Law of Sines Your Guilds have earned a “Day Of Rest”. Note from the Gamemaster: Your Guilds have earned a “Day Of Rest”. Today’s Lesson will be Dragon Free.

What You Should Learn Use the Law of Sines to solve oblique triangles (AAS or ASA). Use the Law of Sines to solve oblique triangles (SSA). Find the areas of oblique triangles. Use the Law of Sines to model and solve real-life problems.

Plan for the day When to use law of sines and law of cosines Applying the law of sines Law of sines - Ambiguous Case

Introduction In this section, we will solve oblique triangles – triangles that have no right angles. As standard notation, the angles of a triangle are labeled A, B, and C, and their opposite sides are labeled a, b, and c. To solve an oblique triangle, we need to know the measure of at least one side and any two other measures of the triangle—either two sides, two angles, or one angle and one side.

Introduction This breaks down into the following four cases: Two angles and any side (AAS or ASA) Two sides and an angle opposite one of them (SSA) Three sides (SSS) Two sides and their included angle (SAS) The first two cases can be solved using the Law of Sines, whereas the last two cases require the Law of Cosines.

Introduction The Law of Sines can also be written in the reciprocal form: .

Given Two Angles and One Side – AAS For the triangle below C = 102, B = 29, and b = 28 feet. Find the remaining angle and sides.

Example AAS - Solution The third angle of the triangle is A = 180 – B – C = 180 – 29 – 102 = 49. By the Law of Sines, you have .

Example AAS – Solution cont’d Using b = 28 produces and

Law of Sines For non right triangles Law of sines Try this: A B C c a

Let’s look at this: Example 1 Given a triangle, demonstrate using the Law of Sines that it is a valid triangle (numbers are rounded to the nearest tenth so they may be up to a tenth off): a = 5 A = 40o b = 7 B = 64.1o c = 7.5 C = 75.9o Is it valid??

And this: Example 2 Given a triangle, demonstrate using the Law of Sines that it is a valid triangle (numbers are rounded to the nearest tenth so they may be up to a tenth off): a = 5 A = 40o b = 7 B = 115.9o c = 3.2 C = 24.1o Is it valid?? Why does this work?

Looking at these two examples a = 5 A = 40o b = 7 B = 64.1o c = 7.5 C = 75.9o b = 7 B = 115.9o c = 3.2 C = 24.1o In both cases a, b and A are the same (two sides and an angle) but they produced two different triangles Why??

Here is what happened a = 5 A = 40o b = 7 B = c = C = What is sin 64.1? What is sin 115.9? What is the relationship between these two angles? Remember the sine of an angle in the first quadrant (acute: 0o – 90o) and second quadrant, (obtuse: 90o – 180o)are the same!

The Ambiguous Case (SSA)

The Ambiguous Case (SSA) In our first example we saw that two angles and one side determine a unique triangle. However, if two sides and one opposite angle are given, three possible situations can occur: (1) no such triangle exists, (2) one such triangle exists, or (3) two distinct triangles may satisfy the conditions.

Back to these examples Given two sides and an angle across a = 5 A = 40o b = 7 B = 64.1o c = 7.5 C = 75.9o b = 7 B = 115.9o c = 3.2 C = 24.1o The Ambiguous Case

The Ambiguous Case (SSA)

Ambiguous Case Is it Law or Sines or Law of Cosines Law of Cosines – solve based upon one solution Law of Sines – go to #2 Law of Sines - Is it the SSA case? (Two sides and angle opposite) No – not ambiguous, solve based upon one solution Yes – go to #3. Is the side opposite the angle the shortest side? Yes – go to #4 Is the angle obtuse? No – go to #5 Yes – no solution Calculate the height of the triangle height = the side not opposite the angle x the sine of the angle If the side opposite the angle is shorter than the height – no solution If the side opposite the angle is equal to the height – one solution If the side opposite the angle is longer than the height – two solutions

How many solutions are there? A = 30o a = 5 b = 3 B = 50o a = 6 b = 5 C = 80o b = 5 c = 6 A = 40o a = 4 b = 8 a = 5 b = 4 c = 6 B = 20o a = 10 c = 15 A = 25o a = 3 b = 6 C = 75o a = 5 b = 3 1 2 1 1 1 2 1

Example – Single-Solution Case—SSA For the triangle below, a = 22 inches, b = 12 inches, and A = 42. Find the remaining side and angles. One solution: a  b

Example – Solution SSA By the Law of Sines, you have Reciprocal form Multiply each side by b. Substitute for A, a, and b. B is acute.

Example – Solution SSA Now, you can determine that cont’d Now, you can determine that C  180 – 42 – 21.41 = 116.59. Then, the remaining side is

What about more than one solution?

How many solutions are there? A = 30o a = 5 b = 3 B = 50o a = 6 b = 5 C = 80o b = 5 c = 6 A = 40o a = 4 b = 8 a = 5 b = 4 c = 6 B = 20o a = 10 c = 15 A = 25o a = 3 b = 6 C = 75o a = 5 b = 3 1 2 Solve #2, 7

Law of Cosines

What You Should Learn Use the Law of Cosines to solve oblique triangles (SSS or SAS). Use the Law of Cosines to model and solve real-life problems.

Introduction Four cases. Two angles and any side (AAS or ASA) Two sides and an angle opposite one of them (SSA) Three sides (SSS) Two sides and their included angle (SAS) The first two cases can be solved using the Law of Sines, whereas the last two cases require the Law of Cosines.

Law of Cosines: Introduction Two cases remain in the list of conditions needed to solve an oblique triangle – SSS and SAS. If you are given three sides (SSS), or two sides and their included angle (SAS), none of the ratios in the Law of Sines would be complete. In such cases, you can use the Law of Cosines.

Law of Cosines Side, Angle, Side A B C c a b

Try these B = 20o a = 10 c = 15 A = 25o b = 3 c = 6 C = 75o a = 5 b = 3

Law of Cosines Side, Side, Side A B C c a b

Law of Cosines Law of Cosines SSS Always solve for the angle across from the longest side first!

Why It is wise to find the largest angle when you have SSS. Knowing the cosine of an angle, you can determine whether the angle is acute or obtuse. That is, cos  > 0 for 0 <  < 90 cos  < 0 for 90 <  < 180. This avoids the ambiguous case! Acute Obtuse

Try these a = 5 b = 4 c = 6 a = 20 b = 10 c = 28 a = 8 b = 5 c = 12

Applications

An Application of the Law of Cosines The pitcher’s mound on a women’s softball field is 43 feet from home plate and the distance between the bases is 60 feet (The pitcher’s mound is not halfway between home plate and second base.) How far is the pitcher’s mound from first base?

Solution In triangle HPF, H = 45 (line HP bisects the right angle at H), f = 43, and p = 60. Using the Law of Cosines for this SAS case, you have h2 = f 2 + p2 – 2fp cos H = 432 + 602 – 2(43)(60) cos 45  1800.3. So, the approximate distance from the pitcher’s mound to first base is  42.43 feet.