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11 x1 t11 09 locus problems (2012)

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Nigel Simmons
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Locus Problems
Locus Problems Eliminate the parameter (get rid of the p’s and q’s)
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point.
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding.
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters)
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value.
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3)
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3 b) Type 2: obvious relationship between the values, usually only one parameter.
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3 b) Type 2: obvious relationship between the values, usually only one parameter. e.g. 6t , t 2  1
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3 b) Type 2: obvious relationship between the values, usually only one parameter. e.g. 6t , t 2  1 x  6t x t 6
Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3 b) Type 2: obvious relationship between the values, usually only one parameter. e.g. 6t , t 2  1 x  6t y  t 2 1 x x2 t y  1 6 36
c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters.
c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p 2  q 2 , p  q  Given that pq = 3
c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2   p  q   2 pq 2 Given that pq = 3
c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2 x  y2  6   p  q   2 pq 2 Given that pq = 3
c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2 x  y2  6   p  q   2 pq 2 Given that pq = 3 2005 Extension 1 HSC Q4c) The points P2ap, ap 2  and Q2aq, aq 2  lie on the parabola x 2  4ay The equation of the normal to the parabola at P is x  py  2ap  ap 3 and the equation of the normal at Q is given by x  qy  2aq  aq 3
c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2 x  y2  6   p  q   2 pq 2 Given that pq = 3 2005 Extension 1 HSC Q4c) The points P2ap, ap 2  and Q2aq, aq 2  lie on the parabola x 2  4ay The equation of the normal to the parabola at P is x  py  2ap  ap 3 and the equation of the normal at Q is given by x  qy  2aq  aq 3 (i) Show that the normals at P and Q intersect at the point R whose coordinates are  apq p  q , a p 2  pq  q 2  2
c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2 x  y2  6   p  q   2 pq 2 Given that pq = 3 2005 Extension 1 HSC Q4c) The points P2ap, ap 2  and Q2aq, aq 2  lie on the parabola x 2  4ay The equation of the normal to the parabola at P is x  py  2ap  ap 3 and the equation of the normal at Q is given by x  qy  2aq  aq 3 (i) Show that the normals at P and Q intersect at the point R whose coordinates are  apq p  q , a p 2  pq  q 2  2 1 (ii) The equation of the chord PQ is y   p  q x  apq . If PQ passes through (0,a), show that pq = – 1 2
(iii) Find the locus of R if PQ passes through (0,a)
(iii) Find the locus of R if PQ passes through (0,a) x  apq p  q 
(iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a
(iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a y  a p 2  pq  q 2  2
(iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a y  a p 2  pq  q 2  2  y  a  p  q   pq  2 2 
(iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a y  a p 2  pq  q 2  2  y  a  p  q   pq  2 2   x2  y  a 2  1  2  a 
(iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a y  a p 2  pq  q 2  2  y  a  p  q   pq  2 2   x2  y  a 2  1  2  a  x2 y   3a a
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R.
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0   1 2ap  0 2aq  0
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0   1 2ap  0 2aq  0 ap 2 q 2  4a 2 pq
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0   1 2ap  0 2aq  0 ap 2 q 2  4a 2 pq pq  4
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0 y  apq   1 2ap  0 2aq  0 ap 2 q 2  4a 2 pq pq  4
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0 y  apq   1 2ap  0 2aq  0 y  4a ap 2 q 2  4a 2 pq pq  4
2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0 y  apq   1 Exercise 9J; odds 2ap  0 2aq  0 y  4a up to 23 ap 2 q 2  4a 2 pq pq  4

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Destaque

11X1 T08 04 chain rule
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11X1 T12 07 chord of contact (2011)
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11X1 T12 07 chord of contact (2011)Nigel Simmons
 
11 x1 t11 06 tangents & normals ii (2012)
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11 x1 t11 06 tangents & normals ii (2012)Nigel Simmons
 
