Question

Show that the radius \(r_{\alpha}\) of a latitude circle on the earth at \(\alpha^{\circ}\) is given by \(r_{\alpha}=R \cos \alpha\), where \(R\) is the radius of the -earth.

Short answer

Answer: The formula for the radius of a latitude circle on Earth at a given angle α is given by \(r_{\alpha} = R \cos (\alpha)\), where \(r_{\alpha}\) is the radius of the latitude circle, \(R\) is the Earth's radius, and \(\alpha\) is the angle in degrees.

Step-by-step solution

Define the Earth's geometry

In order to derive the relationship between the radius of a latitude circle and the angle, we will assume that Earth is a perfect sphere with a radius of \(R\). The radius of a latitude circle will be denoted by \(r_{\alpha}\), where \(\alpha\) is the angle in degrees.

Relationship between angle \(\alpha\) and radius \(r_{\alpha}\)

Let's consider a right-angled triangle formed by the center of the Earth (O), a point on the Earth's surface located at latitude \(\alpha\) (A), and the intersection of Earth's surface with its equator (B). In this triangle, angle AOB is equal to \(\alpha\) degrees, and the angle OAB is a right angle.

Calculate the radius of the latitude circle using trigonometry

In the right-angled triangle OAB, we can apply the cosine rule: \(\cos (\alpha) = \frac{Adjacent}{Hypotenuse}\) In our case, the adjacent side corresponds to the length \(r_{\alpha}\) and the hypotenuse is equal to the Earth's radius \(R\). So, we can write the equation as: \(\cos (\alpha) = \frac{r_{\alpha}}{R}\)

Rearrange equation to find \(r_{\alpha}\)

In order to find \(r_{\alpha}\), we can rearrange the equation from Step 3: \(r_{\alpha} = R \cos (\alpha)\) This is the equation that relates the angle \(\alpha\) and the latitude circle's radius \(r_{\alpha}\) to the Earth's radius \(R\).

Key concepts

Earth's Geometry

When we speak of Earth's geometry with respect to latitude calculations, it's important to understand that Earth is almost spherical in shape. While the planet is actually an oblate spheroid—slightly flattened at the poles and bulging at the equator—the difference is small enough that for many calculations, we can approximate it as a perfect sphere. This simplification allows us to use spherical geometry to calculate various properties, such as the radius of a latitude circle.

The latitude of a location on Earth is the angular distance north or south from the equator to that location. As we move from the equator towards the poles, these parallel circles of latitude decrease in radius, culminating in a point at the poles. This geometric concept is crucial for understanding how to derive the radius of a latitude circle, which is directly related to the angle of latitude and the Earth's radius.

Trigonometry in Geography

Trigonometry is an indispensable tool in geography for understanding the relationships between angles and distances on the Earth's surface. The methodology involves using trigonometric ratios—sine, cosine, and tangent—which relate the angles of a triangle to the lengths of its sides. These ratios can provide answers to various geographic problems, such as calculating distances between locations or the heights of geographical features.

Specifically, in the context of latitude circle radius calculation, trigonometry allows us to use the concept of right-angled triangles to derive important geographic measurements. By considering the Earth's center, a point on the surface, and the equator to form a triangle, we can use basic trigonometric functions to find the unknown lengths and angles. This foundational concept facilitates deeper comprehension of the spatial relationships on Earth's curved surface.

Cosine Rule Application

The cosine rule, or the law of cosines, is a formula that relates the lengths of the sides of a triangle to the cosine of one of its angles. In the context of latitude circle calculations, the cosine rule is employed to connect the angle of latitude with the radius of the latitude circle on Earth's surface. Specifically, the rule is applied to a right-angled triangle formed by the radius of Earth, the radius of the latitude circle, and a line segment perpendicular to Earth's radius at the equator.

In the original exercise, we used the ratio that defines the cosine of an angle in a right-angled triangle: \(\cos (\alpha) = \frac{Adjacent}{Hypotenuse}\). By considering Earth's geometry as a sphere with radius \(R\), we substituted the adjacent side with the latitude circle radius \(r_{\alpha}\) and the hypotenuse with \(R\). Rearranging this equation provided a straightforward way to calculate the radius of any latitude circle by simply knowing the Earth's radius and the latitude angle: \(r_{\alpha} = R \cos (\alpha)\). This showcases the elegance of trigonometry and its applications, illustrating how one can compute geographic dimensions on Earth's surface using basic trigonometric principles.