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11X1 T09 03 rules for differentiation (2010)

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Nigel Simmons
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Rules For Differentiation
Rules For Differentiation (1) y  c
Rules For Differentiation (1) y  c f  x  c
Rules For Differentiation (1) y  c f  x  c f  x  h  c
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx f  x   kx
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx f  x   kx f  x  h  k  x  h  kx  kh
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx kx  kh  kx f  x   kx f   x   lim h0 h f  x  h  k  x  h  kx  kh
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx kx  kh  kx f  x   kx f   x   lim h0 h f  x  h  k  x  h kh  lim  kx  kh h0 h
Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx kx  kh  kx f  x   kx f   x   lim h0 h f  x  h  k  x  h kh  lim  kx  kh h0 h  lim k h0 k
(3) y  x n
(3) y  x n a 2  b 2   a  b  a  b 
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2 
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3 
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1 
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n  x  h   xn n f   x   lim h0 h
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n  x  h   xn n f   x   lim h0 h  lim   x  h  x   x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n  x  h   xn n f   x   lim h0 h  lim   x  h  x   x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h  lim  h  x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h
(3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n  x  h   xn n f   x   lim h0 h  lim   x  h  x   x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h  lim  h  x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h  lim  x  h    x  h  x     x  h  x n2  x n1 n 1 n2 h0
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 f  x  x
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 f  x  x 1 f  x  h  xh
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 f  x  h  xh
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h 
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h 
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h  1  lim h0 x  x  h 
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h  1  lim h0 x  x  h  1  2 x
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  Note: f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h  1  lim h0 x  x  h  1  2 x
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  Note: f  x  f   x   lim x  h x x h0 h f  x   x 1 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h  1  lim h0 x  x  h  1  2 x
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  Note: f  x  f   x   lim x  h x x h0 h f  x   x 1 1 xxh f  x  h   lim xh h0 hx  x  h  f   x    x 2 h  lim h0 hx  x  h  1  lim h0 x  x  h  1  2 x
f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  Note: f  x  f   x   lim x  h x x h0 h f  x   x 1 1 xxh f  x  h   lim xh h0 hx  x  h  f   x    x 2 h 1  lim  2 h0 hx  x  h  x 1  lim h0 x  x  h  1  2 x
(5) y  x
(5) y  x f  x  x
(5) y  x f  x  x f  x  h  x  h
(5) y  x f  x  x xh x f  x  h  x  h f   x   lim h 0 h
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x h  lim h0  h xh x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim  h0 h xh x h  lim  h0 h xh x 1  lim  h0  xh x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim  h0 h xh x h  lim  h0 h xh x 1  lim  h0  xh x 1  x x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim  h0 h xh x h  lim  h0 h xh x 1  lim  h0  xh x 1  x x 1  2 x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim  h0 h xh x h  lim  h0 h xh x Note: 1  lim  h0  xh x 1  x x 1  2 x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x  h  lim h0  h xh x  Note: 1 1 f  x  x2  lim h0  xh x 1  x x 1  2 x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x  h  lim h0  h xh x  Note: 1 1 f  x  x2  lim h0  xh x 1 1 f  x  x 2 1 2  x x 1  2 x
(5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x  h  lim h0  h xh x  Note: 1 1 f  x  x2  lim h0  xh x 1 1 f  x  x 2 1 2  1 x x  2 x 1  2 x
e.g.  i  y  7
e.g.  i  y  7 dy 0 dx
e.g.  i  y  7 dy 0 dx  ii  y  37 x
e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx
e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10
e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx
e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2
e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x f  x   x3  3  iv  y  3x 2  6 x  2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x f  x   x3  3  iv  y  3x 2  6 x  2 f   x   3x 2 dy  6x  6 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x f  x   x3  3  iv  y  3x 2  6 x  2 f   x   3x 2 dy  6x  6 f   2  3 2 2 dx
