Roots of a function: Difference between revisions
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By itself (i.e. unless specifically asked to do so), Maple will only perform exact (symbolic) operations and not attempt to do any kind of numerical approximation. |
By itself (i.e. unless specifically asked to do so), Maple will only perform exact (symbolic) operations and not attempt to do any kind of numerical approximation. |
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=={{header|Mathematica}}== |
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There are multiple obvious ways to do this in Mathematica. |
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===Solve=== |
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This requires a full equation and will perform symbolic operations only: |
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In[1]:= Solve[x^3-3*x^2+2*x==0,x] |
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Out[1]= {{x->0},{x->1},{x->2}} |
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===NSolve=== |
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This requires merely the polynomial and will perform numerical operations if needed: |
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In[2]:= NSolve[x^3 - 3*x^2 + 2*x , x] |
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Out[2]= {{x->0.},{x->1.},{x->2.}} |
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(note that the results here are floats) |
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===FindRoot=== |
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This will numerically try to find one(!) local root from a given starting point: |
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In[3]:= FindRoot[x^3 - 3*x^2 + 2*x , {x, 1.5}] |
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Out[3]= {x->0.} |
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In[4]:= FindRoot[x^3 - 3*x^2 + 2*x , {x, 1.1}] |
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Out[4]= {x->1.} |
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(note that there is no guarantee which one is found). |
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===FindInstance=== |
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This finds a value (optionally out of a given domain) for the given variable (or a set of values for a set of given variables) that satisfy a given equality or inequality: |
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In[5]:= FindInstance[x^3 - 3*x^2 + 2*x == 0, x] |
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Out[5]= {{x->0}} |
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===Reduce=== |
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This will (symbolically) reduce a given expression to the simplest possible form, solving equations and performing substitutions in the process: |
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In[6]:= Reduce[x^3 - 3*x^2 + 2*x == 0, x] |
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Out[6]= x==0||x==1||x==2 |
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(note that this doesn't yield a "solution" but a different expression that expresses the same thing as the original) |
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=={{header|Perl}}== |
=={{header|Perl}}== |
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Revision as of 19:48, 26 March 2008
You are encouraged to solve this task according to the task description, using any language you may know.
Create a program that finds and outputs the roots of a given function, range and (if applicable) step width. The program should identify whether the root is exact or approximate.
For this example, use f(x)=x^3-3x^2+2x.
Ada
with Ada.Text_Io; use Ada.Text_Io;
procedure Roots_Of_Function is
package Real_Io is new Ada.Text_Io.Float_Io(Long_Float);
use Real_Io;
function F(X : Long_Float) return Long_Float is
begin
return (X**3 - 3.0*X*X + 2.0*X);
end F;
Step : constant Long_Float := 1.0E-6;
Start : constant Long_Float := -1.0;
Stop : constant Long_Float := 3.0;
Value : Long_Float := F(Start);
Sign : Boolean := Value > 0.0;
X : Long_Float := Start + Step;
begin
if Value = 0.0 then
Put("Root found at ");
Put(Item => Start, Fore => 1, Aft => 6, Exp => 0);
New_Line;
end if;
while X <= Stop loop
Value := F(X);
if (Value > 0.0) /= Sign then
Put("Root found near ");
Put(Item => X, Fore => 1, Aft => 6, Exp => 0);
New_Line;
elsif Value = 0.0 then
Put("Root found at ");
Put(Item => X, Fore => 1, Aft => 6, Exp => 0);
New_Line;
end if;
Sign := Value > 0.0;
X := X + Step;
end loop;
end Roots_Of_Function;
C++
#include <iostream>
double f(double x)
{
return (x*x*x - 3*x*x + 2*x);