12 X1 T04 07 approximations to roots (2010)
12 X1 T04 07 approximations to roots (2010)12 X1 T04 07 approximations to roots (2010)
12 X1 T04 07 approximations to roots (2010)Nigel Simmons
 
11 x1 t15 01 definitions (2013)
11 x1 t15 01 definitions (2013)11 x1 t15 01 definitions (2013)
11 x1 t15 01 definitions (2013)Nigel Simmons
 
11 x1 t13 04 converse theorems (2013)
11 x1 t13 04 converse theorems (2013)11 x1 t13 04 converse theorems (2013)
11 x1 t13 04 converse theorems (2013)Nigel Simmons
 
11 x1 t15 02 sketching polynomials (2013)
11 x1 t15 02 sketching polynomials (2013)11 x1 t15 02 sketching polynomials (2013)
11 x1 t15 02 sketching polynomials (2013)Nigel Simmons
 

Destaque (7)

11X1 T08 04 chain rule
11X1 T08 04 chain rule11X1 T08 04 chain rule
11X1 T08 04 chain rule
 
11X1 T12 07 chord of contact (2011)
11X1 T12 07 chord of contact (2011)11X1 T12 07 chord of contact (2011)
11X1 T12 07 chord of contact (2011)
 
11 x1 t11 06 tangents & normals ii (2012)
11 x1 t11 06 tangents & normals ii (2012)11 x1 t11 06 tangents & normals ii (2012)
11 x1 t11 06 tangents & normals ii (2012)
 
12 X1 T04 07 approximations to roots (2010)
12 X1 T04 07 approximations to roots (2010)12 X1 T04 07 approximations to roots (2010)
12 X1 T04 07 approximations to roots (2010)
 
11 x1 t15 01 definitions (2013)
11 x1 t15 01 definitions (2013)11 x1 t15 01 definitions (2013)
11 x1 t15 01 definitions (2013)
 
11 x1 t13 04 converse theorems (2013)
11 x1 t13 04 converse theorems (2013)11 x1 t13 04 converse theorems (2013)
11 x1 t13 04 converse theorems (2013)
 
11 x1 t15 02 sketching polynomials (2013)
11 x1 t15 02 sketching polynomials (2013)11 x1 t15 02 sketching polynomials (2013)
11 x1 t15 02 sketching polynomials (2013)
 

Semelhante a 11 x1 t11 09 locus problems (2012)

11 x1 t11 09 locus problems (2013)
11 x1 t11 09 locus problems (2013)11 x1 t11 09 locus problems (2013)
11 x1 t11 09 locus problems (2013)Nigel Simmons
 
11X1 T12 09 locus problems
11X1 T12 09 locus problems11X1 T12 09 locus problems
11X1 T12 09 locus problemsNigel Simmons
 
11X1 T011 07 chord of contact (2012)
11X1 T011 07 chord of contact (2012)11X1 T011 07 chord of contact (2012)
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11X1 T11 04 chords of a parabola (2010)
11X1 T11 04 chords of a parabola (2010)11X1 T11 04 chords of a parabola (2010)
11X1 T11 04 chords of a parabola (2010)Nigel Simmons
 
11 x1 t11 04 chords of a parabola (2012)
11 x1 t11 04 chords of a parabola (2012)11 x1 t11 04 chords of a parabola (2012)
11 x1 t11 04 chords of a parabola (2012)Nigel Simmons
 
11X1 T12 04 chords of a parabola
11X1 T12 04 chords of a parabola11X1 T12 04 chords of a parabola
11X1 T12 04 chords of a parabolaNigel Simmons
 
11 x1 t15 05 polynomial results (2013)
11 x1 t15 05 polynomial results (2013)11 x1 t15 05 polynomial results (2013)
11 x1 t15 05 polynomial results (2013)Nigel Simmons
 
