angle of the camera. To capture a vertical aerial photograph, both of these axes must be in the same position. The vertical pictures are captured by the camera which is above the object being photographed without any tilting or deviation of the camera axis. Areas in a vertical aerial photograph often have a consistent size.Oblique aerial photographs
Oblique aerial photographs are captured when the cameras are set at specific angles to the land. It is a very helpful enhancement or addition to the traditional vertical image. It allows the vision to pass through a relatively high proportion of the plant cover and leaves of trees. Oblique aerial photographs can be classified into two types.Low oblique
Low oblique aerial photographs are generated when the camera axis has a 15–30° angle difference from the vertical axis, shown in figure 3. The horizon, the dividing border between planet and atmosphere from a viewing angle, is unobservable in a low oblique aerial photograph. The length between two points is unable to be calculated and is not accurate because a low oblique image does not have a scale. The orientation of objects is also inaccurate. Low oblique photographs can be used as a reference before site investigation because they give updated details of local places.High oblique
High oblique aerial photographs are generated when the camera axis has a 60° angle difference from the vertical axis, shown in figure 4. In this case, the horizon is observable. This type of photograph captures a fairly sizable region. As in a low oblique photograph, the length between two points and the orientation of objects are inaccurate. High oblique aerial photographs are widely used in assisting field investigation because the line of sight shown is more similar to humans. Features and structures can be easily recognized. However, landscapes, buildings and hillslopes that are blocked by the mountainous areas are not visible.Color and false color
Black and white
Black and white aerial photographs are frequently used for drawing maps, such as topographic maps. Topographic maps are precise, in-depth descriptions of the terrain characteristics found in the areas or regions. Black and white aerial photography is capable of producing good-quality images under poor weather conditions, such as foggy and misty air.Color
Color aerial photographs preserve and capture the colors of the original objects through the numerous layers inside the film. Color photographs can be used to distinguish different kinds of soils, rocks, and deposits that are located above the rock layers, and some contaminated water sources. The degradation of trees driven by the insects can also be identified using color aerial photos. It can assist in locating storage of materials in the natural environment, such as trees, wild animals and oil.Color infrared
Color infrared aerial photographs are captured using false color film which changes the original color of different features into "false color". For example, grasslands and forests which are green in nature have a red color. But some artificial objects which are covered in green may have a blue color. This phenomenon is due to the fact that plants reflect more infrared radiation than man-made objects. Dense vegetation cover may give a more intense red color than that of sparse vegetation cover. This helps in determining whether the trees are healthy or not. It also gives evidence for the growth rate of plants. It is helpful when identifying the boundary between land and ocean or lakes because the ocean does not reflect the IR.Altitudes
High-altitude
High-altitude aerial photographs are taken when the plane is flying in the altitude range of 10,000 to 25,000 feet. The advantage of high-altitude aerial photography is that it can record the information of a larger area by taking one photograph only. However, high-altitude photographs cannot show as many details as low-altitude photographs since some objects, such as buildings, roads, and infrastructures, are of a very tiny in size in the image.Low-altitude
Low-altitude aerial photographs are taken when the plane is flying at an altitude of less than 10,000 feet. The objects in the photograph are of a larger in size and contain more details compared with those in high-altitude photographs. Due to this advantage, a routine collection of low-altitude photographs has been conducted every six months since 1985.Scale
of aerial photography or satellite imagery is the value calculated when the elevation difference between the photo film and the camera lens is divided by the difference between the camera lens and the terrain surface. It can also be measured by dividing the measured length of two locations in the photo by the length of those locations in reality. In figure 5, several related terms and symbols are shown. Focal length refers to the elevation difference between the film and the lens. H is the elevation difference between the lens and the sea level, which is the average level of the water surface. h is the elevation difference between the terrain surface and the sea level. S is the scale of aerial photographs. is the formula for scale measurement. This measurement controls the amount and types of buildings observed in the photographs, the occurrence of some specific characteristics, and the certainty of the measurements. For example, a large-scale photograph usually gives a more accurate measurement of distance compared with a small-scale photograph. 1:6000 to 1:10000 is the best range of scale for landslip research and geological mapping for ground assessment.Large-scale imagery
Large-scale aerial photographs are those taken at a scale of 1:500 to 1:1000. This type of photograph is best suited for local site investigations. It looks like a zoomed-in map.Small-scale imagery
Small-scale aerial photographs are those taken at a scale of 1:5000 to 1:20000. It is more suitable for provincial or large area research.Interpreting imagery
Elements to interpret
Size
Shape
Shadow
Tone and color
Texture
Pattern
Height and depth
Other factors to consider during interpretation
Photograph Metadata
An aerial photograph marks different data and information about the covered area and the airplane's position and condition. These details are measured and noted by the data panel which includes different devices and instruments for the specific measurements. Figure 8 shows the general format of a vertical aerial photograph.File:Format of aerial photograph 2.png|right|thumb|Figure 8: Details on an aerial photograph. It includes the focal length, flying height, location, photo number, recorded time and date, etc.
Location
Site background and association
Aerial photographs overlap
Overlapping of aerial photos means that around 60% of the covered area of every aerial image overlays that of the one before it. Every object along the flying path can be observed twice at a minimum. The purpose of overlapping the aerial photography is to generate the 3D topography or relief when using a stereoscope for interpretation. The stereoscope is an instrument used to see the 3D overlapping aerial images.Reaching the requirements of the two chosen, overlapping images is simple. The principal points of the two photos must be in different locations on the terrain. Another restriction is that the scale of the images must be the same. The flying routes of the planes and the time of day are not restricted.