HSC Mathematics Advanced, Extension 1, and Extension 2/2Unit/Preliminary/Basic arithmetic and algebra
The start of the 2unit mathematics course is really just revision of year 10 work.
Operations on fractions and decimals
editConverting between fractions, decimals and percentages
editConverting recurring decimals to fractions
editSo, you're in an exam and the test paper gives you a recurring decimal, say 2.35555..., and asks you to convert it into a fraction. Well, that's easy, it's just 2.3 plus 5 9ths divided by 10. simple enough. But then you get another question asking you to convert 5.676767... into a fraction. What fraction makes the repeating 0.676767...? Ahh, now you're stuck.
That's what would have happened if you hadn't learnt how to convert recurring decimals into fractions algebraically before sitting for your exam. What use does converting recurring decimals into fractions have? Can't calculators convert between decimal and fraction easily? Yes they can. This topic is probably most useful in getting you to think like a mathematician, applying maths (in this case algebra) to problems. There isn't much more use for this, other than providing an endless source of questions to test your basic algebra.
So let's start off with our recurring decimal number 5.676767... We are going to assign that value to x, so 'x = 5.676767.... Now we have something to work with. To convert it into a fraction, we need to get rid of all those annoying decimal places. To get rid of them we are going to need to multiply x by 100 to give us 100x = 567.676767..., and then we can subtract x, or 5.676767..., from that.
And there you go. This is the method of removing the first period
When looking at problems with recurring decimals, you need to see how many numbers are in the repeating part. In this example, the start of the repeating part was 0.67, and there were 2 numbers in each repeat. Because there were two numbers in the repeating part being repeated, we had to move the number 2 places to the left, by multiplying the number by 100, or 10^{2}. If you have a number with a nonrepeating part a and the start of the repeating part r, and a repeating length, or period, P, then we can write a general list of equations for converting the recurring decimal number into a fraction.
where the dotted r is the repeating part of the equation that we are going to get rid of.
where 10^{P}r is the start of the repeating part, shifted P places to the left.
Now we subtract one equation from the other to get rid of the repeating part by making it subtract from itself, leaving just the first period of the repeating part which we shifted left P places.
Factorize both sides
make x the subject
If the nonrepeating number a had a decimal part, like in the number 2.35555..., where a was 2.3, then the numerator would be a decimal (but not a recurring decimal) and you would have to multiply the numerator and denominator by a power of ten to make both numbers integers, and then you would have to simplify it. Calculators make this easy with their fraction buttons which can convert divisions into their simplest fractions. You could make an even more general formula if you let D, for decimal, equal the amount of decimal places that the nonrepeating part has. Then you can just multiply the numerator and denominator in your final answer by 10^{D}.
It is really more important that you remember the basic method and idea behind it, cancelling out the repeating part by subtracting it from itself. This formula is just for fun.
An interesting thing here is that the numerator will be equal to the nonrepeating number with its decimal place removed with the repeating part of the number on the end, minus the nonrepeating number with its decimal place removed without the repeating part on the end. So for 2.3555..., a = 2.3, r = 0.05, P = 1, D = 1. This makes the numerator (10×2.3  2.3 + 0.5)×10, so 235  23. 235 is a with no decimals and with r on the end, and then you are just subtracting a without decimals from that. Another thing to notice is that for every recurring number in the recurring part of the decimal, there will be a 9 in the denominator. 10^{P}  1 is a 1 followed by zeros when P is greater than 1. So when you take one away, all you are left with is nines. 100  1 = 99, 1000  1 = 999, etc. Also, for every decimal place in the nonrepeating part, there will be a zero on the end of the denominator, caused by the multiplication of 10^{D}.
This is where the general algorithm of subtracting the nonrepeating plus start of repeating as an integer from the nonrepeating as integer to get the numerator, and then adding nines for every repeating decimal number and zeros for every nonrepeating decimal number comes from.
Powers and roots
editScientific notation and approximation
editsignificant figures
Rules:
1. All nonzero digits are significant. 2. In a number without a decimal point, only zeros BETWEEN nonzero digits are significant. 3. In a number with a decimal point, all zeros to the right of the first nonzero digit are significant.
