Assumed knowledge
Motivation Scale drawings are used when we increase or reduce the size of an object so that it fits nicely on a page or computer screen. For example, we would want to reduce the size when drawing:
and we would want to increase the size when drawing:
The proportional increase or decrease in lengths is called the scale of the drawing. It is usually expressed in terms of a ratio, so the topic of scale drawings is closely related to ratios and fractions. The transformation that produces a scale drawing is an enlargement. An enlargement transformation preserves the shape of the figure, but increases or decreases all distances by a constant ratio. This is different from the three transformations that we have already introduced − translations, rotations and reflections all produce an image that is the same size and shape as the original figure. The module, Congruence studied congruent figures, which are figures that can be mapped one to the other by a sequence of translations, rotations and reflections. Figures that can be mapped one to the other by these transformations and enlargements are called similar. Thus two figures are similar if an enlargement of one is congruent to the other. Any two figures that have the same shape are similar. Matching angles in similar figures are equal, but matching lengths in two similar figures are all in the same ratio. This constant ratio is the same ratio that appears in scale drawings and enlargements. The theory of similarity develops in the same way as congruence. First, most situations involving similarity can be reduced to similar triangles, and we shall establish four similarity tests for triangles, corresponding to the four congruence tests for triangles. Secondly, just as congruence was used to prove many basic theorems about triangles and special quadrilaterals, so similarity will allow us to establish further important theorems in geometry. The treatment of similarity and enlargements in this module has been guided by well-established classroom practice. Scale drawings and enlargements are usually discussed a year or so earlier than similarity, and these topics therefore receive a self-contained treatment in Sections 1−2. Section 3 can then introduce similarity in terms of enlargement transformations. In Section 4−6, the discussion of similar triangles begins with the AAA similarity test, which is usually considered the most straightforward test to use. CONTENT Scale drawings A scale drawing has exactly the same shape as the original object, but usually has a different size. This means that:
Scale = length on the drawing : length on the actual object The scale of a drawing is thus given as the ratio of two numbers. For example, in the photograph below, showing the side of a train engine, Scale = 1 : 200. This means that a length of 1 cm on the photograph above corresponds to a length of 200 cm , or 2 metres, on the actual engine. The scale can also be written as the ratio of two lengths, Scale = 1 cm : 2 m This second notation, using the ratio of two lengths with different units, is often more convenient for maps, where, for example, a scale of 1 cm : 100 km is easier to interpret than 1 : 10 000 000.
Example a Measure the overall length of the engine in the photograph above, including the couplings. Then use the scale to find the approximate length of the actual engine.b Find the approximate width and height of the doors, and the area of each door. Solution a Engine length in photograph = 11 cm
b Width of door in photograph = 0.35 cm
Height of door in photograph = 1.1 cm
Example
Solution
When the scale is written as a ratio of two numbers, the ratio is normally cancelled down to simplest form.
SCALE DRAWINGS:
EXERCISE 1 The photograph below shows the facade of the neo-Gothic St Petrus and Paulus Church in Ostend, Belgium. Assume that the person dressed in a black suit in the bottom right-hand corner of the photograph is 2 metres tall. a What is the approximate scale of the photograph? b What is the approximate height of the top of each spire from the ground? Scales involving very large and very small distances − Scientific notation Science routinely uses scale drawings and photographs of astronomical and microscopic objects. When the scale of such drawings is expressed in terms of pure numbers, the numbers are so large, or so small, that scientific notation becomes appropriate.
