Averages/Pythagorean means: Difference between revisions
→{{header|VBA}}: excel has a built-in harmonic mean ... |
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End Function |
End Function |
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Private Function harmonic_mean(s() As Variant) As Double |
Private Function harmonic_mean(s() As Variant) As Double |
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harmonic_mean = WorksheetFunction.HarMean(s) |
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s(i) = 1 / s(i) |
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Next i |
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harmonic_mean = UBound(s) / WorksheetFunction.sum(s) |
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End Function |
End Function |
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Public Sub pythagorean_means() |
Public Sub pythagorean_means() |
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G = 4,52872868811677 |
G = 4,52872868811677 |
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H = 3,41417152147406 </pre> |
H = 3,41417152147406 </pre> |
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=={{header|VBScript}}== |
=={{header|VBScript}}== |
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<lang vb> |
<lang vb> |
Revision as of 18:28, 28 January 2019
You are encouraged to solve this task according to the task description, using any language you may know.
Compute all three of the Pythagorean means of the set of integers 1 through 10 (inclusive).
Show that for this set of positive integers.
- The most common of the three means, the arithmetic mean, is the sum of the list divided by its length:
- The geometric mean is the th root of the product of the list:
- The harmonic mean is divided by the sum of the reciprocal of each item in the list:
|
11l
<lang 11l>F amean(num)
R sum(num)/Float(num.len)
F gmean(num)
R product(num) ^ (1.0/num.len)
F hmean(num)
return num.len / sum(num.map(n -> 1.0/n))
V numbers = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10] print(amean(numbers)) print(gmean(numbers)) print(hmean(numbers))</lang>
- Output:
5.5 4.52873 3.41417
ActionScript
<lang ActionScript>function arithmeticMean(v:Vector.<Number>):Number { var sum:Number = 0; for(var i: uint = 0; i < v.length; i++) sum += v[i]; return sum/v.length; } function geometricMean(v:Vector.<Number>):Number { var product:Number = 1; for(var i: uint = 0; i < v.length; i++) product *= v[i]; return Math.pow(product, 1/v.length); } function harmonicMean(v:Vector.<Number>):Number { var sum:Number = 0; for(var i: uint = 0; i < v.length; i++) sum += 1/v[i]; return v.length/sum; } var list:Vector.<Number> = Vector.<Number>([1,2,3,4,5,6,7,8,9,10]); trace("Arithmetic: ", arithmeticMean(list)); trace("Geometric: ", geometricMean(list)); trace("Harmonic: ", harmonicMean(list));</lang>
Ada
pythagorean_means.ads: <lang Ada>package Pythagorean_Means is
type Set is array (Positive range <>) of Float; function Arithmetic_Mean (Data : Set) return Float; function Geometric_Mean (Data : Set) return Float; function Harmonic_Mean (Data : Set) return Float;
end Pythagorean_Means;</lang>
