Hooke's law is written as `F = kx`

where:

`F` = force

`k` = proportionality constant or spring constant

`x` = length displacement from its natural length

Apply Hooke's Law to the integral application for work: `W = int_a^b F dx` , we get:

`W = int_a^b kx dx`

`W = k * int_a^b x dx`

Apply Power rule for integration: `int x^n(dx) = x^(n+1)/(n+1)`

`W = k * x^(1+1)/(1+1)|_a^b`

`W = k * x^2/2|_a^b`

From the given work: seven and one-half foot-pounds **(7.5 ft-lbs)** , note that the units has "ft" instead of inches. To be consistent, apply the conversion factor: **12 inches = 1 foot** then:

`2` inches = `1/6` ft

`1/2` or `0.5` inches =`1/24` ft

To solve for k, we consider the initial condition of applying 7.5 ft-lbs to compress a spring `2` inches or `1/6` ft from its natural length. Compressing `1/6` ft of it natural length implies the boundary values:` a=0` to `b=1/6` ft.

Applying `W = k * x^2/2|_a^b` , we get:

`7.5= k * x^2/2|_0^(1/6)`

Apply definite integral formula: `F(x)|_a^b = F(b)-F(a)` .

`7.5 =k [(1/6)^2/2-(0)^2/2]`

`7.5 = k * [(1/36)/2 -0]`

`7.5= k *[1/72]`

`k =7.5*72`

`k =540`

To solve for the work needed to compress the spring with additional 1/24 ft, we plug-in:` k =540` , `a=1/6` , and `b = 5/24` on `W = k * x^2/2|_a^b` .

Note that compressing "additional one-half inches" from its `2` inches compression is the same as to compress a spring `2.5` inches or `5/24` ft from its natural length.

`W= 540 * x^2/2|_((1/6))^((5/24))`

`W = 540 [ (5/24)^2/2-(1/6)^2/2 ]`

`W =540 [25/1152- 1/72 ]`

`W =540[1/128]`

`W=135/32` or `4.21875` ft-lbs

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