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11 x1 t15 06 roots & coefficients (2013)

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Nigel Simmons
BildungSeele & Geist
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Roots and Coefficients
Roots and Coefficients Quadratics ax 2  bx  c  0
Roots and Coefficients Quadratics ax 2  bx  c  0 b    a
Roots and Coefficients Quadratics ax 2  bx  c  0 b    a c   a
Roots and Coefficients Quadratics ax 2  bx  c  0 b    a Cubics ax 3  bx 2  cx  d  0 c   a
Roots and Coefficients Quadratics ax 2  bx  c  0 b    a Cubics ax 3  bx 2  cx  d  0       b a c   a
Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a c       a
Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a d    a c       a
Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0
Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0 b        a
Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0 b        a c             a
Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0 c b                    a a d          a
Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0 c b                    a a d e            a a
For the polynomial equation; ax n  bx n1  cx n2  dx n3    0
For the polynomial equation; ax n  bx n1  cx n2  dx n3    0 b    a (sum of roots, one at a time)
For the polynomial equation; ax n  bx n1  cx n2  dx n3    0 b    a c   a (sum of roots, one at a time) (sum of roots, two at a time)
For the polynomial equation; ax n  bx n1  cx n2  dx n3    0 b    a c   a d    a (sum of roots, one at a time) (sum of roots, two at a time) (sum of roots, three at a time)
For the polynomial equation; ax n  bx n1  cx n2  dx n3    0     b  a c  a d  a e  a (sum of roots, one at a time) (sum of roots, two at a time) (sum of roots, three at a time) (sum of roots, four at a time)
For the polynomial equation; ax n  bx n1  cx n2  dx n3    0     b  a c  a d  a e  a Note:  (sum of roots, one at a time) (sum of roots, two at a time) (sum of roots, three at a time) (sum of roots, four at a time) 2      2  2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    1 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 3 2    1 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 3 2    1 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 1 1 1 b)      3 2    1 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)        3 2    1 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)        3  2 1  2  3 2    1 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)        3  2 1  2  3  3 2    1 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)    c)  2   2   2     3  2 1  2  3  1 2
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    1 2 5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)    c)  2   2   2    2          2       3   2 1  2  3
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    1 2 5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)    c)  2   2   2    2          2       3 2  5   3     2    2 2  2 1  2  3
e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    1 2 5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)    c)  2   2   2    2          2       3 2  5   3     2    2 2  2 1  37 2  4  3
1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)     
1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0
1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii) 
1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1
1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1 (iii) 1   1   1 
1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1 (iii) 1   1   1              1 1 1
1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1 (iii) 1   1   1              1 1 1  3 1
1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1 (iii) 1   1   1              1 1 1 3 1 3 
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k.
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and  
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2   
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3 
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0 2 3   3  k  3  6  0 3 2
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0 2 3   3  k  3  6  0 3 2  54  9  3k  6  0
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0 2 3   3  k  3  6  0 3 2  54  9  3k  6  0 3k  39
2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0 2 3   3  k  3  6  0 3 2  54  9  3k  6  0 3k  39 k  13
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s s   2
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s s   2 1     t
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s s   2 1     t t 2
2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s s   2 1     t t 2 s  t  0
Exercise 4F; 2, 4, 5ac, 6ac, 8, 10a, 13, 15, 16ad, 17, 18, 19

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11 x1 t15 06 roots & coefficients (2013)