11X1 T12 07 chord of contact
11X1 T12 07 chord of contact11X1 T12 07 chord of contact
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11 x1 t11 07 chord of contact (2013)
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Proceedings A Method For Finding Complete Observables In Classical Mechanics
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11 x1 t15 05 polynomial results (2012)
11 x1 t15 05 polynomial results (2012)11 x1 t15 05 polynomial results (2012)
11 x1 t15 05 polynomial results (2012)Nigel Simmons
 
11X1 T15 05 polynomial results (2011)
11X1 T15 05 polynomial results (2011)11X1 T15 05 polynomial results (2011)
11X1 T15 05 polynomial results (2011)Nigel Simmons
 
11X1 T13 05 polynomial results
11X1 T13 05 polynomial results11X1 T13 05 polynomial results
11X1 T13 05 polynomial resultsNigel Simmons
 
11X1 T16 05 polynomial results
11X1 T16 05 polynomial results11X1 T16 05 polynomial results
11X1 T16 05 polynomial resultsNigel Simmons
 
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Semelhante a 11 x1 t11 09 locus problems (2012) (20)

11 x1 t11 09 locus problems (2013)
11 x1 t11 09 locus problems (2013)11 x1 t11 09 locus problems (2013)
11 x1 t11 09 locus problems (2013)
 
11X1 T12 09 locus problems
11X1 T12 09 locus problems11X1 T12 09 locus problems
11X1 T12 09 locus problems
 
11X1 T011 07 chord of contact (2012)
11X1 T011 07 chord of contact (2012)11X1 T011 07 chord of contact (2012)
11X1 T011 07 chord of contact (2012)
 
11X1 T11 04 chords of a parabola (2010)
11X1 T11 04 chords of a parabola (2010)11X1 T11 04 chords of a parabola (2010)
11X1 T11 04 chords of a parabola (2010)
 
11 x1 t11 04 chords of a parabola (2012)
11 x1 t11 04 chords of a parabola (2012)11 x1 t11 04 chords of a parabola (2012)
11 x1 t11 04 chords of a parabola (2012)
 
11X1 T12 04 chords of a parabola
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11 x1 t15 05 polynomial results (2013)
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11 x1 t15 05 polynomial results (2013)
 
11X1 T12 07 chord of contact
11X1 T12 07 chord of contact11X1 T12 07 chord of contact
11X1 T12 07 chord of contact
 
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Proceedings A Method For Finding Complete Observables In Classical Mechanics
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11 x1 t15 05 polynomial results (2012)
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11 x1 t15 05 polynomial results (2012)
 
11X1 T15 05 polynomial results (2011)
11X1 T15 05 polynomial results (2011)11X1 T15 05 polynomial results (2011)
11X1 T15 05 polynomial results (2011)
 
11X1 T13 05 polynomial results
11X1 T13 05 polynomial results11X1 T13 05 polynomial results
11X1 T13 05 polynomial results
 
11X1 T16 05 polynomial results
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Mais de Nigel Simmons

Goodbye slideshare UPDATE
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Goodbye slideshare UPDATENigel Simmons
 
12 x1 t02 02 integrating exponentials (2014)
12 x1 t02 02 integrating exponentials (2014)12 x1 t02 02 integrating exponentials (2014)
12 x1 t02 02 integrating exponentials (2014)Nigel Simmons
 
11 x1 t01 03 factorising (2014)
11 x1 t01 03 factorising (2014)11 x1 t01 03 factorising (2014)
11 x1 t01 03 factorising (2014)Nigel Simmons
 
11 x1 t01 02 binomial products (2014)
11 x1 t01 02 binomial products (2014)11 x1 t01 02 binomial products (2014)
11 x1 t01 02 binomial products (2014)Nigel Simmons
 
12 x1 t02 01 differentiating exponentials (2014)
12 x1 t02 01 differentiating exponentials (2014)12 x1 t02 01 differentiating exponentials (2014)
12 x1 t02 01 differentiating exponentials (2014)Nigel Simmons
 
11 x1 t01 01 algebra & indices (2014)
11 x1 t01 01 algebra & indices (2014)11 x1 t01 01 algebra & indices (2014)
11 x1 t01 01 algebra & indices (2014)Nigel Simmons
 