pythagorean_means.adb: <lang Ada>with Ada.Numerics.Generic_Elementary_Functions; package body Pythagorean_Means is
package Math is new Ada.Numerics.Generic_Elementary_Functions (Float); function "**" (Left, Right : Float) return Float renames Math."**";
function Arithmetic_Mean (Data : Set) return Float is Sum : Float := 0.0; begin for I in Data'Range loop Sum := Sum + Data (I); end loop; return Sum / Float (Data'Length); end Arithmetic_Mean;
function Geometric_Mean (Data : Set) return Float is Product : Float := 1.0; begin for I in Data'Range loop Product := Product * Data (I); end loop; return Product**(1.0/Float(Data'Length)); end Geometric_Mean;
function Harmonic_Mean (Data : Set) return Float is Reciprocal_Sum : Float := 0.0; begin for I in Data'Range loop Reciprocal_Sum := Reciprocal_Sum + Data (I)**(-1); end loop; return Float (Data'Length) / Reciprocal_Sum; end Harmonic_Mean;
end Pythagorean_Means;</lang>
example main.adb: <lang Ada>with Ada.Text_IO; with Pythagorean_Means; procedure Main is
My_Set : Pythagorean_Means.Set := (1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0); Arithmetic_Mean : Float := Pythagorean_Means.Arithmetic_Mean (My_Set); Geometric_Mean : Float := Pythagorean_Means.Geometric_Mean (My_Set); Harmonic_Mean : Float := Pythagorean_Means.Harmonic_Mean (My_Set);
begin
Ada.Text_IO.Put_Line (Float'Image (Arithmetic_Mean) & " >= " & Float'Image (Geometric_Mean) & " >= " & Float'Image (Harmonic_Mean));
end Main;</lang>
ALGOL 68
<lang algol68>main: (
INT count:=0; LONG REAL f, sum:=0, prod:=1, resum:=0;
FORMAT real = $g(0,4)$; # preferred real format #
FILE fbuf; STRING sbuf; associate(fbuf,sbuf);
BOOL opts := TRUE;
FOR i TO argc DO IF opts THEN # skip args up to the - token # opts := argv(i) NE "-" ELSE rewind(fbuf); sbuf := argv(i); get(fbuf,f); count +:= 1; sum +:= f; prod *:= f; resum +:= 1/f FI OD; printf(($"c: "f(real)l"s: "f(real)l"p: "f(real)l"r: "f(real)l$,count,sum,prod,resum)); printf(($"Arithmetic mean = "f(real)l$,sum/count)); printf(($"Geometric mean = "f(real)l$,prod**(1/count))); printf(($"Harmonic mean = "f(real)l$,count/resum))
)</lang> Lunix command:
a68g Averages_Pythagorean_means.a68 - 1 2 3 4 5 6 7 8 9 10
- Output:
c: 10.0000 s: 55.0000 p: 3628800.0000 r: 2.9290 Arithmetic mean = 5.5000 Geometric mean = 4.5287 Harmonic mean = 3.4142
ALGOL W
<lang algolw>begin
% returns the arithmetic mean of the elements of n from lo to hi % real procedure arithmeticMean ( real array n ( * ); integer value lo, hi ) ; begin real sum; sum := 0; for i := lo until hi do sum := sum + n( i ); sum / ( 1 + ( hi - lo ) ) end arithmeticMean ; % returns the geometric mean of the elements of n from lo to hi % real procedure geometricMean ( real array n ( * ); integer value lo, hi ) ; begin real product; product := 1; for i := lo until hi do product := product * n( i ); exp( ln( product ) / ( 1 + ( hi - lo ) ) ) end geometricMean ; % returns the harminic mean of the elements of n from lo to hi % real procedure harmonicMean ( real array n ( * ); integer value lo, hi ) ; begin real sum; sum := 0; for i := lo until hi do sum := sum + ( 1 / n( i ) ); ( 1 + ( hi - lo ) ) / sum end harmonicMean ;
real array v ( 1 :: 10 ); for i := 1 until 10 do v( i ) := i;