  • 3. Roots and Coefficients Quadratics ax 2  bx  c  0 b    a
  • 4. Roots and Coefficients Quadratics ax 2  bx  c  0 b    a c   a
  • 5. Roots and Coefficients Quadratics ax 2  bx  c  0 b    a Cubics ax 3  bx 2  cx  d  0 c   a
  • 6. Roots and Coefficients Quadratics ax 2  bx  c  0 b    a Cubics ax 3  bx 2  cx  d  0       b a c   a
  • 7. Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a c       a
  • 8. Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a d    a c       a
  • 9. Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0
  • 10. Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0 b        a
  • 11. Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0 b        a c             a
  • 12. Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0 c b                    a a d          a
  • 13. Roots and Coefficients Quadratics ax 2  bx  c  0 c   a b    a Cubics ax 3  bx 2  cx  d  0 b       a Quartics d    a c       a ax 4  bx 3  cx 2  dx  e  0 c b                    a a d e            a a
  • 14. For the polynomial equation; ax n  bx n1  cx n2  dx n3    0
  • 15. For the polynomial equation; ax n  bx n1  cx n2  dx n3    0 b    a (sum of roots, one at a time)
  • 16. For the polynomial equation; ax n  bx n1  cx n2  dx n3    0 b    a c   a (sum of roots, one at a time) (sum of roots, two at a time)
  • 17. For the polynomial equation; ax n  bx n1  cx n2  dx n3    0 b    a c   a d    a (sum of roots, one at a time) (sum of roots, two at a time) (sum of roots, three at a time)
  • 18. For the polynomial equation; ax n  bx n1  cx n2  dx n3    0     b  a c  a d  a e  a (sum of roots, one at a time) (sum of roots, two at a time) (sum of roots, three at a time) (sum of roots, four at a time)
  • 19. For the polynomial equation; ax n  bx n1  cx n2  dx n3    0     b  a c  a d  a e  a Note:  (sum of roots, one at a time) (sum of roots, two at a time) (sum of roots, three at a time) (sum of roots, four at a time) 2      2  2
  • 20. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7
  • 21. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2
  • 22. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2
  • 23. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    1 2
  • 24. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 3 2    1 2
  • 25. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 3 2    1 2
  • 26. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 1 1 1 b)      3 2    1 2
  • 27. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)        3 2    1 2
  • 28. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)        3  2 1  2  3 2    1 2
  • 29. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)        3  2 1  2  3  3 2    1 2
  • 30. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)    c)  2   2   2     3  2 1  2  3  1 2
  • 31. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    1 2 5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)    c)  2   2   2    2          2       3   2 1  2  3
  • 32. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    1 2 5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)    c)  2   2   2    2          2       3 2  5   3     2    2 2  2 1  2  3
  • 33. e.g. (i ) If  ,  and  are the roots of 2 x 3  5 x 2  3 x  1  0, find the values of; a) 4  4   4  7 5      2        3 2    1 2 5  1 4  4   4  7  4    7    2  2 27  2 1 1 1      b)    c)  2   2   2    2          2       3 2  5   3     2    2 2  2 1  37 2  4  3
  • 34. 1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)     
  • 35. 1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0
  • 36. 1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii) 
  • 37. 1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1
  • 38. 1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1 (iii) 1   1   1 
  • 39. 1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1 (iii) 1   1   1              1 1 1
  • 40. 1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1 (iii) 1   1   1              1 1 1  3 1
  • 41. 1988 Extension 1 HSC Q2c) 3 If  ,  and  are the roots of x  3 x  1  0 find: (i)           0 (ii)    1 (iii) 1   1   1              1 1 1 3 1 3 
  • 42. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k.
  • 43. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and  
  • 44. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2   
  • 45. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3 
  • 46. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0
  • 47. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0 2 3   3  k  3  6  0 3 2
  • 48. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0 2 3   3  k  3  6  0 3 2  54  9  3k  6  0
  • 49. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0 2 3   3  k  3  6  0 3 2  54  9  3k  6  0 3k  39
  • 50. 2003 Extension 1 HSC Q4c) It is known that two of the roots of the equation 2 x 3  x 2  kx  6  0 are reciprocals of each other. Find the value of k. 1 Let the roots be  , and   1      6    2     3  P   3  0 2 3   3  k  3  6  0 3 2  54  9  3k  6  0 3k  39 k  13
  • 51. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r
  • 52. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r
  • 53. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1
  • 54. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t
  • 55. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s
  • 56. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s s   2
  • 57. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s s   2 1     t
  • 58. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s s   2 1     t t 2
  • 59. 2006 Extension 1 HSC Q4a) The cubic polynomial P x   x 3  rx 2  sx  t , where r, s and t are real numbers, has three real zeros, 1,  and   (i) Find the value of r 1       r r  1 (ii) Find the value of s + t 1   1         s s   2 1     t t 2 s  t  0
  • 60. Exercise 4F; 2, 4, 5ac, 6ac, 8, 10a, 13, 15, 16ad, 17, 18, 19