EXAMPLE a A distant galaxy with diameter 100 000 light years appears on a photograph as an image with diameter 3 cm. Given that a light year is very roughly 1013 km, express this scale as the ratio of two numbers.b A molecule with diameter 10 Angstrom units across appears on an electron microscope photograph as an image with diameter 5 cm. Given that 1 Angstromunit is 10-10 metres, express this scale as the ratio of two numbers. Solution a 3 cm : 105 light years = 3 cm : 105 × 1013 × 105 cm = 3 : 1023.b 5 cm : 10 Angstrom units = 5 cm : 10 × 10-10 × 100 cm = 5 : 10-7 = 5 × 107 : 1. The best form for the answer to this question is 1 : 2 × 10-8 or 5 × 107 : 1. Enlargements We have already dealt with three transformations of the plane − translations, rotations and reflections. These three transformations are examples of congruence transformations, because the image of a figure under one of these transformations is congruent to the original. Indeed, we defined two figures to be congruent if one could be mapped to the other by a sequence of these transformations. This section introduces a fourth type of transformation of the plane called an enlargement, in which all lengths are increased or decreased in the same ratio. To specify an enlargement, we need to specify two things:
In this module, we will only deal with positive enlargement factors. For example, the diagram below shows a point O and a triangle ABC. The next figure below shows how to construct the image
We can use this diagram to verify three important properties of enlargements. First, it is easy to verify with compasses that each side of the image triangle A′B′C′ is twice the length of the matching sides of the original triangle ABC. That is,
Secondly, we can verify that each angle of Thirdly, since the corresponding angles are equal, each side of the image triangle is parallel to the matching side of the original triangle: A′B′ || AB, B′C′ || BC and C′A′ || CA. It follows from the first and second points above that the image Enlargements are reversible. In our examples above, An enlargement can have any positive real number as its enlargement factor. The definition and the properties of enlargements are summarised in the box below. ENLARGEMENT TRANSFORMATIONS:
PROPERTIES OF AN ENLARGEMENT:
The following exercise is intended to present two further examples of enlargements, and to confirm that in these two cases, each distance is increased by the enlargement factor.
EXERCISE 2 ii Confirm that: -B′C′ = 3 × BC and D′C′ = 3 × DC, and -the images ii Confirm that: -each interval of the image has half the length of the original interval, and -each angle of the image is equal to the original angle. Similarity Two plane figures are called similar if an enlargement of one figure is congruent to the other. That is, if one can be mapped to the other by a sequence of translations, rotations, reflections and enlargements. Similar figures thus have the same shape, but not necessarily the same size. Thus a scale drawing of a two-dimensional object, and an enlargement of a plane figure, bith produce figures similar to the original. It follows from the properties of enlargements discussed in the previous section that when two figures are similar:
Conversely, if two figures can be matched up so that these two conditions apply, we can enlarge the first figure by the constant ratio. The enlarged figure is thus congruent to the second figure, so the first and second figures are similar. The constant ratio is called the similarity ratio or similarity factor. If two figures are similar with similarity ratio 1 : 1, then the two figures are congruent, otherwise they will have different sizes. The two maps above are similar to each other. Each distance on the second map is twice the matching distance on the first map, so we say that the similarity ratio is 1 : 2, or that the similarity factor is 2. In the language of the first section, each map is a scale drawing of Australia (ignoring the curvature of the Earth), and each map is a scale drawing of the other map. We can continue to solve problems in similarity using the unitary method approach adopted with scale drawings, but it is more usual to use algebra and fractions, as in the following example. As with congruence, vertices must be kept in matching order.
Example The two parallelograms below are known to be similar. a What is the size of b Find the base DC of the large parallelogram. c Find the similarity ratio of: i PQRS to ABCD, ii ABCD to PQRS. Solution
Both methods of writing the algebra of part b are equally good.
One should use whichever method seems more natural at the time − this will often depend on the particular problem. The subsequent algebra will be easier, however, if one always starts by placing the unknown length on the top of the left-hand side. It is worthwhile writing down the algebra that proves that the two identities are equivalent:
The middle identity says that two products of lengths are equal. In later work, particularly with circle geometry, this middle identity will be a common way of expressing the consequences of similarity. Some may prefer to find the length DC by continuing with the arithmetic approach used in scale drawings. Such an approach is not recommended, because it is unsuitable when similarity is applied to more general situations where the similarity ratio is not readily apparent. Comparing the sides QR and BC, the similarity ratio is 1 : 2.5.