r_w := 10; r_d := 5; r_format := "A"; s_w := 0; % set output format %
write( "Arithmetic mean: ", arithmeticMean( v, 1, 10 ) ); write( "Geometric mean: ", geometricMean( v, 1, 10 ) ); write( "Harmonic mean: ", harmonicMean( v, 1, 10 ) )
end.</lang>
- Output:
Arithmetic mean: 5.50000 Geometric mean: 4.52872 Harmonic mean: 3.41417
APL
<lang APL>
arithmetic←{(+/⍵)÷⍴⍵} geometric←{(×/⍵)*÷⍴⍵} harmonic←{(⍴⍵)÷(+/÷⍵)}
x←⍳10
arithmetic x
5.5
geometric x
4.528728688
harmonic x
3.414171521</lang>
AppleScript
<lang AppleScript>-- arithmetic_mean :: [Number] -> Number on arithmetic_mean(xs)
-- sum :: Number -> Number -> Number script sum on |λ|(accumulator, x) accumulator + x end |λ| end script foldl(sum, 0, xs) / (length of xs)
end arithmetic_mean
-- geometric_mean :: [Number] -> Number on geometric_mean(xs)
-- product :: Number -> Number -> Number script product on |λ|(accumulator, x) accumulator * x end |λ| end script foldl(product, 1, xs) ^ (1 / (length of xs))
end geometric_mean
-- harmonic_mean :: [Number] -> Number on harmonic_mean(xs)
-- addInverse :: Number -> Number -> Number script addInverse on |λ|(accumulator, x) accumulator + (1 / x) end |λ| end script (length of xs) / (foldl(addInverse, 0, xs))
end harmonic_mean
-- TEST ----------------------------------------------------------------------- on run
set {A, G, H} to ap({arithmetic_mean, geometric_mean, harmonic_mean}, ¬ Template:1, 2, 3, 4, 5, 6, 7, 8, 9, 10) {values:{arithmetic:A, geometric:G, harmonic:H}, inequalities:¬end run -- GENERIC FUNCTIONS ---------------------------------------------------------- -- A list of functions applied to a list of arguments -- (<*> | ap) :: [(a -> b)] -> [a] -> [b] on ap(fs, xs) set {nf, nx} to {length of fs, length of xs} set acc to {} repeat with i from 1 to nf tell mReturn(item i of fs) repeat with j from 1 to nx set end of acc to |λ|(contents of (item j of xs)) end repeat end tell end repeat return acc end ap -- foldl :: (a -> b -> a) -> a -> [b] -> a on foldl(f, startValue, xs) tell mReturn(f) set v to startValue set lng to length of xs repeat with i from 1 to lng set v to |λ|(v, item i of xs, i, xs) end repeat return v end tell end foldl -- map :: (a -> b) -> [a] -> [b] on map(f, xs) tell mReturn(f) set lng to length of xs set lst to {} repeat with i from 1 to lng set end of lst to |λ|(item i of xs, i, xs) end repeat return lst end tell end map -- Lift 2nd class handler function into 1st class script wrapper -- mReturn :: Handler -> Script on mReturn(f) if class of f is script then f else script property |λ| : f end script end if end mReturn</lang>
- Output:
<lang AppleScript>{values:{arithmetic:5.5, geometric:4.528728688117, harmonic:3.414171521474}, inequalities:{|A >= G|:true}, |G >= H|:true}</lang>
AutoHotkey
<lang autohotkey>A := ArithmeticMean(1, 10) G := GeometricMean(1, 10) H := HarmonicMean(1, 10)
If G Between %H% And %A%
Result := "True"
Else
Result := "False"
MsgBox, %A%`n%G%`n%H%`n%Result%
- ---------------------------------------------------------------------------
ArithmeticMean(a, b) { ; of integers a through b
- ---------------------------------------------------------------------------
n := b - a + 1 Loop, %n% Sum += (a + A_Index - 1) Return, Sum / n
}