For example: 1. 1500 has two significant figures because the two zeros after 15 do not count. If the question asks to round to 1 significant figure then the answer is 2000.
2. 1050 has three significant figures since the 0 between 1 and 5 counts. If the question asks to round to 2 significant figures then the answer is 1100.
3. 0.001500 has four significant figures because the 3 zeros on the left hand side of the 1 do not count. However, the 2 zeros on the right hand side of 5 DO count, thus there are four significant figures. If the question asks to round to 1 significant figure then the answer is 0.002.
Evaluation of expressions involving all this stuff
editIf The N+1 Number Of S.f More Than 5 We Add 1+ To N Number , If It Is Less Than 5 nothing is change
Surds
editA surd is any irrational expression, i.e. it cannot be expressed rationally (as a fraction of two integers). Common examples include √2 and . These numbers have no known patterns in their digits, and so cannot be expressed as the fraction of two integers, they can only be expressed as a decimal with the decimal places continuing on forever. Because of this, surds can only ever be evaluated as approximations to a number of decimal places. The word 'surd' actually comes from the Arabic surdus which means root. The Arab mathematicians saw numbers like plants, growing out of their roots.
Like and Unlike surds
editBasically, two surds are like if they have the same number under the radical, which is called the radicand. For example, and are like surds. Unlike surds do not have the same radicand, and hence, for example, and are unlike.
Simplifying surds
editSome surds can be simplified as a product of a rational number and a surd. For example,
can be simplified to
This happens when the number within the surd is expressed as a product of two numbers, one of them being a perfect square:
Using the law of surds, this surd can be expressed as a product of two different, separate surds:
We can then evaluate as :
This method of simplification can also be applied to roots of any power.
Addition and subtraction of surds
editMultiplication of surds
editDivision of surds
editOne surd (root) divided by another surd (root) is equal to the root of the fraction of the two radicands.
Distributive law and surds
editRationalizing the denominator
editThe correct form of writing a fraction requires that the denominator be rational, and hence, not a surd. To rationalise the denominator, we multiply both numerator and denominator by the denominator, resulting in a rational denominator.
Inequalities and absolute values
editInequations
editInequations are mathematical statements that don't use the equals sign to express relationships between the two sides of the statement, but instead use signs such as greater than, greater than or equal to, less than, and less than or equal to.
greater than  
greater than or equal to  
less than  
less than or equal to 
While equations give exact values for pronumerals, such as x = 2, where x is exactly 2, inequations give a range of values which the pronumeral can have, such as x > 2, where x can posses any value greater than 2.
Just like when dealing with equations, adding or subtracting an amount to both sides doesn't change the inequation. If y + 2 > 1 then by subtracting 2 from both sides y > 1.
When multiplying or dividing both sides by positive number it also works the same as an equation, for example if then by dividing both sides by 8 you get .
When multiplying or dividing both sides of an inequation by a negative number the sign reverses. for example if you have and you divide both sides by 2, the less than or equal sign changes to a greater than or equal sign as . This is because if one number is greater than another number , i.e. , then on a number line is further away from 0 in the positive direction (right) than . But if you multiply the two numbers by 1, they both move to the left of the number line. Both numbers are still the same distance from 0, but because they are on the negative side of 0 is now more negative than , and so . This applies to any two numbers, positive or negative.
Absolute Values
editWhat are absolute values? Lets say you have a number x, and you put it on a number line. The value of x is the value that it has on the number line, lets say 3. The absolute value of x, expressed in mathematics as is the distance of x from 0. Because distance cannot be negative, is always greater than or equal to 0. This means that if x = 3 then would be 3, because the distance of 3 from 0 is 3. So if x is greater than or equal to 0, will just be its normal value x. But if x is less than 0, then will be its negative value (the negative of a negative number), and so will be positive. This can be expressed as
where x is the absolute value of x.
Algebraic manipulation
editSimplification
editRemoving grouping symbols and collecting like terms...
Substitution
editEvaluating expressions using giving values and formulas. Usually requires you to make something the subject first.
Factorization
editdistributive law?
