Question

Question #1b9c7

Answer 1

Solution to a) `->x=1/2`

Explanation:

Solution to a)

Adding logs reflects the action of multiplication of the source values.

So `ln(x-1)+ln(3)=ln(x)` is the same as: `ln( 3[x-1])=ln(x)`

Using an example: note that `ln^(-1)(a)=a`

So `" "ln^(-1)(3[x-1])" "=" "ln^(-1)(x)`

`" "3(x-1)" "=" "x`

`" "3x-1=x`

`" "2x=1`

`" "x=1/2`

Answer 2

Solution to b) `" "x~~8.773...` to 3 decimal places

Explanation:

Solution to b)

Using an example: note that `" "2ln(a) -> ln(a^2)`

So we have:

`ln[(5x)^3]-ln(x^2)=7`

`ln[(125x^3)/x^2]=7`

`ln(125x)=7`

`ln^(-1)(125x)=ln^(-1)(7) larr" not convinced this will work!"`

Trying something else!

`ln(125)+ln(x)=7`

`ln(x)=7-ln(125)`

`x=ln^(-1)(x)= ln^(-1)[color(white)(2/2)7-ln(125)color(white)(2/2)]`

`x~~8.773...` to 3 decimal places