- ---------------------------------------------------------------------------
GeometricMean(a, b) { ; of integers a through b
- ---------------------------------------------------------------------------
n := b - a + 1 Prod := 1 Loop, %n% Prod *= (a + A_Index - 1) Return, Prod ** (1 / n)
}
- ---------------------------------------------------------------------------
HarmonicMean(a, b) { ; of integers a through b
- ---------------------------------------------------------------------------
n := b - a + 1 Loop, %n% Sum += 1 / (a + A_Index - 1) Return, n / Sum
}</lang> Message box shows:
5.500000 4.528729 3.414172 True
AWK
<lang awk>#!/usr/bin/awk -f {
x = $1; # value of 1st column A += x; G += log(x); H += 1/x; N++;
}
END {
print "Arithmethic mean: ",A/N; print "Geometric mean : ",exp(G/N); print "Harmonic mean : ",N/H;
}</lang>
BBC BASIC
The arithmetic and harmonic means use BBC BASIC's built-in array operations; only the geometric mean needs a loop. <lang bbcbasic> DIM a(9)
a() = 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 PRINT "Arithmetic mean = " ; FNarithmeticmean(a()) PRINT "Geometric mean = " ; FNgeometricmean(a()) PRINT "Harmonic mean = " ; FNharmonicmean(a()) END DEF FNarithmeticmean(a()) = SUM(a()) / (DIM(a(),1)+1) DEF FNgeometricmean(a()) LOCAL a, I% a = 1 FOR I% = 0 TO DIM(a(),1) a *= a(I%) NEXT = a ^ (1/(DIM(a(),1)+1)) DEF FNharmonicmean(a()) LOCAL b() DIM b(DIM(a(),1)) b() = 1/a() = (DIM(a(),1)+1) / SUM(b())
</lang>
- Output:
Arithmetic mean = 5.5 Geometric mean = 4.52872869 Harmonic mean = 3.41417152
C
<lang c>#include <stdio.h>
- include <stdlib.h> // atoi()
- include <math.h> // pow()
int main(int argc, char* argv[]) {
int i, count=0; double f, sum=0.0, prod=1.0, resum=0.0;
for (i=1; i<argc; ++i) { f = atof(argv[i]); count++; sum += f; prod *= f; resum += (1.0/f); } //printf(" c:%d\n s:%f\n p:%f\n r:%f\n",count,sum,prod,resum); printf("Arithmetic mean = %f\n",sum/count); printf("Geometric mean = %f\n",pow(prod,(1.0/count))); printf("Harmonic mean = %f\n",count/resum);
return 0;
}</lang>
C++
<lang cpp>#include <vector>
- include <iostream>
- include <numeric>
- include <cmath>
- include <algorithm>
double toInverse ( int i ) {
return 1.0 / i ;
}
int main( ) {
std::vector<int> numbers ; for ( int i = 1 ; i < 11 ; i++ ) numbers.push_back( i ) ; double arithmetic_mean = std::accumulate( numbers.begin( ) , numbers.end( ) , 0 ) / 10.0 ; double geometric_mean = pow( std::accumulate( numbers.begin( ) , numbers.end( ) , 1 , std::multiplies<int>( ) ), 0.1 ) ; std::vector<double> inverses ; inverses.resize( numbers.size( ) ) ; std::transform( numbers.begin( ) , numbers.end( ) , inverses.begin( ) , toInverse ) ; double harmonic_mean = 10 / std::accumulate( inverses.begin( ) , inverses.end( ) , 0.0 ); //initial value of accumulate must be a double! std::cout << "The arithmetic mean is " << arithmetic_mean << " , the geometric mean " << geometric_mean << " and the harmonic mean " << harmonic_mean << " !\n" ; return 0 ;
}</lang>
- Output:
The arithmetic mean is 5.5 , the geometric mean 4.52873 and the harmonic mean 3.41417 !
C#
The standard Linq extension method Average provides arithmetic mean. This example adds two more extension methods for the geometric and harmonic means.