12 x1 t01 03 integrating derivative on function (2013)
12 x1 t01 03 integrating derivative on function (2013)12 x1 t01 03 integrating derivative on function (2013)
12 x1 t01 03 integrating derivative on function (2013)Nigel Simmons
 
12 x1 t01 02 differentiating logs (2013)
12 x1 t01 02 differentiating logs (2013)12 x1 t01 02 differentiating logs (2013)
12 x1 t01 02 differentiating logs (2013)Nigel Simmons
 
12 x1 t01 01 log laws (2013)
12 x1 t01 01 log laws (2013)12 x1 t01 01 log laws (2013)
12 x1 t01 01 log laws (2013)Nigel Simmons
 
X2 t02 04 forming polynomials (2013)
X2 t02 04 forming polynomials (2013)X2 t02 04 forming polynomials (2013)
X2 t02 04 forming polynomials (2013)Nigel Simmons
 
X2 t02 03 roots & coefficients (2013)
X2 t02 03 roots & coefficients (2013)X2 t02 03 roots & coefficients (2013)
X2 t02 03 roots & coefficients (2013)Nigel Simmons
 
X2 t02 02 multiple roots (2013)
X2 t02 02 multiple roots (2013)X2 t02 02 multiple roots (2013)
X2 t02 02 multiple roots (2013)Nigel Simmons
 
X2 t02 01 factorising complex expressions (2013)
X2 t02 01 factorising complex expressions (2013)X2 t02 01 factorising complex expressions (2013)
X2 t02 01 factorising complex expressions (2013)Nigel Simmons
 
11 x1 t16 07 approximations (2013)
11 x1 t16 07 approximations (2013)11 x1 t16 07 approximations (2013)
11 x1 t16 07 approximations (2013)Nigel Simmons
 
11 x1 t16 06 derivative times function (2013)
11 x1 t16 06 derivative times function (2013)11 x1 t16 06 derivative times function (2013)
11 x1 t16 06 derivative times function (2013)Nigel Simmons
 
11 x1 t16 05 volumes (2013)
11 x1 t16 05 volumes (2013)11 x1 t16 05 volumes (2013)
11 x1 t16 05 volumes (2013)Nigel Simmons
 
11 x1 t16 04 areas (2013)
11 x1 t16 04 areas (2013)11 x1 t16 04 areas (2013)
11 x1 t16 04 areas (2013)Nigel Simmons
 
11 x1 t16 03 indefinite integral (2013)
11 x1 t16 03 indefinite integral (2013)11 x1 t16 03 indefinite integral (2013)
11 x1 t16 03 indefinite integral (2013)Nigel Simmons
 
11 x1 t16 02 definite integral (2013)
11 x1 t16 02 definite integral (2013)11 x1 t16 02 definite integral (2013)
11 x1 t16 02 definite integral (2013)Nigel Simmons
 

Mais de Nigel Simmons (20)

Goodbye slideshare UPDATE
Goodbye slideshare UPDATEGoodbye slideshare UPDATE
Goodbye slideshare UPDATE
 
Goodbye slideshare
Goodbye slideshareGoodbye slideshare
Goodbye slideshare
 
12 x1 t02 02 integrating exponentials (2014)
12 x1 t02 02 integrating exponentials (2014)12 x1 t02 02 integrating exponentials (2014)
12 x1 t02 02 integrating exponentials (2014)
 
11 x1 t01 03 factorising (2014)
11 x1 t01 03 factorising (2014)11 x1 t01 03 factorising (2014)
11 x1 t01 03 factorising (2014)
 
11 x1 t01 02 binomial products (2014)
11 x1 t01 02 binomial products (2014)11 x1 t01 02 binomial products (2014)
11 x1 t01 02 binomial products (2014)
 
12 x1 t02 01 differentiating exponentials (2014)
12 x1 t02 01 differentiating exponentials (2014)12 x1 t02 01 differentiating exponentials (2014)
12 x1 t02 01 differentiating exponentials (2014)
 
