Transcript Week 1
Course Content: Quantitative Methods A 1. 2. 3. 4. 5. 6. 7. Introduction to mathematical thinking (today) Introduction to algebra Linear and quadratic equations Applications of equations Linear and quadratic functions Exponential functions and an introduction to logarithmic functions Solving equations involving logarithmic and exponential functions 1 Course Content (continued) 8. 9. 10. 11. 12. Compound interest Annuities Amortisation of loans Introduction to differentiation Applications of differentiation 2 Introduction to Mathematical Thinking On completion of this module you should be able to: • Understand real numbers, integers, rational and irrational numbers • Perform some mathematical operations with real numbers • Work with fractions • Understand exponents and radicals • Work with percentages • Use your calculator to perform some simple tasks 3 Numbers Integers • The counting numbers: 1, 2, 3, 4, … are positive integers. • The set of all integers is: …-3, -2, -1, 0, 1, 2, 3 • There are an infinite number of these. • Integers are useful for counting objects (eg people in a city, months a sum of money is invested, units of product needed to maximise profit etc). 4 Rational numbers • These can be written as a ratio of two integers. eg 1 , 8 2 5 8 Note that 5 and 1.6 are the same rational number. • p/q is a rational number where p and q are integers but q cannot be zero. 5 • Integers can be written as rational numbers: 5 5 , 1 9 9= 1 • Rational numbers with exact decimals: 1 0.5, 2 7 0.4375 16 6 Rational numbers with repeating decimals: 1 1 3 0.3333 , 9 0.1111 Can use a ‘dot’ to indicate the digits repeat: 0.3333 0.3 5 0.416666 0.416 12 5 11 0.454545 0.45 7 Irrational numbers • A number whose decimal equivalent repeats without any known pattern in the digits or which has no known terminating point is called an irrational number. • Examples are: 3.141592654 e 2.718281828 2 1.414213562 8 Real numbers • Real numbers are all the rational and irrational numbers combined. • This can be illustrated using a number line: – 3.5 –5 –4 –3 2 1.6 –2 –1 0 1 2 e 3 4 5 • Real numbers are used when we measure something (height, weight, width, time, distance etc) but also for interest rates, cost, revenue, price, profit, marginal cost, marginal revenue etc 9 Operations with real numbers Order of operations: remember BODMAS Brackets Of Multiplication Division Addition Subtraction Some examples: 4 2 3 4 6 2 3 4 2 3 2 6 4 2 5 2 2 5 2 7 2 14 10 Operations with real numbers Multiplication: 3 4 2 is equivalent to 3 4 2 Division: 42 4 2 3 or 4 2 3 is equivalent to 3 Expanding brackets: 3 4-2 =3 4 -3 2 =3×4-3×2 =12-6 = 6 or 3 4 2 3 2 6 11 Rules for multiplying and dividing negative numbers • If a negative numbers is multiplied or divided by a negative number, then the answer is positive. • If a negative numbers is multiplied or divided by a positive number, then the answer is negative. • If a positive numbers is multiplied or divided by a negative number, then the answer is negative. 12 Example 9 8 72 9 8 72 9 8 72 9 8 72 8 2 4 8 2 4 8 2 4 8 2 4 Remember: 0 anything = 0 0 anything = 0 BUT you can’t divide by zero (the result is undefined). 13 Rounding • When you have a nice round number, write 0.5 not 0.50000 and 0.4375 not 0.437500. • If rounding, the last required digit will round up one value if the next digit is five or greater, but will stay the same if the next digit is four or less. 14 Example 1. Round 0.1263 to three decimal places. 2. Round 4.15525 to two decimal places. Answer • Next digit (4th one) is 3, which is four or less, 3rd digit stays the same: 0.126. • Next digit (3rd one) is 5, which is five or more, the 2nd digit goes up by one: 4.16. 15 Rounding guidelines • Do what the questions asks… • If your answer is people, cats, ball bearings, pencils etc round to the nearest whole number. • If your answer is an intermediate step in working, don’t round at all!! • If your answer is money then round to 2 decimal places – never more!! eg $4.05. 16 Rounding guidelines (continued) • If your answer is an interest rate, keep at least two decimal places but four to five may be wise. • Use your common sense… Big numbers usually need fewer decimal places whereas small numbers need more. • So 1,056,900.3 is better than 1,056,900.27384034 but 0.013046 is better than 0.0! 17 Rounding guidelines (continued) • It would be wise to include the number of decimal places you’ve used with your answer: 1,056,900.3 (to 1 decimal place) 0.0130 (to 4 decimal places) 18 Fractions numerator fraction denominator 5 9 5 is called the numerator 9 is called the denominator 19 Equivalent fractions • 1 4 2 and 8 are equivalent fractions since 1 1 4 4 2 24 8 4 • Multiplying numerator and 1 4 denominator by the same number is equivalent to multiplying by 1. 20 • If we divide both numerator and denominator by the same factor (called cancelling) we get an equivalent fraction: 2 12 1 or 4 22 2 2 4 1 2 1 2 • If the numerator and denominator have no factors in common, the fraction is said to be in its lowest terms. 