<lang csharp>using System; using System.Collections.Generic; using System.Diagnostics; using System.Linq;
namespace PythMean {
static class Program { static void Main(string[] args) { var nums = from n in Enumerable.Range(1, 10) select (double)n;
var a = nums.Average(); var g = nums.Gmean(); var h = nums.Hmean();
Console.WriteLine("Arithmetic mean {0}", a); Console.WriteLine("Geometric mean {0}", g); Console.WriteLine("Harmonic mean {0}", h);
Debug.Assert(a >= g && g >= h); }
// Geometric mean extension method. static double Gmean(this IEnumerable<double> n) { return Math.Pow(n.Aggregate((s, i) => s * i), 1.0 / n.Count()); }
// Harmonic mean extension method. static double Hmean(this IEnumerable<double> n) { return n.Count() / n.Sum(i => 1.0 / i); } }
}</lang>
- Output:
Arithmetic mean 5.5 Geometric mean 4.52872868811677 Harmonic mean 3.41417152147406
CoffeeScript
<lang coffeescript>a = [ 1..10 ] arithmetic_mean = (a) -> a.reduce(((s, x) -> s + x), 0) / a.length geometic_mean = (a) -> Math.pow(a.reduce(((s, x) -> s * x), 1), (1 / a.length)) harmonic_mean = (a) -> a.length / a.reduce(((s, x) -> s + 1 / x), 0)
A = arithmetic_mean a G = geometic_mean a H = harmonic_mean a
console.log "A = ", A, " G = ", G, " H = ", H console.log "A >= G : ", A >= G, " G >= H : ", G >= H</lang>
- Output:
A = 5.5 G = 4.528728688116765 H = 3.414171521474055 A >= G : true G >= H : true
Common Lisp
<lang lisp>(defun generic-mean (nums reduce-op final-op)
(funcall final-op (reduce reduce-op nums)))
(defun a-mean (nums)
(generic-mean nums #'+ (lambda (x) (/ x (length nums)))))
(defun g-mean (nums)
(generic-mean nums #'* (lambda (x) (expt x (/ 1 (length nums))))))
(defun h-mean (nums)
(generic-mean nums (lambda (x y) (+ x (/ 1 y))) (lambda (x) (/ (length nums) x))))
(let ((numbers (loop for i from 1 to 10 collect i)))
(let ((a-mean (a-mean numbers)) (g-mean (g-mean numbers)) (h-mean (h-mean numbers))) (assert (> a-mean g-mean h-mean)) (format t "a-mean ~a~%" a-mean) (format t "g-mean ~a~%" g-mean) (format t "h-mean ~a~%" h-mean)))</lang>
Clojure
<lang Clojure>(use '[clojure.contrib.math :only (expt)])
(defn a-mean [coll]
(/ (apply + coll) (count coll)))
(defn g-mean [coll]
(expt (apply * coll) (/ (count coll))))
(defn h-mean [coll]
(/ (count coll) (apply + (map / coll))))
(let [numbers (range 1 11)
a (a-mean numbers) g (g-mean numbers) h (h-mean numbers)] (println a ">=" g ">=" h) (>= a g h))</lang>
D
The output for the harmonic mean is wrong. <lang d>import std.stdio, std.algorithm, std.range, std.functional;
auto aMean(T)(T data) pure nothrow @nogc {
return data.sum / data.length;
}
auto gMean(T)(T data) pure /*@nogc*/ {
return data.reduce!q{a * b} ^^ (1.0 / data.length);
}
auto hMean(T)(T data) pure /*@nogc*/ {
return data.length / data.reduce!q{ 1.0 / a + b };
}
void main() {
immutable m = [adjoin!(hMean, gMean, aMean)(iota(1.0L, 11.0L))[]]; writefln("%(%.19f %)", m); assert(m.isSorted);
}</lang>
- Output:
0.9891573712076470036 4.5287286881167647619 5.5000000000000000000
Delphi
<lang Delphi>program AveragesPythagoreanMeans;
{$APPTYPE CONSOLE}
uses Types, Math;
function ArithmeticMean(aArray: TDoubleDynArray): Double; var
lValue: Double;
begin