e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x f  x   x3  3  iv  y  3x 2  6 x  2 f   x   3x 2 dy  6x  6 f   2  3 2 2 dx  12
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 dy  15 x 2  12 x dx
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 dy  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 dy  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx 3
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 dy  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx 3  required slope  3
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx 3  required slope  3
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx 3  required slope  3
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal y  x 3  12 x
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal y  x 3  12 x dy  3 x 2  12 dx
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal dy tangents are horizontal when 0 y  x 3  12 x dx dy  3 x 2  12 dx
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal dy tangents are horizontal when 0 y  x 3  12 x dx i.e. 3 x  12  0 2 dy  3 x 2  12 dx
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal dy tangents are horizontal when 0 y  x 3  12 x dx i.e. 3 x  12  0 2 dy  3 x 2  12 x2  4 dx x  2
 xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal dy tangents are horizontal when 0 y  x 3  12 x dx i.e. 3 x  12  0 2 dy  3 x 2  12 x2  4 dx x  2  tangents are horizontal at  2,16  and  2, 16 
A normal is a line perpendicular to the tangent at the point of contact
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x tangent
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29 
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2 dy  8x  3 dx
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2 dy  8x  3 dx dy when x  3,  8  3  3 dx
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2 dy  8x  3 dx dy when x  3,  8  3  3 dx  21
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2 dy  8x  3 dx dy when x  3,  8  3  3 dx  21 1  required slope   21
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  1 y  4 x  3x  2 2 y  29    x  3 dy 21  8x  3 dx dy when x  3,  8  3  3 dx  21 1  required slope   21
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  1 y  4 x  3x  2 2 y  29    x  3 dy 21  8x  3 21 y  609   x  3 dx dy when x  3,  8  3  3 dx  21 1  required slope   21
A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  1 y  4 x  3x  2 2 y  29    x  3 dy 21  8x  3 21 y  609   x  3 dx dy when x  3,  8  3  3 x  21 y  612  0 dx  21 1  required slope   21
Exercise 7C; 1ace etc, 2ace etc, 3ace etc, 4bd, 5bdfh, 8bd, 9bd, 10ac, 12, 13b, 16, 21 Exercise 7D; 2ac, 3bd, 4ace, 6c, 7b, 11a, 13aei, 18, 22

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11X1 T09 03 rules for differentiation (2010)

  • 3. Rules For Differentiation (1) y  c f  x  c
  • 4. Rules For Differentiation (1) y  c f  x  c f  x  h  c
  • 5. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c
  • 6. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h
  • 7. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0
  • 8. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx
  • 9. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx f  x   kx
  • 10. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx f  x   kx f  x  h  k  x  h  kx  kh
  • 11. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx kx  kh  kx f  x   kx f   x   lim h0 h f  x  h  k  x  h  kx  kh
  • 12. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx kx  kh  kx f  x   kx f   x   lim h0 h f  x  h  k  x  h kh  lim  kx  kh h0 h
  • 13. Rules For Differentiation (1) y  c cc f  x  c f   x   lim h0 h f  x  h  c 0  lim h 0 h  lim 0 h0 0 (2) y  kx kx  kh  kx f  x   kx f   x   lim h0 h f  x  h  k  x  h kh  lim  kx  kh h0 h  lim k h0 k
  • 14. (3) y  x n
  • 15. (3) y  x n a 2  b 2   a  b  a  b 
  • 16. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2 
  • 17. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3 
  • 18. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1 
  • 19. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn
  • 20. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n
  • 21. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n  x  h   xn n f   x   lim h0 h
  • 22. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n  x  h   xn n f   x   lim h0 h  lim   x  h  x   x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h
  • 23. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n  x  h   xn n f   x   lim h0 h  lim   x  h  x   x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h  lim  h  x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h
