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12X1 T01 01 log laws (2010)

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Nigel Simmons
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Logarithms
Logarithms Logarithms are the inverse of exponentials.
Logarithms Logarithms are the inverse of exponentials. If y  a x
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y x  ln y
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y x  ln y x  log y
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y y y  log a x a  1 1 x
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y y y  log a x a  1 1 x y  log a x 0  a  1
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y y y  log a x a  1 1 x domain : x  0 y  log a x 0  a  1
Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y y y  log a x a  1 1 x domain : x  0 range : all real y y  log a x 0  a  1
Log Laws
Log Laws 1 log a m  log a n  log a mn
Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n
Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m
Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m 4 log a 1  0
Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m 4 log a 1  0 5 log a a  1
Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m 4 log a 1  0 5 log a a  1 6 a log x  x a
Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m 4 log a 1  0 5 log a a  1 6 a log x  x a log b x 7  log a x  log b a
e.g. (i) x  log 5 125
e.g. (i) x  log 5 125 5 x  125
e.g. (i) x  log 5 125 5 x  125 x3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16  log 4 4 2
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16  log 4 4 2  2 log 4 4
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16  log 4 4 2  2 log 4 4 2
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3  log 4 4 2  2 log 4 4 2
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3  log 4 4 2 6 log 6 32  2 log 4 4 2
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3  log 4 4 2 6 log 6 32  2 log 4 4  32 2
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3  log 4 4 2 6 log 6 32  2 log 4 4  32 2 9
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  2 log 4 4  32 2 9
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32 2 9
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 125  32   log10     4 
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 125  32   log10     4   log10 1000
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 125  32   log10     4   log10 1000 3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 log 7 8 e) 125  32  log 7 2  log10     4   log10 1000 3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 log 7 8 e) 125  32  log 7 2  log10     4   log 2 8  log10 1000 3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 log 7 8 e) 125  32  log 7 2  log10     4   log 2 8  log10 1000 3 3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 125  32  log 7 2  log10     4   log 2 8  log10 1000 3 3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 1 1 log 7 2  log 2 125  32   log10    2 8  4   log 2 8  log10 1000 3 3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 1 1 log 7 2  log 2 125  32   log10    2 8  4   log 2 8  log10 1000 3 3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 1 1 log 7 2  log 2 125  32   log10    2 8  4   log 2 8 1  log10 1000   3 3 2 3
e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 1 1 log 7 2  log 2 125  32   log10    2 8  4   log 2 8 1  log10 1000   3 3 2 3 3  2
1 iv  32 x 1  27
1 iv  32 x 1  27 32 x 1  33
1 iv  32 x 1  27 32 x 1  33 2 x  1  3 2 x  4 x  2
1 iv  32 x 1  v  2 x  9 27 32 x 1  33 2 x  1  3 2 x  4 x  2
1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 2 x  1  3 2 x  4 x  2
1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 x log 2  log 9 2 x  1  3 2 x  4 x  2
1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 x log 2  log 9 2 x  1  3 log 9 2 x  4 x log 2 x  2
1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 x log 2  log 9 2 x  1  3 log 9 2 x  4 x log 2 x  2 x  3.17 (to 2 dp)
1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 x log 2  log 9 2 x  1  3 log 9 2 x  4 x log 2 x  2 x  3.17 (to 2 dp) Exercise 12A; 2, 3aceg, 4bdfh, 5ab, 6ab, 7ac, 8bdh, 9ac, 14, 18* Exercise 6B; 8

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12X1 T01 01 log laws (2010)

