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1 Ratio, Proportion, & Variation Chapter 18. 2 Sect 18.1 : Ratio and Proportion A ratio conveys the notion of “relative magnitude”. Ratios are used to.

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Presentation on theme: "1 Ratio, Proportion, & Variation Chapter 18. 2 Sect 18.1 : Ratio and Proportion A ratio conveys the notion of “relative magnitude”. Ratios are used to."— Presentation transcript:

1 1 Ratio, Proportion, & Variation Chapter 18

2 2 Sect 18.1 : Ratio and Proportion A ratio conveys the notion of “relative magnitude”. Ratios are used to compare two quantities. Remember the set of rational numbers?

3 3 A ratio can be used to compare quantities of the same kind (can be expressed using the same units). Example 1: The TI-84 calculator display screen is 94 pixels by 62 pixels. Write this as a ratio in simplest form.

4 4 Example 2: Write as the ratio of whole numbers in simplest form.

5 5 Example 3: Write the ratios in simplest form. a) The ratio of 75 s to 3 min b) The ratio of 2.7 kg to 60.5 g

6 6 A ratio can be used to compare denominate numbers with different units. These ratios are also called rates. Example 5 lb of fertilizer covers 1200 square feet. How many square feet are covered per pound of fertilizer?

7 7 An equation stating that two ratios are equal is called a ________________________. The product of the ______________ equals the product of the ________________.

8 8 Example 2: To conserve energy and still allow for as much natural lighting as possible, an architect suggest that the ratio of the area of a window to the area of the total wall surface to be 5 to 12. Using this ratio, determine the recommended area of a window to be installed in a wall that measures 8 ft by 12 ft.

9 9 Examples from the book: P. 494 # 26, 40, 44

10 10

11 11 Section 18.2: Variation To estimate the number of phone calls expected per day between two cities, one telecommunication company used the following formula which shows that the daily number of phone calls, C, increases as the populations of the cities, P 1 and P 2, in thousands, increase and decreases as the distance, d, between the cities increases.

12 12 Variation Variation formulas show how one quantity changes in relation to other quantities. Quantities can vary directly, inversely, or jointly.

13 13 Direct Variation When you swim underwater, the pressure in your ears depends on the depth at which you are swimming. The formula describes the water pressure, p, in pounds per square inch, at a depth of d feet. a)Find the water pressure in your ears at a depth of 10 ft. b)Find the water pressure in your ears at a depth of 20 ft. c)Find the water pressure in your ears at a depth of 40 ft.

14 14 Direct Variation In this example, the water pressure is a constant multiple of your underwater depth. If your depth is doubled, the pressure is doubled; if the depth is tripled, the pressure is tripled; etc. The pressure in your ears is said to vary directly as your underwater depth.

15 15 Direct Variation When two quantities are in the same proportion and can be expressed as an equation in the form y = k x, we say that y varies directly as x or y is directly proportional to x. The (non-zero) number k is called the constant of proportionality.

16 16 Direct Variation Example The number of gallons of water, W, used when taking a shower varies directly as the time, t, in minutes, in the shower. A shower lasting 5 minutes uses 30 gallons of water. How much water is used in a shower lasting 11 minutes?

17 17 Direct Variation Direct variation can involve variables to higher powers. We say that y is directly proportional to the nth power of x.

18 18 Direct Variation Example The distance, s, that a body falls from rest varies directly as the square of the time, t, of the fall. If skydivers fall 64 feet in 2 seconds, how far will they fall in 4.5 seconds?

19 19 Inverse Variation When two quantities are related by an equation in the form we say that y varies inversely as x or y is inversely proportional to x. The (non-zero) number k is called the constant of variation.

20 20 Inverse Variation For example, for a fixed distance, the time it takes to travel that distance is inversely proportional to the rate at which one drives. The distance from Plattsburgh to Albany is 150 miles.

21 21 Inverse Variation Example At a constant temperature, the pressure, P, of a gas container varies inversely with the volume, V, of the container. The pressure of a gas sample in a container whose volume is 8 cubic inches is 12 pounds per square inch. If the sample expands to a volume of 22 cubic inches, what is the new pressure of the gas?

22 22 In combined variation, direct and inverse variation occur at the same time. Example One’s intelligence quotient, or IQ, varies directly as a person’s mental age and inversely as that person’s chronological age. A person with a mental age of 25 and a chronological age of 20 has and IQ of 125. What is the chronological age of a person with a mental age of 40 and an IQ of 80? Combined Variation

23 23 Joint Variation Joint variation is a variation in which a variable varies directly as the product of two or more other variables. To show that y varies jointly as x and z, we would write

24 24 Joint Variation Newton’s famous formula for gravitation shows this: The force, F, between two bodies varies jointly as the product of their masses, m 1 and m 2, and inversely as the square of the distance between them, d 2. (G is the gravitational constant.)

25 25 Joint Variation Example The volume of a cone, V, varies jointly as its height, h, and the square of its radius, r. A cone with a radius measuring 6 feet and a height measuring 10 feet has a volume of 120  cubic feet. Find the volume of a cone having radius of 12 feet and a height of 2 feet.

26 26 Joint Variation Example The centrifugal force, C, of a body moving in a circle varies jointly with the radius of the circular path, r, and the body’s mass, m, and inversely with the square of the time, t, it takes to move about one full circle. A 6-gram body moving in a circle with radius 100 cm at a rate of 1 rev in 2 seconds has a centrifugal force of 6000 dynes. Find the centrifugal force of an 18-gram body moving in a circle with radius 100 cm at a rate of 1 revolution in 3 seconds.

27 27 End of Section


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