  • 24. (3) y  x n a 2  b 2   a  b  a  b  a 3  b3   a  b   a 2  ab  b 2  a 4  b 4   a  b   a 3  a 2b  ab 2  b3   a n  b n   a  b   a n1  a n2b  a n3b 2    a 2b n3  ab n2  b n1  f  x   xn f  x  h   x  h n  x  h   xn n f   x   lim h0 h  lim   x  h  x   x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h  lim  h  x  h    x  h  x     x  h  x n2  x n1 n 1 n2  h0 h  lim  x  h    x  h  x     x  h  x n2  x n1 n 1 n2 h0
  • 25. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0
  • 26. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1
  • 27. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1
  • 28. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x
  • 29. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 f  x  x
  • 30. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 f  x  x 1 f  x  h  xh
  • 31. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 f  x  h  xh
  • 32. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h 
  • 33. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h 
  • 34. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h  1  lim h0 x  x  h 
  • 35. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h  1  lim h0 x  x  h  1  2 x
  • 36. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  Note: f  x  f   x   lim x  h x x h0 h 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h  1  lim h0 x  x  h  1  2 x
  • 37. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  Note: f  x  f   x   lim x  h x x h0 h f  x   x 1 1 xxh f  x  h   lim xh h0 hx  x  h  h  lim h0 hx  x  h  1  lim h0 x  x  h  1  2 x
  • 38. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  Note: f  x  f   x   lim x  h x x h0 h f  x   x 1 1 xxh f  x  h   lim xh h0 hx  x  h  f   x    x 2 h  lim h0 hx  x  h  1  lim h0 x  x  h  1  2 x
  • 39. f   x   lim  x  h    x  h x     x  h  x n2  x n1 n 1 n2 h0  x n1  x n1    x n1  x n1  nx n1 1 (4) y  x 1 1 1  Note: f  x  f   x   lim x  h x x h0 h f  x   x 1 1 xxh f  x  h   lim xh h0 hx  x  h  f   x    x 2 h 1  lim  2 h0 hx  x  h  x 1  lim h0 x  x  h  1  2 x
  • 41. (5) y  x f  x  x
  • 42. (5) y  x f  x  x f  x  h  x  h
  • 43. (5) y  x f  x  x xh x f  x  h  x  h f   x   lim h 0 h
  • 44. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x
  • 45. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x
  • 46. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x h  lim h0  h xh x
  • 47. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim  h0 h xh x h  lim  h0 h xh x 1  lim  h0  xh x
  • 48. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim  h0 h xh x h  lim  h0 h xh x 1  lim  h0  xh x 1  x x
  • 49. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim  h0 h xh x h  lim  h0 h xh x 1  lim  h0  xh x 1  x x 1  2 x
  • 50. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim  h0 h xh x h  lim  h0 h xh x Note: 1  lim  h0  xh x 1  x x 1  2 x
  • 51. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x  h  lim h0  h xh x  Note: 1 1 f  x  x2  lim h0  xh x 1  x x 1  2 x
  • 52. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x  h  lim h0  h xh x  Note: 1 1 f  x  x2  lim h0  xh x 1 1 f  x  x 2 1 2  x x 1  2 x
  • 53. (5) y  x f  x  x xh x xh x f  x  h  x  h f   x   lim  h 0 h xh x xhx  lim h0  h xh x  h  lim h0  h xh x  Note: 1 1 f  x  x2  lim h0  xh x 1 1 f  x  x 2 1 2  1 x x  2 x 1  2 x
  • 54. e.g.  i  y  7
  • 55. e.g.  i  y  7 dy 0 dx
  • 56. e.g.  i  y  7 dy 0 dx  ii  y  37 x
  • 57. e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx
  • 58. e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10
  • 59. e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx
  • 60. e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2
  • 61. e.g.  i  y  7 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 62. e.g.  i  y  7  v  y   2 x  1 2 dy 0 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 63. e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 64. e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x dy  37 dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 65. e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 66. e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2  iii  y  x10 dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 67. e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy  10 x 9 dx  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 68. e.g.  i  y  7  v  y   2 x  1 2 dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 69. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 dx dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 70. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dx  ii  y  37 x 1 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 71. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2  37 x dx  3 x  x 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 72. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx dy 2  10 x 9  3 3 dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 73. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 74. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x f  x   x3  3  iv  y  3x 2  6 x  2 dy  6x  6 dx
