# Mathematica Interpolation[] that remains constant when outside range

I want to "modify" Mathematica's Interpolation[] function (in 1 dimension) by replacing extrapolation with constant values when the input is out of range.

In other words, if the interpolation domain is [1,20] and f[1]==7 and f[20]==12, I want:

f[x] = 7 for x<=1
f[x] = 12 for x>=20
f[x] = Interpolation[...]

However, this fails:

(* interpolation w cutoff *)
interpcut[r_] := Module[{s, minpair, maxpair},

(* sort array by x coord *)
s = Sort[r, #1[[1]] < #2[[1]] &];

(* find min x value and corresponding y value *)
minpair = s[[1]];

(* ditto for max x value *)
maxpair = s[[-1]];

(* return the pure function representing cutoff interpolation *)
Piecewise[{
{minpair[[2]] &, #1 < minpair[[1]] &},
{maxpair[[2]] &, #1 > maxpair[[1]] &},
{Interpolation[r], True}
}]]

test = Table[{x,Prime[x]},{x,1,10}]

InputForm[interpcut[test]]

Piecewise[{{minpair\$59[[2]] & , #1 < minpair\$59[[1]] & },
{maxpair\$59[[2]] & , #1 > maxpair\$59[[1]] & }},
InterpolatingFunction[{{1, 10}}, {3, 1, 0, {10}, {4}, 0, 0, 0, 0},
{{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}}, {{2}, {3}, {5}, {7}, {11}, {13}, {17},
{19}, {23}, {29}}, {Automatic}]]

I'm sure I'm missing something basic. What?

-

Function definition

interpcut[r_, x_] :=
Module[{s},(*sort array by x coord*)
s = SortBy[r, First];
Piecewise[
{{First[s][[2]], x < First[s][[1]]},
{Last [s][[2]], x > Last [s][[1]]},
{Interpolation[r][x], True}}]];

Test

test = Table[{x, Prime[x]}, {x, 1, 10}];
f[x_] := interpcut[test, x]
Plot[f[x], {x, -10, 30}]

Edit

I did it that way just for clarity, not for cheating. For using pure functions just "follow the recipe":

interpcut[r_] := Module[{s},
s = SortBy[r, First];
Function[Piecewise[
{{First[s][[2]], # < First[s][[1]]},
{Last [s][[2]], # > Last [s][[1]]},
{Interpolation[r][#], True}}]]
]

test = Table[{x, Prime[x]}, {x, 1, 10}];
f = interpcut[test] // InputForm
Plot[interpcut[test][x], {x, -10, 30}]
-
OK, but that's cheating. I want it to return a pure function like Interpolation[] does. interpcut should take an array as input and return a pure function as output. Otherwise, I have to rewrite a lot of stuff. –  barrycarter Dec 18 '10 at 3:56
OK, it turns out that calling your function interpcut1 and then doing: interpcut[r_] := Function[x, interpcut1[r,x]] does the trick. –  barrycarter Dec 18 '10 at 4:49
@barrycarter Yes, once you get the pure function you can redefine it as you want ... –  belisarius Dec 18 '10 at 4:52
You can get the best of both the "not-cheating" and "clarity" worlds if you use currying: interpcut[r_][x_] := ...first definition... –  WReach Dec 18 '10 at 19:52
@WReach That is the virtue and the curse of Mma - There is always another (right) way ... –  belisarius Dec 19 '10 at 3:18
show 1 more comment

Here's a possible alternative to belisarius's answer:

interpcut[r_] := Module[{s}, s = SortBy[r, First];
Composition[Interpolation[r], Clip[#, Map[First, Through[{First, Last}[s]]]] &]]
-
Code golf rocks! "interpcut[r_] := Composition[Interpolation[r], Clip[#, Map[First, Through[{First, Last}[SortBy[r,First]]]]] &]" (look ma, no module!) –  barrycarter Dec 28 '10 at 18:27
@barry: Code golf is indeed a nice game to play in Mathematica... :) –  user414706 Dec 29 '10 at 0:43
@barrycarter we can do a bit better than that: interpcut[r_]:=Interpolation[r][#~Clip~SortBy[dat,First][[{1,-1},1]]]& –  Mr.Wizard Nov 25 '11 at 15:56