Result := 0; for lValue in aArray do Result := Result + lValue; if Result > 0 then Result := Result / Length(aArray);
end;
function GeometricMean(aArray: TDoubleDynArray): Double; var
lValue: Double;
begin
Result := 1; for lValue in aArray do Result := Result * lValue; Result := Power(Result, 1 / Length(aArray));
end;
function HarmonicMean(aArray: TDoubleDynArray): Double; var
lValue: Double;
begin
Result := 0; for lValue in aArray do Result := Result + 1 / lValue; Result := Length(aArray) / Result;
end;
var
lSourceArray: TDoubleDynArray; AMean, GMean, HMean: Double;
begin
lSourceArray := TDoubleDynArray.Create(1,2,3,4,5,6,7,8,9,10); AMean := ArithmeticMean(lSourceArray)); GMean := GeometricMean(lSourceArray)); HMean := HarmonicMean(lSourceArray)); if (AMean >= GMean) and (GMean >= HMean) then Writeln(AMean, " ≥ ", GMean, " ≥ ", HMean) else writeln("Error!");
end.</lang>
E
Given that we're defining all three together, it makes sense to express their regularities:
<lang e>def makeMean(base, include, finish) {
return def mean(numbers) { var count := 0 var acc := base for x in numbers { acc := include(acc, x) count += 1 } return finish(acc, count) }
}
def A := makeMean(0, fn b,x { b+x }, fn acc,n { acc / n }) def G := makeMean(1, fn b,x { b*x }, fn acc,n { acc ** (1/n) }) def H := makeMean(0, fn b,x { b+1/x }, fn acc,n { n / acc })</lang>
<lang e>? A(1..10)
- value: 5.5
? G(1..10)
- value: 4.528728688116765
? H(1..10)
- value: 3.414171521474055</lang>
EchoLisp
<lang scheme> (define (A xs) (// (for/sum ((x xs)) x) (length xs)))
(define (G xs) (expt (for/product ((x xs)) x) (// (length xs))))
(define (H xs) (// (length xs) (for/sum ((x xs)) (// x))))
(define xs (range 1 11)) (and (>= (A xs) (G xs)) (>= (G xs) (H xs)))
→ #t
</lang>
Elixir
<lang elixir>defmodule Means do
def arithmetic(list) do Enum.sum(list) / length(list) end def geometric(list) do :math.pow(Enum.reduce(list, &(*/2)), 1 / length(list)) end def harmonic(list) do 1 / arithmetic(Enum.map(list, &(1 / &1))) end
end
list = Enum.to_list(1..10) IO.puts "Arithmetic mean: #{am = Means.arithmetic(list)}" IO.puts "Geometric mean: #{gm = Means.geometric(list)}" IO.puts "Harmonic mean: #{hm = Means.harmonic(list)}" IO.puts "(#{am} >= #{gm} >= #{hm}) is #{am >= gm and gm >= hm}"</lang>
- Output:
Arithmetic mean: 5.5 Geometric mean: 4.528728688116765 Harmonic mean: 3.414171521474055 (5.5 >= 4.528728688116765 >= 3.414171521474055) is true
Erlang
<lang Erlang>%% Author: Abhay Jain <abhay_1303@yahoo.co.in>
-module(mean_calculator). -export([find_mean/0]).
find_mean() -> %% This is function calling. First argument is the the beginning number %% and second argument is the initial value of sum for AM & HM and initial value of product for GM. arithmetic_mean(1, 0), geometric_mean(1, 1), harmonic_mean(1, 0).
%% Function to calculate Arithmetic Mean arithmetic_mean(Number, Sum) when Number > 10 -> AM = Sum / 10, io:format("Arithmetic Mean ~p~n", [AM]); arithmetic_mean(Number, Sum) -> NewSum = Sum + Number, arithmetic_mean(Number+1, NewSum).
%% Function to calculate Geometric Mean geometric_mean(Number, Product) when Number > 10 -> GM = math:pow(Product, 0.1), io:format("Geometric Mean ~p~n", [GM]); geometric_mean(Number, Product) -> NewProd = Product * Number, geometric_mean(Number+1, NewProd).