Exercise 3 Is each statement true or false? If it is false, can you qualify the statement to make it true? a Any two squares are similar. b Any two rectangles are similar. c Any two rhombuses are similar. d Any two circles are similar. e Any two sectors of circles are similar. f Any two equilateral triangles are similar. g Any two isosceles triangles are similar. Four similarity tests for triangles Two figures are congruent when they are similar with similarity factor 1. Similarity is thus a generalisation of congruence, and we would expect the theory of similarity to proceed along similar lines to the theory of congruence that we have already developed. As with congruence, discussions involving the similarity of straight-sided figures can be reduced to discussions of similar triangles. Triangles have three vertex angles and three side lengths. If the vertices of two triangles can be matched up so that matching angles are equal and matching sides are in a constant ratio, then the two triangles are similar. This can be demonstrated with the two triangles above, where matching angles are equal and matching sides are in the ratio 1 : k. We can enlarge As with congruent triangles, however, we do not need to check all six measurements to be sure that the two triangles are similar. There are four standard tests for two triangles to be similar, corresponding to the four standard congruence tests. We can develop each similarity test from the corresponding congruence test. First, the AAS congruence test corresponds to the AAA similarity test, which states:
If two triangles have two pairs of equal angles, then their third pair is also equal because the angle sum of a triangle is 180°. Thus two such triangles are called equi-angular, and the test is often referred to as the AAA similarity test. To prove this test, let
Then Hence This same argument can be applied to develop a similarity test from each of the other three congruence tests. From the SAS congruence test we obtain the SAS similarity test:
From the SSS congruence test we obtain the SSS similarity test:
From the RHS congruence test we obtain the RHS similarity test:
Exercise 4 Develop the SSS similarity test from the SSS congruence test. Use the same argument as was used above to develop the AAA similarity test from the AAS congruence test. Refer to the triangles ABC and PQR that illustrate the statement of the SSS similarity test above. Using the AAA similarity test Similarity problems are set out in much the same way as congruence problems. The following example shows how to use the AAA similarity test to find lengths. There are two ways of writing the ratio condition on the sides, as discussed in the previous section, and the first example has been solved both ways.
Example a Show that b Hence find: i BQ, ii BM. Solution a In the triangles AMP and BMQ:
so b i Hence
ii Also
EXAMPLE a In each diagram below, complete the similarity statement ‘ABC is similar to…’, stating the similarity test used. b Hence find the length of AC in each case. Solution a nABC is similar to b We apply matching sides of similar triangles in both diagrams.
Using the SAS similarity test The first example below displays both ways of writing the ratio condition on the sides, first in the proof of similarity in part a, then in the subsequence calculation of a side length. Part c shows how the equality of two angles can be used to prove that two lines are parallel.
Example a Prove that b Find the length of CD. c Prove that AB || DC. Solution
The second method in parts a and b above compares lengths within each triangle. Using the SSS similarity test The following example shows how to use the SSS similarity test to prove that angles are equal.
Example a Prove that the two triangles in the diagram are similar. b Which of the marked angles are equal? Solution
AB = 2 × CB (given) BC = 2 × BD (given) CA = 2 × DC (given) so b Hence g = θ (matching angles of similar triangles). Using the RHS similarity test As with congruence, the SAS similarity test requires that the pair of equal angles be included between the pairs of sides that are in ratio. When the equal angles are right angles, however, we can use the RHS similarity test, in which the pair of equal angles are not included between the pairs of sides that are in ratio.
Example
b Identify the equal angles in the two triangles. c Prove that AB || PQ. Solution a In the triangles ABM and QPM:
so bHence θ = β and f = α(matching angles of similar triangles). cHence AB || PQ(alternate angles are equal). We indicated above how the RHS similarity test can be developed from the RHS congruence test. It is also possible to use Pythagoras’ theorem to develop the RHS congruence test from the SSS congruence test. The following exercise gives the details.