Common factor
editDifference of two squares
editx^{2}  y^{2}. This can be factorized. Can you guess how? It's probably a good idea to add some maths in here instead of just giving you the formula, so lets look at the geometrical interpretation of this. Both pronumerals are squared. The terms squared and cubed come from the formula for area of a square and volume of a cube. The area of a square is equal to the length of one side multiplied by the length of another, and because the sides of a square are all equal, the area is the length of one side multiplied by itself, so it is raised to the power of 2, or squared =).
So if you have one squared number subtracted from another squared number, you could interpret this as one area of a square being subtracted from another area of another square. One square has side length x, while the other square has side length y. Does it matter which square is larger? Not really, if the area being subtracted is larger, you will end up with a negative area, and even though area, like distance, cannot be negative, we are not talking about real area, and x^{2}  y^{2} is allowed to be negative because it is an algebraic expression. If you don't like that, then think of it this way x^{2}  y^{2} = (y^{2}  x^{2}), so if y is larger than x, then just subtract the area of the x square from the area of the y square to get a positive area, then make that negative.
So, think about this in terms of a larger square with sides x having a smaller square with sides y subtracted from it. Subtracting a square from a square is going to leave a square shaped hole in the larger square, lets say in the corner. Now what used to be the larger square is going to have 6 edges. The two edges that were not cut will still have a length x. The other two sides of the original square are going to have a length of xy, and the two inner edges created by the hole are going to have a length y. From this we can calculate the remaining area. There are two rectangles, each with area (xy)×y, and one square with area (xy)(xy). If we expand and simplify these we get 2xy  2y^{2} + x^{2}  2xy + y^{2}, which can be written as y^{2} + 2xy + x^{2}  2xy, which factorizes to y(y+2x) + x(x2y), then y(x+y)  xy  x(xy) + xy, which can be further factorizes to (xy)(x+y) simplifies to x^{2}y^{2}. So
You could try the same thing with x^{2}+y^{2}, but it doesn't get you anything really useful, just a(ab) + b(a+b).
Another way to looks at this kind of factorisation problem, especially if there aren't any geometrical methods to factorize it, is to look for an expression that looks similar, but gives slightly different results, and then figure out what needs to be done in order to get from that expression to the first.e.g.
A third way to look at it is to add something to both sides.
probably went into too much detail on this. Awell.
Quadratic trinomials
editGrouping of terms to involve the other types of factorization
editThe sum and difference of two cubes
edit
Algebraic fractions
editReduction
editfactorizing numerator and denominator and canceling any common factors
Multiplication and division
editAddition and subtraction
editLCM
Linear equations
editSyllabus Point: 1.4 (i)
Linear inequalities
editSyllabus Point: 1.4 (ii)
if both sides of an inequality are multiplied by a negative number, the direction of the inequality is reversed.
Quadratic equations
editSyllabus Point: 1.4 (iii)
Factorisation
editExample:
OR
OR
Completing the square
editQuadratic formula
editSimultaneous equations
editSyllabus Point: 1.4 (iv)
Simultaneous equations are also referred to as systems of liner equations. The solution of simultaneous equations is any ordered pairs of the variables that can satisfy the constraints of the system.
Example:
In this example, the ordered pair (3,4) can satisfy all the equations, thus making it a solution of this system. When and , both equations( and ) are satisfied.
The content below represent the methods to solve simultaneous equations.
Substitution
editlinear, quadratic, circular, hyperbolic?
Elimination
editThe elimination method is sometimes also known as the linear combination method. This method attempts to add or subtract equations so that the equation set can be reduced to one simple linear equation.
Example:
From this stage, we can try to eliminate x and solve for y. (It is possible to eliminate y and solve for x.) Start by multiplying equation 1 by 3 to match the coefficient of x for equation 1 and equation 2.
Please note that when operating on one side of the equation, you must also operate the other side to keep the Left hand side equal to the Right hand side.
With the coefficient of X equal on both equations, it is now possible to eliminate x by subtracting equation 2 from equation 1.

=
=
From here we can solve this equation like a simple linear equation.
We can now substitute this back to either equation 1 or 2 to get the full answer.
∴ and