A piecewise-polynomial is usually constructed by some command, through a process of interpolation or approximation, or conversion from some other form e.g., from the B-form, and is output as a variable. But it is also possible to make one up from scratch, using the statement

pp = ppmak(breaks,coefs)

For example, if you enter `pp=ppmak(-5:-1,-22:-11)`

,
or, more explicitly,

breaks = -5:-1; coefs = -22:-11; pp = ppmak(breaks,coefs);

you specify the uniform break sequence
-`5:`

-`1`

and the coefficient sequence
-`22:`

-`11`

. Because this break
sequence has 5 entries, hence 4 break intervals, while the coefficient
sequence has 12 entries, you have, in effect, specified a piecewise-polynomial
of order 3 (= 12/4). The command

fnbrk(pp)

prints out all the constituent parts of this piecewise-polynomial, as follows:

breaks(1:l+1) -5 -4 -3 -2 -1 coefficients(d*l,k) -22 -21 -20 -19 -18 -17 -16 -15 -14 -13 -12 -11 pieces number l 4 order k 3 dimension d of target 1

Further, `fnbrk`

can be used to supply each
of these parts separately. But the point of Curve Fitting Toolbox™ spline
functionality is that you usually need not concern yourself with these
details. You simply use `pp`

as an argument to commands
that evaluate, differentiate, integrate, convert, or plot the piecewise-polynomial
whose description is contained in `pp`

.

Here are some functions for operations you can perform on a piecewise-polynomial.

| Evaluates |

| Differentiates |

| Differentiates in the direction |

| Integrates |

| Finds the minimum value in given interval |

| Finds the zeros in the given interval |

| Pulls out the |

| |

| Extends outside its basic interval by polynomial of specified order |

| Plots on given interval |

| Converts to B-form |

| Inserts additional breaks |

Inserting additional breaks comes in handy when you want to
add two piecewise-polynomials with different breaks, as is done in
the command `fncmb`

.

Execute the following commands to create and plot the particular piecewise-polynomial (ppform) described in the Constructing a ppform section.

Create the piecewise-polynomial with break sequence

`-5:-1`

and coefficient sequence`-22:-11`

:pp=ppmak(-5:-1,-22:-11)

Create the basic plot:

x = linspace(-5.5,-.5,101); plot(x, fnval(pp,x),'x')

Add the break lines to the plot:

breaks=fnbrk(pp,'b'); yy=axis; hold on for j=1:fnbrk(pp,'l')+1 plot(breaks([j j]),yy(3:4)) end

Superimpose the plot of the polynomial that supplies the third polynomial piece:

plot(x,fnval(fnbrk(pp,3),x),'linew',1.3) set(gca,'ylim',[-60 -10]), hold off

**A Piecewise-Polynomial Function, Its Breaks,
and the Polynomial Giving Its Third Piece**

The figure above is the final picture. It shows the piecewise-polynomial
as a sequence of points and, solidly on top of it, the polynomial
from which its third polynomial piece is taken. It is quite noticeable
that the value of a piecewise-polynomial at a break is its limit from
the *right*, and that the value of the piecewise-polynomial
outside its basic interval is obtained by extending its leftmost,
respectively its rightmost, polynomial piece.

While the ppform of a piecewise-polynomial is efficient for evaluation,
the *construction* of a piecewise-polynomial from
some data is usually more efficiently handled by determining first
its *B-form*, i.e., its representation as a linear
combination of B-splines.