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Part of HELM Book 1.1
", "licence": "Creative Commons Attribution-NonCommercial 4.0 International"}, "statement": "If the letters \\(x\\) and \\(y\\) represent two numbers, then their sum is written as \\(x+y\\) . Note that \\(x+y\\) is the same as \\(y+x\\) just as \\(4+7\\) is equal to \\(7+4\\) .
\n\nSubtracting \\(y\\) from \\(x\\) yields \\(x-y\\) . Note that \\(x-y\\) is not the same as \\(y-x\\) just as \\(11-7\\) is not the same as \\(7-11\\) , however in both cases the difference is said to be \\(4\\).
\n\nThe instruction to multiply \\(x\\) and \\(y\\) together is written as \\(x\\times y\\) . Usually the multiplication sign is omitted and we write simply \\(xy\\) . An alternative notation is to use a dot to represent multiplication and so we could write \\(x\\cdot y\\) The quantity \\(xy\\) is called the product of \\(x\\) and \\(y\\) . As discussed earlier multiplication is both commutative and associative:
\n\n\\[\\text{i.e.}\\quad x\\times y=y\\times x\\quad\\text{and}\\quad (x\\times y)\\times z=x\\times (y\\times z)\\]
\n\nThis last expression can thus be written \\(x\\times y\\times z\\) without ambiguity. When mixing numbers and symbols it is usual to write the numbers first. Thus \\(3\\times x\\times y\\times 4=3\\times 4\\times x\\times y=12xy\\) .
\n\nSimplify
\n\\(2\\times x\\times 2\\times y=2\\times 2\\times x\\times y=12xy\\)
\nWhat is the distinction between \\(9(-2y)\\) and \\(9-2y\\) ?
\n\nThe expression \\(9(-2y)\\) means \\(9\\times (-2y)\\) . Because of associativity of multiplication we can write this as \\(9\\times (-2)\\times y\\) which equals \\(18y\\) .
\n\nOn the other hand \\(9-2y\\) means subtract \\(2y\\) from \\(9\\). This cannot be simplified.
\n\nThe quantity \\(x\\div y\\) means \\(x\\) divided by \\(y\\) . This is also written as \\(x/y\\) or \\(\\frac{x}{y}\\) and is known as the quotient of \\(x\\) and \\(y\\) . In the expression \\(\\frac{x}{y}\\) the symbol \\(x\\) is called the numerator and the symbol \\(y\\) is called the denominator . Note that \\(x/y\\) is not the same as \\(y/x\\) . Division by \\(1\\) leaves a quantity unchanged so that \\(\\frac{x}{1}\\) is simply \\(x\\) .
\n\nA quantity made up of symbols and the operations \\(+, -, \\times\\) and \\(/\\) is called an algebraic expression . One algebraic expression divided by another is called an algebraic fraction. Thus
\n\n\\[\\frac{x+7}{x-3}\\quad\\text{and}\\quad\\frac{3x-y}{2x+z}\\]
\n\nare algebraic fractions. The reciprocal of an algebraic fraction is found by inverting it. Thus the reciprocal of \\(\\frac{2}{x}\\) is \\(\\frac{x}{2}\\) . The reciprocal of \\(\\frac{x+7}{x-3}\\) is \\(\\frac{x-3}{x+7}\\) .
\n\nState the reciprocal of each of the following expressions:
\n\nFinding the reciprocal of complicated expressions can cause confusion. Study the following Example carefully.
\n\nObtain the reciprocal of:
\n\nThe equals sign, \\(=\\) , is used in several different ways.
\n\nFirstly, an equals sign is used in equations . The left-hand side and right-hand side of an equation are equal only when the variable involved takes specific values known as solutions of the equation. For example, in the equation \\(x-8=0\\) , the variable is \\(x\\) . The left-hand side and right-hand side are only equal when \\(x\\) has the value \\(8\\). If \\(x\\) has any other value the two sides are not equal.
\n\nSecondly, the equals sign is used in formulae . Physical quantities are often related through a formula. For example, the formula for the length, \\(C\\) , of the circumference of a circle expresses the relationship between the circumference of the circle and its radius, \\(r\\) . This formula states \\(C=2\\pi r\\) . When used in this way the equals sign expresses the fact that the quantity on the left is found by evaluating the expression on the right.
\n\nThirdly, an equals sign is used in identities . An identity looks just like an equation, but it is true for all values of the variable. We shall see shortly that \\((x-1)(x+1)=x^2-1\\) for any value of \\(x\\) whatsoever. This mean that the quantity on the left means exactly the same as that on the right whatever the value of \\(x\\) . To distinguish this usage from other uses of the equals symbol it is more correct to write \\((x-1)(x+1)\\equiv x^2-1\\) , where \\(\\equiv\\) means ‘is identically equal to’. However, in practice, the equals sign is often used. We will only use \\(\\equiv\\) where it is particularly important to do so.
\n\nThe sign \\(\\ne\\) means ‘is not equal to’. For example, \\(5\\ne 6\\) , \\(7\\ne -7\\) .
\n\nThe change in the value of a quantity is found by subtracting its initial value from its final value. For example, if the temperature of a mixture is initially \\(13^\\circ\\) C and at a later time is found to be \\(17^\\circ\\) C, the change in temperature is \\(17-13=4^\\circ\\) C. The Greek letter \\(\\delta\\) is often used to indicate such a change. If \\(x\\) is a variable we write \\(\\delta x\\) to stand for a change in the value of \\(x\\) . We sometimes refer to \\(\\delta x\\) as an increment in \\(x\\) . For example if the value of \\(x\\) changes from \\(3\\) to \\(3.01\\) we could write \\(\\delta x=3.01-3=0.001\\) . It is important to note that this is not the product of \\(\\delta\\) and \\(x\\) , rather the whole symbol ‘ \\(\\delta x\\) ’ means ‘the increment in \\(x\\).
\n\nThis provides a concise and convenient way of writing long sums.
\n\nThe sum
\n\n\\[x_1+x_2+x_3+x_4+\\dots +x_11+x_12\\]
\nis written using the capital Greek letter sigma, \\(\\Sigma\\) , as
\n\n\\[\\sum_{k=1}^{12}x_k\\]
\n\nThe symbol \\(\\Sigma\\) stands for the sum of all the values of \\(x_k\\) as \\(k\\) ranges from \\(1\\) to \\(12\\). Note that the lower-most and upper-most values of \\(k\\) are written at the bottom and top of the sigma sign respectively.
\n\nWrite out explicitly what is meant by \\(\\sum_{k=1}^5k^3\\)
\n\nWe must let \\(k\\) range from \\(1\\) to \\(5\\). \\(\\sum_{k=1}^5k^3=1^3+2^3+3^3+4^3+5^3\\)
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