Exercise 5 In the two right-angled triangles in the diagram,
a Show that PR = k bHence show that The similarity tests as generalisations of the congruence tests Two figures are congruent when they are similar with similarity ratio 1 : 1. The four congruence tests can be regarded as special cases of the four similarity tests when the similarity ratio is 1 : 1. For example, the SSS similarity test specifies that the matching sides of the two triangles are in a constant ratio, and the SSS congruence test specifies that the matching sides have equal length, that is, that the constant ratio is 1 : 1. Similarly, the SAS and RHS similarity tests each specify that the ratios of the two pairs of matching sides are equal, and the SAS and RHS congruence tests each specify that the two pairs of matching sides have equal length, that is, that the constant ratio is 1 : 1. The AAS congruence test requires that matching angles are equal, and that one pair of matching sides are equal. This is generalised by the AA congruence test, which only specifies that matching angles are equal − the ratio of any pair of matching sides is then the similarity ratio of the pair. Similarity and intercept theorems A point F on an interval AB divides the interval A point on a side of a triangle divides that side into two intercepts. Several important theorems about intercepts on the sides of triangles can be proven quickly using similarity. The intercept theorem − A special case involving midpoints We shall deal first with the special case involving the midpoints of two sides. Theorem The interval joining the midpoints of two sides of a triangle is parallel to the third side and half its length. Proof Let F and G be the midpoints of the sides AB and AC of
so
This dissection also demonstrates that each small triangle has one quarter the area of the large triangle. The special case can also be proven using congruence alone, as in the following exercise, although the construction is a little more elaborate.
Exercise 6 of AB and AC. Construct the line through C parallel to BA, aProve that AFG × CMG. b Prove that FG || BC. cProve that FG = The midpoints of the sides of a quadrilateral is half the area of the original quadrilateral. This theorem is proven in the following exercise.
Exercise 7 In the diagram to the right, the points P, Q, R and S are the midpoints of the sides AB, BC, CD and DA respectively of a quadrilateral ABCD. a Show that PS || QR, and that PS = QR. b Show that PQ || SR, and that PQ = SR. c Show that area ASP = dShow that area PQRS = e What conclusion can you draw about the diagonals of ABCD if: i PQRS is a rectangle? ii PQRS is a rhombus? The intercept theorem − The general case case − the points F and G can divide the sides AB and AC in any given ratio. Theorem Let the points F and G divide the sides AB and AC of a triangle ABC in the same ratio 1 : k. Then FG || BC and Proof
The converse of the intercept theorem for triangles − The intercept theorem has an important converse. Again we shall deal first with the special case where F is the midpoint of the side AB. Theorem The interval from the midpoint of one side of a triangle parallel to a second side is half the length of the second side and bisects the third side. Proof In the triangles AFG and ABC: so AFG is similar to ABC (AAA similarity test). Hence, using matching sides of similar triangles,
As before, this special case of the theorem does not actually require similarity.
Exercise 8 b Prove that BE = FG = EC and that AG = FE = GC. The converse of the intercept theorem − The general case This special case can be generalised to apply to any line parallel to a side of a triangle. Theorem Let the line through F parallel to BC meet AC at G. Then
Proof
The ratio of areas of similar triangles We saw above that when two triangles are similar with similarity factor 2, then their areas are in the ratio 1 : 4. This is a special case of a more general result. Theorem then their areas are in the ratio 1 : k2. Proof
Further applications of similarity This section contains some further applications of similarity in geometry. The altitude to the hypotenuse of a right-angled triangle The altitude to the hypotenuse of a right-angled triangle divides the triangle into two triangles each similar to the original triangle. Several interesting results follow from this observation. The exercise below uses the construction to provide another proof of Pythagoras’ theorem, and then to prove these two further results: Theorem Let the altitude to the hypotenuse of a right-angled triangle divide the hypotenuse into two intercepts. a The square of the altitude equals the product of the intercepts.b The ratio of the squares of the other two sides equal the ratio of the intercepts.
Exercise 9
cUse a similar method to prove that b2 = y2 + xy. dHence prove Pythagoras’ theorem by showing that a2 + b2 = (x + y)2. eUse the identities of parts b and c to prove that fUse the similarity of the two smaller triangles to prove that h2 = xy. An enlargement construction a : b, where a and b are the lengths of two given intervals OF and OG on a common ray OFG. The following exercise shows how this can done.
Exercise 10 Join FP, then construct the line through G parallel to FP. Let this line meet OP, produced if necessary, at P′. Use similarity to prove that OP : OP′ = a : b. The intercept theorem for three parallel lines Theorem When two transversals cross three parallel lines, the intercepts cut of one transversal are in the same ratio as the intercepts cut off the other transversal. This means that in the diagram to the right,
Exercise 11 aProve the result when AC || PR.
