When rubber is stretched, its elongation is initially proportional to the applied force, but as it reaches about twice its original length, the force required to stretch the rubber increases rapidly. The force, as a function of elongation, that was required to stretch a rubber specimen that was initially 3 in. long is displayed in the following table.
(a) Curve-fit the data with a forth-order polynomial. Make a plot of the data points and the polynomial. Use the polynomial to estimate the force when the rubber specimen was 11.5 in. long.
(b) Fit the data with spline interpolation (use MATLAB's built-in function interpl). Make a plot that shows the data points and a curve made by interpolation. Use interpolation to estimate the force when the rubber specimen was 11.5 in. long.

Transcribed Image Text:

Force (b) Elongation in)0 | | 1.2 2.4 3.6 4.8 6.0 7.2 8.4 3.12 | 4. 14 15341 6.22-i-7.12]-7.86 Force (lb) 1.92 8.42. Elongation (in) 9.6 10.8 | 12.0 1-13.2 14.41 15.6 16.8118-