Graph of y = tan(θ)
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Understanding the Graph of y = tan(θ)
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Today, we will explore the graph of y = tan(θ). Can anyone tell me what they already know about tangent?
I know that tangent is related to the opposite and adjacent sides of a right triangle.
That's correct! The tangent function is indeed defined as tan(θ) = opposite/adjacent. How do you think this relates to its graph?
I guess it means the graph could have values depending on the angle?
Exactly! The values of tan(θ) will change dramatically as θ approaches certain angles, specifically where the function becomes undefined, like 90° and 270°. This leads us to the next concept: vertical asymptotes!
What are vertical asymptotes?
Great question! Vertical asymptotes are lines where the function goes to infinity, causing the graph to be undefined. For the tangent function, this occurs at every odd multiple of 90°.
So, are there specific key points on the graph we should remember?
Yes! Some critical points include: tan(0°) = 0, tan(45°) = 1, and at 90°, the function is undefined. Remembering these values can help sketch the graph.
In summary, the graph of y = tan(θ) has a repeating pattern, vertical asymptotes at odd multiples of 90°, and key points at tan(0°) and tan(45°).
Properties of the Tangent Graph
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Now that we've covered the basics, let's explore the properties of the tangent graph. What do you think happens to the values when we input angles greater than 90°?
I think it would keep increasing or maybe decrease?
Correct! The tangent function is periodic with a period of 180°. This means it will repeat its values every 180°. Can anyone calculate tan(180°) for me?
That would be 0, right?
Exactly! Now, since the tangent function goes to positive infinity just before reaching 90°, can you visualize how that looks on the graph?
Yes, I can see it going up and approaching a straight line.
Fantastic! That's the vertical asymptote around θ = 90°. This pattern repeats for every 180°, creating more asymptotes. Always remember, across each period, the graph will start again from tan(0°) = 0.
To summarize, the tangent graph has vertical asymptotes at odd multiples of 90°, a period of 180°, and key points we need to memorize.
Sketching the Tangent Function
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Now, let’s practice sketching the graph of y = tan(θ). What is our starting point?
I think we start at the origin.
Correct! That’s where tan(0°) = 0. Now, where do we place our first asymptote?
At 90°!
Exactly! From the origin, if we sketch the curve, it will rise indefinitely as we approach 90°. What comes next after 90°?
Then it jumps back from -∞ to 0 at 180°.
Perfect! Now, as you sketch between these points, remember that you’ll have another asymptote at 270°, and it will repeat thereafter. Make sure to label these points accurately.
In summary, sketching the tangent function involves plotting key points and recognizing asymptotes at odd multiples of 90°. Excellent work today, everyone!
Introduction & Overview
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Quick Overview
Standard
The graph of y = tan(θ) features a repeating curve with vertical asymptotes and a periodicity of 180° (or π). It is undefined at specific angles, highlighting its unique properties compared to sine and cosine functions.
Detailed
Detailed Summary
The graph of the tangent function, represented as y = tan(θ), exhibits distinctive properties including a repeating curve and vertical asymptotes. Unlike the sine and cosine graphs, which oscillate between fixed amplitude values, the tangent function continues indefinitely, having a period of 180° (or π radians). The function is specifically undefined at angles such as θ = 90°, 270°, etc., where it approaches vertical asymptotes. Understanding these characteristics is crucial as they demonstrate how the tangent function behaves differently in comparison to sine and cosine functions. Key points include:
- Shape of the Graph: The tangent graph appears as a series of curves that continue up and down, with segments cut off at vertical asymptotes.
- Periodicity: The periodic nature of the tangent function repeats every 180° (or π), contrasting with the sine and cosine that repeat every 360° (or 2π).
- Key Points: Important reference points include tan(0°) = 0 (the function crosses the origin), tan(45°) = 1, demonstrating the positive slope at 45°, and undefined behavior at 90°. Additionally, these characteristics are essential for applying trigonometric concepts in various real-world contexts, including physics and engineering.