Extension − The centroid of a triangle of the triangle. Moreover, the centroid trisects each median, or more precisely, divides it in the ratio 2 : 1. Theorem The medians AP, BQ and CR of a triangle ABC are concurrent at a point G called the centroid. The centroid trisects each median, in the sense that AG : GP = BG : GQ = CG : GR = 2 : 1. Extension − The golden mean and the diagonals of the regular pentagon The five angles at the centre of a regular pentagon are each 360° ÷ 5 = 72°, so each interior angle of the pentagon is 54° + 54° = 108°. When we draw a diagonal, it forms an isosceles triangle with base angles 36° and 36°. Thus at each vertex, the two diagonal trisect the vertex angle into three angles, each 36°. Let ABCDE be a regular pentagon with side length 1, and join the diagonals AC, AD and BD. Let AC meet BD at M, and let CM = x. Then by isosceles triangles, the lengths are as shown.
Exercise 13 a Find the angles ofb Hence show that c By solving the quadratic equation, show that x = d Show that each diagonal has length e The number f =
Use the calculator to find an approximation for correct to three decimal places. Then verify this identity on your calculator. Links Forward Similarity in circle geometry Similarity is a useful tool in circle geometry, where equal angles turn up in what seem at first surprising positions. It is also more natural in circle geometry to express the theorems in terms of products of lengths than ratios of lengths. One example is worth giving in detail to illustrate the usefulness of similarity. Theorem the products of the intercepts are equal. Proof Let AB and PQ be chords intersecting at M. Join AP and BQ. In the triangles APM and QBM: 1 2 so Hence so AM × BM = PM × QM. Similarity is also useful in the study of the other conic sections − parabolas, Similarity in trigonometry The most important use of similarity in Years 9−10 mathematics, however, is in trigonometry, where similarity is required in the definitions of the trigonometric ratios. For example, we define sin 40° = in a right-angled triangle with an angle of 40°. Such a definition requires the AAA similarity test to ensure that in any two such triangles, the ratio of the two sides is the same, no matter what the size of the triangle: Because similarity is built into trigonometry, many geometric proofs using similarity also have an alternative trigonometric proof, where trigonometry can function as a sort of ‘automated similarity’, transferring ratios around the diagram. For example, here is an alternative proof of the intersecting chord theorem above. It uses trigonometry, in particular the sine rule, to transfer the ratio of the lengths. Proof
Similarity of other conic sections We have already noted that any two circles are similar. The definition of the other conic sections in terms of focus and directrix and eccentricity means that
To prove this, apply an enlargement to one conic so that the distance from focus to directrix is the same in its enlargement and in the other conic. The enlarged conic is then congruent to the other conic. More generally,
Enlargements and other transformations Suppose that a figure in the coordinate plane is defined by an equation, and that an enlargement with centre the origin and similarity factor k is applied to the figure. The equation of the transformed figure can be found by replacing x by
that is, x2 + y2 = 25. There are many other important transformations in mathematics besides the four introduced so far. The study of functions uses dilations or stretchings, which enlarge a figure in one direction only, so that a circle becomes an ellipse. For example, when we stretch the unit circle x2 + y2 = 1 by a factor of 5 in the x-direction only, we replace x by
or equivalently, x2 + 25y2 = 25. Another interesting transformation is a shear. For example, if we move every point In these last two situations, the resulting ellipse and parallelogram no longer have the same shape as the original figures. Nevertheless, they share important properties of the original − the diagonals of the parallelogram, for example, still bisect each other, and many theorems about tangents to circles have analogies in ellipses. A great deal of geometry investigates properties of figures that are preserved under various sets of transformations of them. History and applications Scale drawings One can scarcely imagine a more useful piece of geometry than scale drawings. The notes in this module carefully talked about scale drawings of ‘the side of a train engine’ and ‘the facade of a cathedral’, so that all scale drawings were scale drawings of two-dimensional objects. The normal situation in architecture or engineering or biology, however, is scale drawings of three-dimensional objects. This can be done in various ways. In architecture, the most obvious way to draw a plan for a building is to project the building onto a plane such as the ground, or onto a side wall. More complicated drawings project the build onto a slant plane, making it easier for the viewer to imagine a three-dimensional picture of the building. Such projections are extremely useful for drawing up building plans, but they do not mimic the view of someone looking at the building. Whenever we see parallel lines with our eyes, they appear to meet at a point way off in the distance, and these considerations lead to the projective projections of buildings. Projective projections were made famous by painters in the Renaissance, but they are now used routinely in the computer programmes used by architects, who can invite viewers to take a virtual walk through a proposed building with the projection constantly changing as they go. Projective transformations also allow the various conic sections − circles, ellipses, parabolas and hyperbolas − to be transformed into each other. Maps of anything larger than a small city need to take account of the curvature of the Earth when they represent the landscape on a two-dimensional map. A typical atlas will use various projections for different purposes, because each projection has its characteristic advantages and disadvantages. Similarity Similarity is an essential part of Greek geometry, and was used to great effect. An important theorem about cyclic quadrilaterals proven by the Egyptian mathematician Ptolemy (cAD90 − cAD 168) theorem shows how similarity can be used to prove surprising results about lengths and products of lengths. Its proof is given below in a structured exercise that is suitable as extension material. Ptolemy’s theorem: The product of the diagonals of a cyclic quadrilateral equals the sum of the products of opposite sides.
