1 / 22

14-3

Fundamental Trigonometric Identities. 14-3. Warm Up. Lesson Presentation. Lesson Quiz. Holt Algebra 2. Warm Up Simplify. 1 . 2. . cos A. 1. Objective. Use fundamental trigonometric identities to simplify and rewrite expressions and to verify other identities.

Télécharger la présentation

14-3

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Fundamental Trigonometric Identities 14-3 Warm Up Lesson Presentation Lesson Quiz Holt Algebra 2

  2. Warm Up Simplify. 1. 2. cos A 1

  3. Objective Use fundamental trigonometric identities to simplify and rewrite expressions and to verify other identities.

  4. You can use trigonometric identities to simplify trigonometric expressions. Recall that an identity is a mathematical statement that is true for all values of the variables for which the statement is defined.

  5. Substitute cos θ for and sin θ for A derivation for a Pythagorean identity is shown below. x2 + y2 = r2 Pythagorean Theorem Divide both sides by r2. cos2θ + sin2θ = 1

  6. To prove that an equation is an identity, alter one side of the equation until it is the same as the other side. Justify your steps by using the fundamental identities.

  7. Example 1A: Proving Trigonometric Identities Prove each trigonometric identity. Choose the right-hand side to modify. Reciprocal identities. Simplify. Ratio identity.

  8. Example 1B: Proving Trigonometric Identities Prove each trigonometric identity. Choose the right-hand side to modify. 1 – cot θ = 1 + cot(–θ) Reciprocal identity. Negative-angle identity. = 1 + (–cotθ) Reciprocal identity. = 1 – cotθ Simplify.

  9. Helpful Hint You may start with either side of the given equation. It is often easier to begin with the more complicated side and simplify it to match the simpler side.

  10. Check It Out! Example 1a Prove each trigonometric identity. sin θcot θ = cos θ Choose the left-hand side to modify. cos θ Ratio identity. cos θ = cos θ Simplify.

  11. Check It Out! Example 1b Prove each trigonometric identity. Choose the left-hand side to modify. 1 – sec(–θ) = 1 – secθ Reciprocal identity. Negative-angle identity. Reciprocal Identity.

  12. Helpful Hint If you get stuck, try converting all of the trigonometric functions to sine and cosine functions. You can use the fundamental trigonometric identities to simplify expressions.

  13. Example 2A: Using Trigonometric Identities to Rewrite Trigonometric Expressions Rewrite each expression in terms of cos θ, and simplify. sec θ(1 – sin2θ) Substitute. Multiply. Simplify. cos θ

  14. Example 2B: Using Trigonometric Identities to Rewrite Trigonometric Expressions Rewrite each expression in terms of sin θ, cos θ, and simplify. sinθcosθ(tanθ + cotθ) Substitute. Multiply. sin2θ + cos2θ Simplify. 1 Pythagorean identity.

  15. Check It Out! Example 2a Rewrite each expression in terms of sin θ, and simplify. Pythagorean identity. Factor the difference of two squares. Simplify.

  16. Check It Out! Example 2b Rewrite each expression in terms of sin θ, and simplify. cot2θ csc2θ– 1 Pythagorean identity. Substitute. Simplify.

  17. Example 3: Physics Application At what angle will a wooden block on a concrete incline start to move if the coefficient of friction is 0.62? Set the expression for the weight component equal to the expression for the force of friction. mg sinθ = μmg cosθ Divide both sides by mg. sinθ = μcosθ Substitute 0.62 for μ. sinθ = 0.62 cosθ

  18. Example 3 Continued Divide both sides by cos θ. Ratio identity. tanθ = 0.62 Evaluate inverse tangent. θ = 32° The wooden block will start to move when the concrete incline is raised to an angle of about 32°.

  19. Check It Out! Example 3 Use the equation mg sinθ = μmg cosθto determine the angle at which a waxed wood block on a wood incline with μ = 0.4 begins to slide. Set the expression for the weight component equal to the expression for the force of friction. mg sinθ = μmg cosθ Divide both sides by mg. sinθ = μcosθ Substitute 0.4 for μ. sinθ = 0.4 cosθ

  20. Check It Out! Example 3 Continued Divide both sides by cos θ. Ratio identity. tanθ = 0.4 Evaluate inverse tangent. θ = 22° The wooden block will start to move when the concrete incline is raised to an angle of about 22°.

  21. Lesson Quiz: Part I Prove each trigonometric identity. 1. sinθ secθ = 2. sec2θ = 1 + sin2θ sec2θ = 1 + tan2θ = sec2θ

  22. Lesson Quiz: Part II Rewrite each expression in terms of cos θ, and simplify. 3. sin2θcot2θ secθ cosθ 4. 2 cosθ

More Related