  • 75. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x f  x   x3  3  iv  y  3x 2  6 x  2 f   x   3x 2 dy  6x  6 dx
  • 76. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x f  x   x3  3  iv  y  3x 2  6 x  2 f   x   3x 2 dy  6x  6 f   2  3 2 2 dx
  • 77. e.g.  i  y  7  v  y   2 x  1 2  vii  y  x 2 x dy 0  4x2  4 x  1 5 dx x 2 dy  8x  4 dy 5 3 dx  x2  ii  y  37 x 1 dx 2 dy  vi  y  3x  2 5  37 x  x x dx  3 x  x 2 2 dy  3  2 x 3  iii  y  x10 dx  viii  If f  x   x3  3, dy  10 x 9  3 3 2 find f   2  dx x f  x   x3  3  iv  y  3x 2  6 x  2 f   x   3x 2 dy  6x  6 f   2  3 2 2 dx  12
  • 78.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1
  • 79.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2
  • 80.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 dy  15 x 2  12 x dx
  • 81.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 dy  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx
  • 82.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 dy  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx 3
  • 83.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 dy  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx 3  required slope  3
  • 84.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx 3  required slope  3
  • 85.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 dx 3  required slope  3
  • 86.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3
  • 87.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal
  • 88.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal y  x 3  12 x
  • 89.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal y  x 3  12 x dy  3 x 2  12 dx
  • 90.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal dy tangents are horizontal when 0 y  x 3  12 x dx dy  3 x 2  12 dx
  • 91.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal dy tangents are horizontal when 0 y  x 3  12 x dx i.e. 3 x  12  0 2 dy  3 x 2  12 dx
  • 92.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal dy tangents are horizontal when 0 y  x 3  12 x dx i.e. 3 x  12  0 2 dy  3 x 2  12 x2  4 dx x  2
  • 93.  xix  Find the equation of the tangent to the curve y  5 x3  6 x 2  2 at the point 1,1 y  5 x3  6 x 2  2 y  1  3  x  1 dy y  1  3x  3  15 x 2  12 x dx dy when x  1,  15 1  12 1 2 3x  y  2  0 dx 3  required slope  3  x  Find the points on the curve y  x3  12 x where the tangents are horizontal dy tangents are horizontal when 0 y  x 3  12 x dx i.e. 3 x  12  0 2 dy  3 x 2  12 x2  4 dx x  2  tangents are horizontal at  2,16  and  2, 16 
  • 94. A normal is a line perpendicular to the tangent at the point of contact
  • 95. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x
  • 96. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x tangent
  • 97. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent
  • 98. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29 
  • 99. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2
  • 100. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2 dy  8x  3 dx
  • 101. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2 dy  8x  3 dx dy when x  3,  8  3  3 dx
  • 102. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2 dy  8x  3 dx dy when x  3,  8  3  3 dx  21
  • 103. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  y  4 x 2  3x  2 dy  8x  3 dx dy when x  3,  8  3  3 dx  21 1  required slope   21
  • 104. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  1 y  4 x  3x  2 2 y  29    x  3 dy 21  8x  3 dx dy when x  3,  8  3  3 dx  21 1  required slope   21
  • 105. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  1 y  4 x  3x  2 2 y  29    x  3 dy 21  8x  3 21 y  609   x  3 dx dy when x  3,  8  3  3 dx  21 1  required slope   21
  • 106. A normal is a line perpendicular to the tangent at the point of contact y y  f  x x normal tangent  xi  Find the equation of the normal to the curve y  4 x 2  3 x  2 at the point  3, 29  1 y  4 x  3x  2 2 y  29    x  3 dy 21  8x  3 21 y  609   x  3 dx dy when x  3,  8  3  3 x  21 y  612  0 dx  21 1  required slope   21
  • 107. Exercise 7C; 1ace etc, 2ace etc, 3ace etc, 4bd, 5bdfh, 8bd, 9bd, 10ac, 12, 13b, 16, 21 Exercise 7D; 2ac, 3bd, 4ace, 6c, 7b, 11a, 13aei, 18, 22