21 42 Simplify by cancelling. 168 • Start by dividing numerator and 21 42 denominator by 2: 42 168 168 84 7 21 21 • Divide by 3: 84 84 28 1 7 7 1 • Divide by 7: 4 28 28 4 22 • Try easy factors first (2, 3 etc). • Sometimes a common factor is obvious. • At other times, trial and error is necessary to cancel and simplify fractions successfully. • A proper fraction has numerator less than denominator. • An improper fraction has numerator greater than denominator. • A mixed number has an integer and a fraction. e.g. 2½ 23 Adding and subtracting fractions • To add or subtract fractions, they must be converted to equivalent fractions with the same denominator. 5 1 • For example 12 12 can be calculated immediately since both denominators are 12. 5 1 5 1 6 1 12 12 12 12 2 24 Adding and subtracting fractions When the denominators differ we can either: • multiply denominators together to find the common denominator or • find the lowest common denominator. We will look at an example of each. 25 Example 4 3 Find 5 4 Multiplying the denominators together gives: 4 3 4 4 3 5 5 4 5 4 45 16 15 31 20 20 20 20 11 11 11 1 1 20 20 20 20 26 Example 4 3 1 Find 5 4 8 Multiplying the denominators together gives 548=160, but the lowest common denominator is actually 40 since 4, 5 and 8 all divide evenly into 40. 4 3 1 4 8 3 10 1 5 5 4 8 40 40 40 32 30 5 67 27 1 40 40 40 27 Example 7 8 Find 13 14 7 8 7 14 8 13 13 14 13 14 98 104 6 182 182 3 91 28 Multiplying and dividing fractions • To multiply fractions, multiply numerators and denominators together. 8 2 4 2 4 2 4 3 5 3 5 3 5 15 • To divide fractions, multiply by the reciprocal. 2 4 2 5 10 5 3 5 3 4 12 6 29 Multiplying and dividing fractions • ‘of’ is equivalent to multiplication: 3 3 3 7 21 1 of 7 7 5 4 4 4 1 4 4 30 Exponents and Radicals • A number (called the base) raised to a positive whole number (the exponent) means multiply the base by itself the number of times given in the exponent. • So 34 means 3333=81. • Any number raised to the power of zero is equal to one: 0 3 1 0 8 1 2 5 8 6 0 1 31 Multiplying powers Rules for multiplying powers: 1. If you are multiplying bases with the same exponent, then multiply the bases and put them to this exponent. 2 2 2 2 2 5 2 5 10 2. If you are multiplying the same base with different exponents then add the exponents. 32 34 32 4 36 32 3. If you are raising a number to an exponent and then to another exponent, multiply the exponents. 3 2 5 325 310 33 Taking the root of a number (fractional powers) The square root of a number is the reverse of squaring. (2)2 4 4 2 2 (2) (4.5)2 20.25 20.25 4.5 2 (4.5) 34 Note: When taking the square root, the answer is usually taken to be a positive number, although, as can be seen in the examples on the previous slide, either a positive or negative number squared results in the same answer. 35 Roots with other bases: 3 8 means “what number multiplied together three times gives 8?” Since 2 2 2 =8, 3 8 2. 3 8 is read as “the cube root of 8” or “the third root of 8” 36 4 4 81 is read “the fourth root of 81” 81 3 since 3 3 3 3 = 81 Sometimes you may need to use a calculator: 6 805 3.049996 (to 6 decimal places) 37 Fractional powers Another way of writing roots is using fractional powers: 1 44 2 12 594 594 3 1 27 27 3 1 12 38 Negative exponents A negative power can be rewritten as one over the same number with a positive power: 2 3 1 1 2 9 3 1 5 2 32 5 2 4 6 1 1 6 4096 4 1 1 25 Note that 5 1 25 1 1 2 25 39 Examples of negative fractional exponents: 9 1 64 2 1 6 1 1 9 2 1 1 64 1 1 9 3 1 6 1 6 64 2 1 13 3 27 27 3 1 3 27 40 Percentages When we speak of 15% of a number, we mean 15 100 number or 0.15 number Example Calculate 47% of 3092. 47 47% 3092 3092 or 0.47 3092 100 47 3092 145324 100 100 1453.24 41 Example An account’s salary of $75 300 is going to be increased by 7%. What are the increase in salary and the new salary? 7 75300 100 1 7 75300 5271 100 7% 75300 So the increase in salary is $5271. The new salary is $75 300 + $5271 = $80 571. 42 Using the calculator You will require a scientific calculator for the remainder of the course. The keys which shall be required most frequently are: Mathematical functions add subtract - multiply divide change of sign squares x 2 43 Mathematical functions (continued) x or x1 2 powers x y y or x logs to base 10 square roots 1 roots x y log antilog to base 10 10 x logs to base e ln antilog to base e e x 44 The memory keys Clear memory Put into memory Add to the contents of memory Subtract from the contents of memory 45 IMPORTANT Activity 1-1: using your calculator (ask for help in tutorials if you need to). 46 Accuracy and rounding 9 13 9 (1.8571429) 262.7893802 7 9 13 9 (1.85) 253.8315230 7 error 8.9578572 when truncated to 2D 9 13 9 (1.86) 266.4504745 7 error 3.6610943 when rounded to 2D Rounding intermediate results leads to loss of accuracy in final result. 47