Exercise 14 with sides AB = a, BC = b, CD = c and DA = d, with diagonals AC = s and BD = t. Construct K on AC with and bShow that cShow that dHence show that st = ac + bd. The converse of this theorem is also true, ‘If the product of the diagonals of a quadrilateral equals the sum of the products of opposite sides, then the quadrilateral is cyclic.’ Because the Greeks had no coherent theory of irrational numbers, there is always an uneasy relationship between similarity and the rest of Greek geometry. For example, one can construct with straight edge and compasses enlargements whose enlargement factor is any given rational number or square root of a rational number, but it is now known that one cannot construct an enlargement with enlargement factor 32 (the proof of this is not straightforward). This is the basis of one the three most famous unsolved problems passed on to the modern world by Greek mathematicians, ‘Given a cube, construct another cube of twice the volume.’ The problems of the relationships between the arithmetic of the real numbers and the geometry of the plane were only sorted out in the late 19th century. Appendix The study of similarity is quite a challenge to students. The discussion in this module, using enlargement transformations to introduce similarity, was chosen because it makes good sense to students, and because it is well established in schools. It would be unwise to make the topic more complicated by introducing logical difficulties. Nevertheless, the preceding discussion has logical problems that some students begin asking questions about. For example:
This appendix gives one of several possible approaches to dealing with these issues. The first section, which essentially proves the AAA similarity test for positive rational values of k, may be suitable as Extension material for some students. A. Equi-angular triangles in which two matching sidesk: 1 Let us then begin the whole discussion again, with neither similarity nor enlargements defined. The first step is a theorem which essentially shows that the AAA similarity test holds when the similarity ratio k is a positive rational number. Because similarity has not yet been defined, the theorem is expressed not in terms of similarity, but as a test for the sides being in ratio. Theorem Let ABC and PQR be equi-angular triangles, with Let BC = α, CA = β and AB = c, and let QR = ka, where k is a positive rational number. Then RP = kb and PQ = kc. Proof Let F be the midpoint of QR. Then QF = FR = a. Construct G on RP and H on QP so that FG || QP and FH || RP. Omitting the details of the angle-chasing, Using opposite sides of parallelograms and matching sides of congruent triangles, Omitting the details of the angle-chasing, RFG is similar to FQH (AAA similarity test with ratio 1 : 2). Using opposite sides of parallelograms and matching sides of congruent triangles, HP = FG = Thirdly, to prove the result for all whole numbers k, each successive step uses the previous step and adapts the same argument. For example, the argument for k = 4 uses exactly the same argument as used for k = 3, except that the length FQ is now 3a. Eventually the result can be proven for any whole number k. This method of successive argument for one whole number after the other will be formalised in Years 11−12 as mathematical induction. Lastly, we have now outlined congruence proofs of the result for k = 2, 3, 4…. The test is therefore also proven for the reciprocal similarity factors k = B. A new axiom Since every irrational number is ‘as close as we like’ to a rational number, it is reasonable to take as a new axiom of our geometry that the previous result holds for all positive real numbers.