  • 2. Logarithms Logarithms are the inverse of exponentials.
  • 3. Logarithms Logarithms are the inverse of exponentials. If y  a x
  • 4. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y
  • 5. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x
  • 6. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y
  • 7. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y x  ln y
  • 8. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y x  ln y x  log y
  • 9. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y
  • 10. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y y y  log a x a  1 1 x
  • 11. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y y y  log a x a  1 1 x y  log a x 0  a  1
  • 12. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y y y  log a x a  1 1 x domain : x  0 y  log a x 0  a  1
  • 13. Logarithms Logarithms are the inverse of exponentials. If y  a x then x  log a y If y  e x then x  log e y log base e is known as x  ln y the natural logarithm. x  log y y y  log a x a  1 1 x domain : x  0 range : all real y y  log a x 0  a  1
  • 15. Log Laws 1 log a m  log a n  log a mn
  • 16. Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n
  • 17. Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m
  • 18. Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m 4 log a 1  0
  • 19. Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m 4 log a 1  0 5 log a a  1
  • 20. Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m 4 log a 1  0 5 log a a  1 6 a log x  x a
  • 21. Log Laws 1 log a m  log a n  log a mn m 2 log a m  log a n  log a   n 3 log a m n  n log a m 4 log a 1  0 5 log a a  1 6 a log x  x a log b x 7  log a x  log b a
  • 22. e.g. (i) x  log 5 125
  • 23. e.g. (i) x  log 5 125 5 x  125
  • 24. e.g. (i) x  log 5 125 5 x  125 x3
  • 25. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x3
  • 26. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3
  • 27. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7
  • 28. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16
  • 29. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16  log 4 4 2
  • 30. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16  log 4 4 2  2 log 4 4
  • 31. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16  log 4 4 2  2 log 4 4 2
  • 32. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3  log 4 4 2  2 log 4 4 2
  • 33. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3  log 4 4 2 6 log 6 32  2 log 4 4 2
  • 34. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3  log 4 4 2 6 log 6 32  2 log 4 4  32 2
  • 35. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3  log 4 4 2 6 log 6 32  2 log 4 4  32 2 9
  • 36. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  2 log 4 4  32 2 9
  • 37. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32 2 9
  • 38. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9
  • 39. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7
  • 40. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4
  • 41. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 125  32   log10     4 
  • 42. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 125  32   log10     4   log10 1000
  • 43. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 125  32   log10     4   log10 1000 3
  • 44. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 log 7 8 e) 125  32  log 7 2  log10     4   log10 1000 3
  • 45. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 log 7 8 e) 125  32  log 7 2  log10     4   log 2 8  log10 1000 3
  • 46. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 d) log10125  log10 32  log10 4 log 7 8 e) 125  32  log 7 2  log10     4   log 2 8  log10 1000 3 3
  • 47. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 125  32  log 7 2  log10     4   log 2 8  log10 1000 3 3
  • 48. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 1 1 log 7 2  log 2 125  32   log10    2 8  4   log 2 8  log10 1000 3 3
  • 49. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 1 1 log 7 2  log 2 125  32   log10    2 8  4   log 2 8  log10 1000 3 3
  • 50. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 1 1 log 7 2  log 2 125  32   log10    2 8  4   log 2 8 1  log10 1000   3 3 2 3
  • 51. e.g. (i) x  log 5 125 ii  log x 343  3 5 x  125 x 3  343 x3 x7 iii  Evaluate; a) log 4 16 b) 6 2log 6 3 c) log 216  log 2 8  log 4 4 2 6 log 6 32  log 2 128  2 log 4 4  32  log 2 27 2 9 7 1 f) log 2 log 7 8 8 d) log10125  log10 32  log10 4 e) 1 1 log 7 2  log 2 125  32   log10    2 8  4   log 2 8 1  log10 1000   3 3 2 3 3  2
  • 52. 1 iv  32 x 1  27
  • 53. 1 iv  32 x 1  27 32 x 1  33
  • 54. 1 iv  32 x 1  27 32 x 1  33 2 x  1  3 2 x  4 x  2
  • 55. 1 iv  32 x 1  v  2 x  9 27 32 x 1  33 2 x  1  3 2 x  4 x  2
  • 56. 1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 2 x  1  3 2 x  4 x  2
  • 57. 1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 x log 2  log 9 2 x  1  3 2 x  4 x  2
  • 58. 1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 x log 2  log 9 2 x  1  3 log 9 2 x  4 x log 2 x  2
  • 59. 1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 x log 2  log 9 2 x  1  3 log 9 2 x  4 x log 2 x  2 x  3.17 (to 2 dp)
  • 60. 1 iv  32 x 1  v  2 x  9 27 log 2 x  log 9 32 x 1  33 x log 2  log 9 2 x  1  3 log 9 2 x  4 x log 2 x  2 x  3.17 (to 2 dp) Exercise 12A; 2, 3aceg, 4bdfh, 5ab, 6ab, 7ac, 8bdh, 9ac, 14, 18* Exercise 6B; 8