Tan -135 On Unit Circle

Understanding tan⁻¹(-135°) on the Unit Circle: A Comprehensive Guide

Finding the value of tan⁻¹(-135°) might seem daunting at first, but with a clear understanding of the unit circle and trigonometric functions, it becomes a straightforward process. This comprehensive guide will break down the concept step-by-step, ensuring you grasp not just the answer but the underlying principles. We'll explore the unit circle, the tangent function, inverse trigonometric functions, and address common points of confusion. This will equip you with the knowledge to tackle similar problems confidently.

Introduction to the Unit Circle

The unit circle is a circle with a radius of 1 unit, centered at the origin (0,0) of a coordinate plane. It's a fundamental tool in trigonometry because it provides a visual representation of trigonometric functions. Each point on the unit circle is defined by an angle θ (theta) measured counterclockwise from the positive x-axis and its corresponding coordinates (x, y). These coordinates are directly related to the trigonometric functions:

• x = cos θ: The x-coordinate represents the cosine of the angle.
• y = sin θ: The y-coordinate represents the sine of the angle.

The tangent function is defined as the ratio of sine to cosine:

• tan θ = sin θ / cos θ = y / x

This ratio represents the slope of the line connecting the origin to the point (x, y) on the unit circle.

Understanding Inverse Trigonometric Functions

While trigonometric functions like sine, cosine, and tangent take an angle as input and return a ratio, inverse trigonometric functions do the opposite. They take a ratio as input and return an angle. For example:

• sin⁻¹(x): Returns the angle whose sine is x.
• cos⁻¹(x): Returns the angle whose cosine is x.
• tan⁻¹(x): Returns the angle whose tangent is x.

These inverse functions are also known as arc functions, often written as arcsin(x), arccos(x), and arctan(x). It's crucial to remember that inverse trigonometric functions typically have a restricted range to ensure a unique output for a given input.

Calculating tan⁻¹(-135°)

Now let's focus on calculating tan⁻¹(-135°). This means we need to find the angle whose tangent is -135°. However, there's a subtle but important point: the tangent function is periodic with a period of 180°. This means tan(θ) = tan(θ + 180n), where 'n' is any integer. Consequently, there are infinitely many angles whose tangent is any given value.

To address this ambiguity, the range of tan⁻¹(x) is conventionally restricted to (-90°, 90°). This means the calculator or software will return an angle within this range.

Let's break down the process:

1. Recognize the Negative Tangent: A negative tangent indicates that the angle lies either in the second or fourth quadrant of the unit circle. In these quadrants, either the sine or the cosine is negative, resulting in a negative ratio.

2. Find a Reference Angle: We can ignore the negative sign for now and focus on the magnitude, 135°. We know that the tangent function is not directly defined for 135° because cos(135°) = -√2/2 and sin(135°) = √2/2, resulting in tan(135°) = -1. However, a related angle in the first quadrant has a tangent of 1. In the first quadrant the angle is 45°. We will now find the angle that has a tangent of -1.

3. Determine the Angle in the Restricted Range: Since we are looking for an angle with a tangent of -1, and the range of tan⁻¹(x) is (-90°, 90°), we need to find an angle in this range whose tangent is -1. That angle is -45°. This is because tan(-45°) = -1. Therefore, tan⁻¹(-1) = -45°.

4. Considering the Periodicity: Remember that tan(x) = tan(x + 180n). While -45° is the principal value within the restricted range, other angles like 135° (-45° + 180°), 315° (-45° + 360°), and so on also have a tangent of -1. However, only -45° falls within the standard range of the inverse tangent function.

Graphical Representation

Visualizing this on the unit circle helps solidify the understanding. The angle -45° is measured clockwise from the positive x-axis. The point on the unit circle corresponding to -45° has coordinates (√2/2, -√2/2). The tangent of -45° is the ratio of the y-coordinate to the x-coordinate: (-√2/2) / (√2/2) = -1.

Mathematical Explanation and Trigonometric Identities

The result, tan⁻¹(-1) = -45°, can be further supported by trigonometric identities and the properties of the tangent function. The tangent function is an odd function, meaning tan(-x) = -tan(x). Therefore, tan⁻¹(-1) = -tan⁻¹(1) = -45°. Furthermore, we know that tan(45°) = 1. Using the odd function property, we get tan(-45°) = -tan(45°) = -1.

Frequently Asked Questions (FAQ)

• Q: Why is the range of tan⁻¹(x) restricted?

A: Restricting the range ensures that the inverse tangent function provides a single, unique output for each input. Without a restricted range, there would be infinitely many possible angles.

• Q: How do I handle angles outside the range of -90° to 90°?

A: If you obtain an angle outside this range, you can add or subtract multiples of 180° to find an equivalent angle within the restricted range.

• Q: What if I use a calculator and get a different answer?

A: Calculators might use radians instead of degrees. Ensure your calculator is set to the correct angle mode (degrees or radians). Also, double-check the input value.

• Q: Can I use the unit circle for all inverse trigonometric function calculations?

A: Yes, the unit circle is a powerful visual tool for understanding inverse trigonometric functions. However, for more complex calculations or angles, you might need to use trigonometric identities or a calculator.

Conclusion

Calculating tan⁻¹(-135°) involves understanding the unit circle, the properties of the tangent function, and the concept of inverse trigonometric functions, particularly their restricted ranges. While the principal value is -45°, remember the periodicity of the tangent function and the existence of infinitely many angles with the same tangent value. By mastering these fundamental concepts, you’ll be well-equipped to confidently solve similar problems and deepen your understanding of trigonometry. Remember to always visualize the problem on the unit circle to aid your understanding and intuition. Practice with different examples, and you'll find that these concepts become second nature.