11 x1 t01 01 algebra & indices (2014)
11 x1 t01 01 algebra & indices (2014)11 x1 t01 01 algebra & indices (2014)
11 x1 t01 01 algebra & indices (2014)
 
12 x1 t01 03 integrating derivative on function (2013)
12 x1 t01 03 integrating derivative on function (2013)12 x1 t01 03 integrating derivative on function (2013)
12 x1 t01 03 integrating derivative on function (2013)
 
12 x1 t01 02 differentiating logs (2013)
12 x1 t01 02 differentiating logs (2013)12 x1 t01 02 differentiating logs (2013)
12 x1 t01 02 differentiating logs (2013)
 
12 x1 t01 01 log laws (2013)
12 x1 t01 01 log laws (2013)12 x1 t01 01 log laws (2013)
12 x1 t01 01 log laws (2013)
 
X2 t02 04 forming polynomials (2013)
X2 t02 04 forming polynomials (2013)X2 t02 04 forming polynomials (2013)
X2 t02 04 forming polynomials (2013)
 
X2 t02 03 roots & coefficients (2013)
X2 t02 03 roots & coefficients (2013)X2 t02 03 roots & coefficients (2013)
X2 t02 03 roots & coefficients (2013)
 
X2 t02 02 multiple roots (2013)
X2 t02 02 multiple roots (2013)X2 t02 02 multiple roots (2013)
X2 t02 02 multiple roots (2013)
 
X2 t02 01 factorising complex expressions (2013)
X2 t02 01 factorising complex expressions (2013)X2 t02 01 factorising complex expressions (2013)
X2 t02 01 factorising complex expressions (2013)
 
11 x1 t16 07 approximations (2013)
11 x1 t16 07 approximations (2013)11 x1 t16 07 approximations (2013)
11 x1 t16 07 approximations (2013)
 
11 x1 t16 06 derivative times function (2013)
11 x1 t16 06 derivative times function (2013)11 x1 t16 06 derivative times function (2013)
11 x1 t16 06 derivative times function (2013)
 
11 x1 t16 05 volumes (2013)
11 x1 t16 05 volumes (2013)11 x1 t16 05 volumes (2013)
11 x1 t16 05 volumes (2013)
 
11 x1 t16 04 areas (2013)
11 x1 t16 04 areas (2013)11 x1 t16 04 areas (2013)
11 x1 t16 04 areas (2013)
 
11 x1 t16 03 indefinite integral (2013)
11 x1 t16 03 indefinite integral (2013)11 x1 t16 03 indefinite integral (2013)
11 x1 t16 03 indefinite integral (2013)
 
11 x1 t16 02 definite integral (2013)
11 x1 t16 02 definite integral (2013)11 x1 t16 02 definite integral (2013)
11 x1 t16 02 definite integral (2013)
 

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11 x1 t11 09 locus problems (2012)

