The function MKPP will *shift* the polynomial so that `x = 0`

will start at the beginning of the corresponding range you give it. In your first example, the polynomial `x^3`

is shifted to the range `[1 2]`

, so if you want to evaluate the polynomial at an *unshifted* range of `[0 1]`

, you would have to do the following:

```
>> pp = mkpp(1:2,[1 0 0 0]); %# Your polynomial
>> ppval(pp,1.5+pp.breaks(1)) %# Shift evaluation point by the range start
ans =
3.3750 %# The answer you expect
```

In your second example, you have one polynomial `x^3`

shifted to the range `[1 1.5]`

and another polynomial `x^3`

shifted to the range of `[1.5 2]`

. Evaluating the piecewise polynomial at `x = 1.5`

gives you a value of zero, occurring at the start of the second polynomial.

It may help to visualize the polynomials you are making as follows:

```
x = linspace(0,3,100); %# A vector of x values
pp1 = mkpp([1 2],[1 0 0 0]); %# Your first piecewise polynomial
pp2 = mkpp([1 1.5 2],[1 0 0 0; 1 0 0 0]); %# Your second piecewise polynomial
subplot(1,2,1); %# Make a subplot
plot(x,ppval(pp1,x)); %# Evaluate and plot pp1 at all x
title('First Example'); %# Add a title
subplot(1,2,2); %# Make another subplot
plot(x,ppval(pp2,x)); %# Evaluate and plot pp2 at all x
axis([0 3 -1 8]) %# Adjust the axes ranges
title('Second Example'); %# Add a title
```