Using this axiom, we can now establish the other three tests in a form that still avoids the word ‘similarity’.
Here is a proof of the SAS test as stated above. In the two triangles below, AB : PQ = AC : PR = 1 : k and so that AB′ = kc. Let the line through B′ parallel to BC meet AC, produced if necessary, at C′.
Hence ABC and PQR are equi-angular, so using the new axiom introduced above,
The other two tests can be proven with exactly analogous constructions. C. Enlargements The definition of enlargement given in this module is not really satisfactory as a geometric definition. It was based on constructing an interval that is k times a given interval, where k is any positive real number − such a construction cannot be done in general. What we need is a definition of enlargement that is based not on a given real number k, but on the ratio of two given lengths. Such a construction was the subject of Exercise 10, and we now redefine enlargement to be the result of this construction. This new definition of enlargement, together with the new axiom, will enable us to prove the properties of enlargements that could only be established by demonstration in the module. The enlargement transformation: Suppose that we are given a centre of enlargement O, and two intervals OF and OG of lengths a and b, lying on the same ray from O. Define the enlargement with centre O and ratio a : b to be the transformation whose image of a point P in the plane is the point P′ as in the diagram to the right. That is, P′ is the intersection of OP, produced if necessary, with the line through G parallel to FP. Using corresponding angles on parallel lines, the triangles OFP and OGP′ are equi-angular, so by the new axiom introduced in part B, it follows that OP : OP′ = a : b. The three properties of enlargements can now be proven. Theorem When an enlargement with centre O and ratio OF : OG = a : b is applied. aAB : A′B′ = a : b, for each interval AB in the plane. bAB || A′B′, for each interval AB in the plane. c Proof awe have shown above that OA : OA′ = OB : OB′ = a : b. Hence using the SAS situation discussed in part B above, applied to OAB and OA′B′, AB : A′B′ = a : b. b Also so AB || A′B′. c we know from part b that AB || A′B′ and BC || B′C′.Hence using corresponding angles, D. Similarity We can now define similarity exactly as before.
The theorem of part C now shows that two figures are similar when the points of one can be paired up with the points of the other so that matching angles are equal and matching sides are in the same ratio. Answers to Exercises Exercise 1
Exercise 3
Exercise 4 factor so that A′B′ = PQ = kc. Then B′C′ = ka and C′A′ = kb because the ratios of sides is preserved by enlargements. Hence Exercise 5 aUsing Pythagoras’ theorem in each triangle,
Exercise 6
Exercise 7
Exercise 8
Exercise 9
Exercise 10 In the triangles OFP and OGP′:
Exercise 11
Note: The working in part c assumed that the transversals meet outside the three parallel lines on the same side as A. There are, of course, three other cases to consider. What other cases should be considered in part b? Exercise 12 a i RQ || BC and RQ =ii In the triangles BCM and QRM: so BC = 2 × RQ iii Hence using matching sides of similar triangles, MQ : MB = MR : MC = QR : BC = 1 : 2. b We have now proven that any two medians of a triangle intersect in point that divides each median in the ratio 2 : 1. Let G be the point that divides the median AP in the ratio 2 : 1. Then the other two medians BQ and CR pass through G, and G also divides these medians in the ratio 2 : 1. Exercise 13 a Each triangle is isosceles with apex angle 72° and base angles 36°. b
c Hence x2 + x − 1 = 0 x = Since x is positive, x =
e Substituting = x + 1 into the second line of part b gives φ − 1 = From the calculator, φ ≈ 1:628, and Exercise 14 a Use angles on the same arc, and adjacent angles at a point. b so AK × t = ac. c so CK × t = bd. d Adding the results of parts b and c,
The Improving Mathematics Education in Schools (TIMES) Project 2009-2011 was funded by the Australian Government Department of Education, Employment and Workplace Relations. The views expressed here are those of the author and do not necessarily represent the views of the Australian Government Department of Education, Employment and Workplace Relations. © The University of Melbourne on behalf of the International Centre of Excellence for Education in Mathematics (ICE-EM), the education division of the Australian Mathematical Sciences Institute (AMSI), 2010 (except where otherwise indicated). This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivs 3.0 Unported License. |