How to calculate a square root http://www.youtube.com/watch?v=3i94NWF39nU Pre-listening 1) How can you find out what a square root of a number is without a calculator? 2) Which numbers are "perfect squares"? Listening. Listen to and watch the video and decide whether the statements are true or false. 1) Approximation technique will produce a number which is not accurate. 2) The method proposed by the professor is exact decimal by decimal. 3) He learned it in 1968 when he was at a university. 4) There were no calculators at that time, so he had to ask the teacher about the square roots. 5) We start with number 1, which is a perfect square. 6) 2 is not possible because it is not a perfect square. 7) We put a random number in the blank space. 8) 7 is the smallest digit we can use. 9) The important step is to double the underlined digit. 10) When the last digit is 0, we must subtract another place. 11) He can't present the explanation why it works because it is extremely difficult. 12) Square roots of integers that are not perfect squares are called irrational. 13) They have two important features: decimals go on forever and there is a certain pattern of repetition. 14) They go on forever because you never get a zero remainder. * 15) Cube roots cannot be solved in a similar way. 1. Look nod read: Exact calculations and approximations Some square roots may be calculated exactly e-g- 74 = 2 76-25 = 25 71444 = 3-8 Other square roots may be calculated only approximately e.g. 72=1-414213...... 73= 1-7320508...... 75 = 2-236068...... These approximate square roots are called irrational numbers i.e. we can continue the numbers after the decimal point as long as we wish. Look ai the following and say whether they can be calculated exactly or only approximately: a) 79 c) 712-25 c) The area of a circle g) 7TT6^5 b) 713 d) k f) Any irrational number h) 723-5 2. Read this: Approximations to square roots To find 77: First, we guess a value for 7?. say 2\. 7/2± = 2-8. Thus 2£ is too small. So we try a value half-way between 2\ and 2-8 i.e. 2-65. 7/2-65 = 2-64. Thus 2-65 is slightly too large. So we try (2-65 + 2-64)/2 = 2-645. 7/2-645 = 2-646. 77 may be calculated to an arbitrary degree of accuracy i.e. we can calculate- it to any required degree of accuracy, but 2-645 is a reasonably good approximation. Now write similar paragraphs using the following examples: a) 711; first guess 3i b) 73*= first guess 5± 3. Read this: • 4 exceeds 77 by a considerable amount. • 2-65 exceeds 77 by a very small amount. -*6 4. Look and read: 0 x*+2x-35 = 0 d) e> .. rational number......% - x is divisible by both 7 and 9 and x< 100 0 - ■ . ■ > 5. Look and read; rem > t " " /is ...:> We are given the length of one side of a regular hexagon. This is sufficient for the area to be calculated - 1 * ......■;' nan We are given the length of one side of a triangle. This is insufficient for the area to be calculated. cv^* *7 s same way: Given Required a) one side of a square area b) one side of a rectangle area c) the altitude of a cone volume d) the area of one face of a regular dodecahedron surface area e) the ie>h of ihe non-paralld sides of a trapezium area f) Ihe surface area of a sphere. volume g) the area of the lateral Taces of a prism volume h) a chord of a circle area Fig. 7.2 • IuFigure 7.1 A = X, B = Y, C = Z (i.e. the angles are equal). This is a necessary condition for the two triangles to be congruent, but it is not a sufficient condition, i.e. the two triangles may be congruent, but we have insufficient information. • In Figure 7.2 A = X AB = XY, AC = XZ (i.e. two sides and the included angle are equal). This is a sufficient condition for the triangles to be congruent, i.e. the triangles are congruent. Now write about the following pairs of triangles in the same way: A/v X/v A Fig. 7.3 Fifl. 7.5 Section 3 Reading 7. Read this: The solution of triangles A triangle has three sides and three angles. When three of these elements are known and at least one of the elements is a side, the otheT three elements can be calculated. Only one trigonometrical ratio, sine, is required in the calculation. In a triangle ABC, we are given the lengths of AB and AC and the value of ABC. We use this formula: „. A 180°. No such triangle can exist. • a = b =* c = 3cm, Only one such triangle can exist. Write similar sentences about the following cases: bfiA j. a b) ^A^i c> bs^A= 1 Section 4 Listening Approximate nines .... 9. Listen to the passage mad write down in figures each number you bear. 10. Listen to tbe passage again and say whether the following statements are true or false. Correct the false statements, a) 3-1416 is an approximate value of *. b) The difference between two approximate values is known as the absolute error. c) The absolute error is the same as the true error. d) The relative error is the true value divided by the absolute error. e) The percentage error is found by multiplying the absolute value by 100. f) The true value of 3-76, which is accurate to three significant figures, may be anywhere between 3-7 and 3-8. 11. Look at this example: 3-76 is an approximate value of 3*757 accurate to three significant figures. Now make similar sentences about the following: 11 Solve these problems: Find a) the absolute error, b) the relative error and c) the percentage error in exercise 11c). 13. puzzle: How many different digits are needed to give the value of: a) 1/3 b) (1/3)* c) (1/3)* to ten significant figures? Unit7 Approximate values The value or* may be calculated to any required degree or accuracy. Correct to four decimal places, its value is 3-1416. This value is said to be correct to five significant figures. 1 f the population of a city is 346 268, then we may say that the population is approximately 350000. This approximation is said to be correct to two significant figures. In this last case the approximate value exceeds the true value by 3 732. This difference is known as the absolute error or the true error. Another important value is relative error. We can use the formula absolute error. c . , , . true value e relat,ve error-In 'his case, we have S = 0-0108. Note that the calculation of the relative error, 00108, is accurate to three significant figures. If w* mtijrip^^^pproximate value by another, the Dumber of significant figures in the product is generally less than in the multiplier and multiplicand. For example, the product of 3-76, accurate to 3 significant figures and 2012, accurate to four significant figures, is 7-56512, which is only accurate to two significant figures, 7-6, as the true answer may be anywhere between 7-553 and 7-577. a) 3-1416; s b) 0108; 0-1077 c) 3500:3498