  • 2. Locus Problems Eliminate the parameter (get rid of the p’s and q’s)
  • 3. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point.
  • 4. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding.
  • 5. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters)
  • 6. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value.
  • 7. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3)
  • 8. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3
  • 9. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3 b) Type 2: obvious relationship between the values, usually only one parameter.
  • 10. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3 b) Type 2: obvious relationship between the values, usually only one parameter. e.g. 6t , t 2  1
  • 11. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3 b) Type 2: obvious relationship between the values, usually only one parameter. e.g. 6t , t 2  1 x  6t x t 6
  • 12. Locus Problems Eliminate the parameter (get rid of the p’s and q’s) We find the locus of a point. 1 Find the coordinates of the point whose locus you are finding. 2 Look for the relationship between the x and y values (i.e. get rid of the parameters) a) Type 1: already no parameter in the x or y value. e.g. (p + q,– 3) locus is y = – 3 b) Type 2: obvious relationship between the values, usually only one parameter. e.g. 6t , t 2  1 x  6t y  t 2 1 x x2 t y  1 6 36
  • 13. c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters.
  • 14. c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p 2  q 2 , p  q  Given that pq = 3
  • 15. c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2   p  q   2 pq 2 Given that pq = 3
  • 16. c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2 x  y2  6   p  q   2 pq 2 Given that pq = 3
  • 17. c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2 x  y2  6   p  q   2 pq 2 Given that pq = 3 2005 Extension 1 HSC Q4c) The points P2ap, ap 2  and Q2aq, aq 2  lie on the parabola x 2  4ay The equation of the normal to the parabola at P is x  py  2ap  ap 3 and the equation of the normal at Q is given by x  qy  2aq  aq 3
  • 18. c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2 x  y2  6   p  q   2 pq 2 Given that pq = 3 2005 Extension 1 HSC Q4c) The points P2ap, ap 2  and Q2aq, aq 2  lie on the parabola x 2  4ay The equation of the normal to the parabola at P is x  py  2ap  ap 3 and the equation of the normal at Q is given by x  qy  2aq  aq 3 (i) Show that the normals at P and Q intersect at the point R whose coordinates are  apq p  q , a p 2  pq  q 2  2
  • 19. c) Type 3: not an obvious relationship between the values, use a previously proven relationship between the parameters. e.g.  p  q , p  q  2 2 x  p2  q2 x  y2  6   p  q   2 pq 2 Given that pq = 3 2005 Extension 1 HSC Q4c) The points P2ap, ap 2  and Q2aq, aq 2  lie on the parabola x 2  4ay The equation of the normal to the parabola at P is x  py  2ap  ap 3 and the equation of the normal at Q is given by x  qy  2aq  aq 3 (i) Show that the normals at P and Q intersect at the point R whose coordinates are  apq p  q , a p 2  pq  q 2  2 1 (ii) The equation of the chord PQ is y   p  q x  apq . If PQ passes through (0,a), show that pq = – 1 2
  • 20. (iii) Find the locus of R if PQ passes through (0,a)
  • 21. (iii) Find the locus of R if PQ passes through (0,a) x  apq p  q 
  • 22. (iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a
  • 23. (iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a y  a p 2  pq  q 2  2
  • 24. (iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a y  a p 2  pq  q 2  2  y  a  p  q   pq  2 2 
  • 25. (iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a y  a p 2  pq  q 2  2  y  a  p  q   pq  2 2   x2  y  a 2  1  2  a 
  • 26. (iii) Find the locus of R if PQ passes through (0,a) x  apq p  q  x  a p  q  x pq  a y  a p 2  pq  q 2  2  y  a  p  q   pq  2 2   x2  y  a 2  1  2  a  x2 y   3a a
  • 27. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay
  • 28. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq
  • 29. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R.
  • 30. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1
  • 31. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0   1 2ap  0 2aq  0
  • 32. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0   1 2ap  0 2aq  0 ap 2 q 2  4a 2 pq
  • 33. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0   1 2ap  0 2aq  0 ap 2 q 2  4a 2 pq pq  4
  • 34. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0 y  apq   1 2ap  0 2aq  0 ap 2 q 2  4a 2 pq pq  4
  • 35. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0 y  apq   1 2ap  0 2aq  0 y  4a ap 2 q 2  4a 2 pq pq  4
  • 36. 2004 Extension 1 HSC Q4b) The two points P2ap, ap 2  and Q2aq, aq 2  are on the parabola x 2  4ay (i) The equation of the tangent to x 2  4ay at an arbitrary point 2at , at 2  on the parabola is y  tx  at 2 Show that the tangents at the points P and Q meet at R, where R is the point a p  q , apq (ii) As P varies, the point Q is chosen so that POQ is a right angle, where O is the origin. Find the locus of R. mOP  mOQ  1 ap 2  0 aq 2  0 y  apq   1 Exercise 9J; odds 2ap  0 2aq  0 y  4a up to 23 ap 2 q 2  4a 2 pq pq  4