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Shape of the Graph
Chapter 1 of 4
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Chapter Content
✅ Graph of y = tan(θ)
• Shape: Repeating curve with vertical asymptotes
Detailed Explanation
The graph of the function y = tan(θ) resembles a repeating curve. This is because the tangent function returns to similar values periodically. However, it also has vertical asymptotes, meaning there are specific angles (like 90° and 270°) where the function is undefined, causing the graph to approach infinity on either side.
Examples & Analogies
Imagine a roller coaster that goes up and down. It has points where it cannot go further up (these points are like our vertical asymptotes). Similar to how the roller coaster cannot operate safely at those points, the tan graph cannot produce values at its asymptotes.
Period of the Tangent Function
Chapter 2 of 4
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Chapter Content
• Period: 180° or π
Detailed Explanation
The period of the tangent function is 180° (or π radians), meaning that the graph repeats its pattern every 180°. If you were to look at the graph starting from 0° and then again at 180°, they would look identical.
Examples & Analogies
Think of watching waves on an ocean. For every 180° (or every certain distance depending on the wave), you will see a complete cycle of waves rising and falling in the same pattern. The pattern of the waves repeats the same way just like the tangent graph.
Undefined Points on the Graph
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• Undefined at: θ = 90°, 270°, ...
Detailed Explanation
The tangent function is undefined at certain angles such as 90° and 270°. This occurs because at these angles, the cosine value is zero, and since tangent is defined as sine divided by cosine (tan(θ) = sin(θ)/cos(θ)), you cannot divide by zero. Hence, the graph cannot continue at these points.
Examples & Analogies
Imagine trying to divide a pizza that has no slices (the denominator being 0). It's impossible to give out slices; similarly, at those angles, the tangent function can't provide values, creating a break in the graph.
Key Values of the Tangent Function
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• Key points:
o tan(0°) = 0
o tan(45°) = 1
o tan(90°) = undefined (vertical asymptote)
Detailed Explanation
Key points provide specific values of the tangent function at important angles. For example, at 0°, tan(0°) equals 0, meaning the output starts low. At 45°, tan(45°) equals 1, indicating a significant increase. As you approach 90°, the tangent becomes undefined, indicating that the function can no longer provide a value.
Examples & Analogies
Imagine climbing a hill. Starting at the bottom (tan(0°) = 0), you make your way up to a peak (tan(45°) = 1), and when you reach a cliff where you can go no further and must turn back (tan(90°) = undefined).
Key Concepts
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Tangent Function: Defined as the ratio of the opposite side to the adjacent side in a right triangle, it varies continuously over its domain.
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Vertical Asymptotes: Tangent function exhibits vertical asymptotes at odd multiples of 90°, indicating where the function becomes undefined.
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Periodicity: The tangent graph has a periodicity of 180°, repeating its values across intervals.
Examples & Applications
Example 1: For angles θ = 0°, 45°, and 90°, we find the values of tan(θ) to sketch its graph.
Example 2: The function tan(30°) equals √3/3, showcasing a specific point on the tangent curve.
Memory Aids
Interactive tools to help you remember key concepts
Rhymes
At zero, the tan is right in the middle, at 90 it’s undefined, oh what a riddle!
Stories
Imagine climbing a hill that keeps steepening until you reach 90°, where it suddenly drops away. That's how tan behaves — slopes steepen until the steepest point is too high to manage!
Memory Tools
Use the phrase: 'The Tangent Travels Too Tall' to remember that it touches 0 at the start but climbs high towards 90°.
Acronyms
TAP - Tangent's Asymptote Positions
Remember the key asymptote positions at 90° and 270°.
Flash Cards
Glossary
- Tangent Function
A trigonometric function defined as the ratio of the opposite side to the adjacent side in a right triangle, represented as tan(θ).
- Vertical Asymptote
A line that the graph approaches but never touches or crosses, occurring where the function is undefined.
- Periodicity
The characteristic of a function to repeat its values in regular intervals, specific to the tangent function being every 180°.
- Key Points
Specific values of θ where the function yields notable outputs, like tan(0°) = 0 and tan(45°) = 1.
Reference links
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