Aerial photographic and satellite image interpretation

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. Areas in a vertical aerial photograph often have a consistent size. 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. Black and white aerial photography is capable of producing good-quality images under poor weather conditions, such as foggy and misty air. 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 (IR) 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 ==

. 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 ==

Size : The size of an object is one of the most distinguishing characteristics and one of the most important elements of interpretation. Most commonly, length, width and perimeter are measured. To be able to do this successfully, it is necessary to know the scale of the photo. Measuring the size of an unknown object allows the interpreter to rule out possible alternatives. It has proved to be helpful to measure the size of a few well-known objects to give a comparison to the unknown-object. For example, field dimensions of major sports like soccer, football, and baseball are standard throughout the world. If objects like this are visible in the image, it is possible to determine the size of the unknown object by simply comparing the two. Shape : There is an infinite number of uniquely shaped natural and man-made objects in the world. A few examples of shape are the triangular shape of modern jet aircraft and the shape of a common single-family dwelling. Humans have modified the landscape in very interesting ways that has given shape to many objects, but nature also shapes the landscape in its own ways. In general, straight, recti-linear features in the environment are of human origin. Nature produces more subtle shapes. Shadow : Virtually all remotely sensed data are collected within 2 hours of solar noon to avoid extended shadows in the image or photo. This is because shadows can obscure other objects that could otherwise be identified. On the other hand, the shadow cast by an object act as a key for the identification of the object as the length of the shadow will be used to estimate the height of the object which is vital for the recognition of the object. Take for example, the Washington Monument in Washington D.C. While viewing this from above, it can be difficult to discern the shape of the monument, but with a shadow cast, this process becomes much easier. It is a good practice to orient the photos so that the shadows are falling towards the interpreter. A pseudoscopic illusion can be produced if the shadow is oriented away from the observer. This happens when low points appear high and high points appear low. Tone and color : Real-world materials like vegetation, water and bare soil reflect different proportions of energy in the blue, green, red, and infrared portions of the electro-magnetic spectrum. An interpreter can document the amount of energy reflected from each at specific wavelengths to create a spectral signature. These signatures can help to understand why certain objects appear as they do on black and white or color imagery. These shades of gray are referred to as tone. The darker an object appears, the less light it reflects. Color imagery is often preferred because, as opposed to shades of gray, humans can detect thousands of different colors. Color aids in the process of photo interpretation. Texture : This is defined as the “characteristic placement and arrangement of repetitions of tone or color in an image.” Adjectives often used to describe texture are smooth (uniform, homogeneous), intermediate, and rough (coarse, heterogeneous). It is important to remember that texture is a product of scale. On a large scale depiction, objects could appear to have an intermediate texture. But, as the scale becomes smaller, the texture could appear to be more uniform, or smooth. A few examples of texture could be the “smoothness” of a paved road, or the “coarseness” a pine forest. Pattern : Pattern is the spatial arrangement of objects in the landscape. The objects may be arranged randomly or systematically. They can be natural, as with a drainage pattern of a river, or man-made, as with the squares formed from the United States Public Land Survey System. Typical adjectives used in describing pattern are: random, systematic, circular, oval, linear, rectangular, and curvilinear to name a few. Height and depth : Height and depth, also known as “elevation” and “bathymetry”, is one of the most diagnostic elements of image interpretation. This is because any object, such as a building or an electric pole that rises above the local landscape will exhibit some sort of radial relief. Also, objects that exhibit this relief will cast a shadow that can also provide information as to its height or elevation. A good example of this would be buildings of any major city. ==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. When the moistened film dries, it expands through one orientation and contracts through the other orientation. Only a small amount of distortion is caused by this. == Pre-digital interpretation methods using a mirror stereoscope ==

• Choose two (2) aerial photos which are taken one after the other and make sure there is at least 60% superimposition. • Make sure they are placed in the same orientation and the northern part of the aerial photograph as well as the generated shadows should be placed towards the interpreter. • Make sure the distance between the pair of eyepieces, a lens used in the stereoscope for observation, fits the distance between the eyes. • Put both forefingers on the same, easily identified object in each of the photos. • Slowly drag the photos until the two objects are overlapped under the stereoscope. • The overlapped areas then appear 3D under the stereoscope.. == See also ==