}
int main()
{
double step = 0.001; // Smaller step values produce more accurate and precise results
double start = -1;
double stop = 3;
double value = f(start);
double sign = (value > 0);
// Check for root at start
if ( 0 == value )
std::cout << "Root found at " << start << std::endl;
for( double x = start + step;
x <= stop;
x += step )
{
value = f(x);
if ( ( value > 0 ) != sign )
// We passed a root
std::cout << "Root found near " << x << std::endl;
else if ( 0 == value )
// We hit a root
std::cout << "Root found at " << x << std::endl;
// Update our sign
sign = ( value > 0 );
}
}
D
module findroot ;
import std.stdio ;
import std.math ;
void report(T)(T[] r, T function(T) f, T tolerance = cast(T) 1e-4L) {
if (r.length) {
writefln("Root found (tolerance = %1.4g) :", tolerance) ;
foreach(x ; r) {
T y = f(x) ;
if (nearZero(y))
writefln("... EXACTLY at %+1.20f, f(x) = %+1.4g", x, y) ;
else if (nearZero(y, tolerance))
writefln(".... MAY-BE at %+1.20f, f(x) = %+1.4g", x, y) ;
else
writefln("Verify needed, f(%1.4g) = %1.4g > tolerance in magnitude", x, y) ;
}
} else
writefln("No root found.") ;
}
bool nearZero(T)(T a, T b = T.epsilon * 4) { return abs(a) <= b ; }
T[] findroot(T)(T function(T) f, T start, T end, T step = cast(T) 0.001L,
T tolerance = cast(T) 1e-4L) {
T[T] result ;
if (nearZero(step))
writefln("WARNING: step size may be too small.") ;
T searchRoot(T a, T b) { // search root by simple bisection
T root ;
int limit = 49 ;
T gap = b - a ;
while (!nearZero(gap) && limit--) {
if (nearZero(f(a))) return a ;
if (nearZero(f(b))) return b ;
root = (b + a)/2.0L ;
if (nearZero(f(root))) return root ;
if (f(a) * f(root) < 0)
b = root ;
else
a = root ;
gap = b - a ;
}
return root ;
}
T dir = cast(T) (end > start ? 1.0 : -1.0) ;
step = (end > start) ? abs(step) : - abs(step) ;
for(T x = start ; x*dir <= end*dir ; x = x + step)
if (f(x)*f(x + step) <= 0) {
T r = searchRoot(x, x+ step) ;
result[r] = f(r) ;
}
return result.keys.sort ; // reduce duplacated root, if any
}
real f(real x){
return x*x*x - 3*x*x + 2*x ;
}
void main(){
findroot(&f, -1.0L, 3.0L, 0.001L).report(&f) ;
}
Output ( NB:smallest increment for real type in D is real.epsilon = 1.0842e-19 ):
Root found (tolerance = 0.0001) : .... MAY-BE at -0.00000000000000000080, f(x) = -1.603e-18 ... EXACTLY at +1.00000000000000000020, f(x) = -2.168e-19 .... MAY-BE at +1.99999999999999999950, f(x) = -8.674e-19
Maple
f := x^3-3*x^2+2*x; roots(f,x);
outputs:
[[0, 1], [1, 1], [2, 1]]
which means there are three roots. Each root is named as a pair where the first element is the value (0, 1, and 2), the second one the multiplicity (=1 for each means none of the three are degenerate).
By itself (i.e. unless specifically asked to do so), Maple will only perform exact (symbolic) operations and not attempt to do any kind of numerical approximation.
Mathematica
There are multiple obvious ways to do this in Mathematica.
Solve
This requires a full equation and will perform symbolic operations only:
In[1]:= Solve[x^3-3*x^2+2*x==0,x]
Out[1]= {{x->0},{x->1},{x->2}}
NSolve
This requires merely the polynomial and will perform numerical operations if needed:
In[2]:= NSolve[x^3 - 3*x^2 + 2*x , x]
Out[2]= {{x->0.},{x->1.},{x->2.}}
(note that the results here are floats)
FindRoot
This will numerically try to find one(!) local root from a given starting point:
In[3]:= FindRoot[x^3 - 3*x^2 + 2*x , {x, 1.5}]
Out[3]= {x->0.}
In[4]:= FindRoot[x^3 - 3*x^2 + 2*x , {x, 1.1}]
Out[4]= {x->1.}
(note that there is no guarantee which one is found).
FindInstance
This finds a value (optionally out of a given domain) for the given variable (or a set of values for a set of given variables) that satisfy a given equality or inequality:
In[5]:= FindInstance[x^3 - 3*x^2 + 2*x == 0, x]
Out[5]= {{x->0}}
Reduce
This will (symbolically) reduce a given expression to the simplest possible form, solving equations and performing substitutions in the process:
In[6]:= Reduce[x^3 - 3*x^2 + 2*x == 0, x] Out[6]= x==0||x==1||x==2
(note that this doesn't yield a "solution" but a different expression that expresses the same thing as the original)
Perl
sub f
{
my $x = shift;
return ($x * $x * $x - 3*$x*$x + 2*$x);
}
my $step = 0.001; # Smaller step values produce more accurate and precise results
my $start = -1;
my $stop = 3;
my $value = &f($start);
my $sign = $value > 0;
# Check for root at start
print "Root found at $start\n" if ( 0 == $value );
for( my $x = $start + $step;
$x <= $stop;
$x += $step )
{
$value = &f($x);
if ( 0 == $value )
{
# We hit a root
print "Root found at $x\n";
}
elsif ( ( $value > 0 ) != $sign )
{
# We passed a root
print "Root found near $x\n";
}
# Update our sign
$sign = ( $value > 0 );
}