%% Function to calculate Harmonic Mean harmonic_mean(Number, Sum) when Number > 10 -> HM = 10 / Sum, io:format("Harmonic Mean ~p~n", [HM]); harmonic_mean(Number, Sum) -> NewSum = Sum + (1/Number), harmonic_mean(Number+1, NewSum). </lang>
- Output:
Arithmetic Mean 5.5 Geometric Mean 4.528728688116765 Harmonic Mean 3.414171521474055
ERRE
<lang> PROGRAM MEANS
DIM A[9]
PROCEDURE ARITHMETIC_MEAN(A[]->M)
LOCAL S,I% NEL%=UBOUND(A,1) S=0 FOR I%=0 TO NEL% DO S+=A[I%] END FOR M=S/(NEL%+1)
END PROCEDURE
PROCEDURE GEOMETRIC_MEAN(A[]->M)
LOCAL S,I% NEL%=UBOUND(A,1) S=1 FOR I%=0 TO NEL% DO S*=A[I%] END FOR M=S^(1/(NEL%+1))
END PROCEDURE
PROCEDURE HARMONIC_MEAN(A[]->M)
LOCAL S,I% NEL%=UBOUND(A,1) S=0 FOR I%=0 TO NEL% DO S+=1/A[I%] END FOR M=(NEL%+1)/S
END PROCEDURE
BEGIN
A[]=(1,2,3,4,5,6,7,8,9,10) ARITHMETIC_MEAN(A[]->M) PRINT("Arithmetic mean = ";M) GEOMETRIC_MEAN(A[]->M) PRINT("Geometric mean = ";M) HARMONIC_MEAN(A[]->M) PRINT("Harmonic mean = ";M)
END PROGRAM </lang>
Euler Math Toolbox
<lang Euler Math Toolbox> >function A(x) := mean(x) >function G(x) := exp(mean(log(x))) >function H(x) := 1/mean(1/x) >x=1:10; A(x), G(x), H(x)
5.5 4.52872868812 3.41417152147
</lang>
Alternatively, e.g.,
<lang Euler Math Toolbox> >function G(x) := prod(x)^(1/length(x)) </lang>
Euphoria
<lang euphoria>function arithmetic_mean(sequence s)
atom sum if length(s) = 0 then return 0 else sum = 0 for i = 1 to length(s) do sum += s[i] end for return sum/length(s) end if
end function
function geometric_mean(sequence s)
atom p p = 1 for i = 1 to length(s) do p *= s[i] end for return power(p,1/length(s))
end function
function harmonic_mean(sequence s)
atom sum if length(s) = 0 then return 0 else sum = 0 for i = 1 to length(s) do sum += 1/s[i] end for return length(s) / sum end if
end function
function true_or_false(atom x)
if x then return "true" else return "false" end if
end function
constant s = {1,2,3,4,5,6,7,8,9,10} constant arithmetic = arithmetic_mean(s),
geometric = geometric_mean(s), harmonic = harmonic_mean(s)
printf(1,"Arithmetic: %g\n", arithmetic) printf(1,"Geometric: %g\n", geometric) printf(1,"Harmonic: %g\n", harmonic) printf(1,"Arithmetic>=Geometric>=Harmonic: %s\n",
{true_or_false(arithmetic>=geometric and geometric>=harmonic)})</lang>
- Output:
Arithmetic: 5.5 Geometric: 4.52873 Harmonic: 3.41417 Arithmetic>=Geometric>=Harmonic: true
Excel
Use the functions : AVERAGE, GEOMEAN and HARMEAN
<lang Excel> =AVERAGE(1;2;3;4;5;6;7;8;9;10) =GEOMEAN(1;2;3;4;5;6;7;8;9;10) =HARMEAN(1;2;3;4;5;6;7;8;9;10) </lang>
- Output:
5.5 4.528728688 3,414171521
F#
<lang fsharp>let P = [1.0; 2.0; 3.0; 4.0; 5.0; 6.0; 7.0; 8.0; 9.0; 10.0]
let arithmeticMean (x : float list) =
x |> List.sum
> (fun acc -> acc / float (List.length(x)))
let geometricMean (x: float list) = x |> List.reduce (*) |
> (fun acc -> Math.Pow(acc, 1.0 / (float (List.length(x)))))
let harmonicMean (x: float list) = x |> List.map (fun a -> 1.0 / a) |
> List.sum | > (fun acc -> float (List.length(x)) / acc)
printfn "Arithmetic Mean: %A" (arithmeticMean P) printfn "Geometric Mean: %A" (geometricMean P) printfn "Harmonic Mean: %A" (harmonicMean P)</lang> Factor<lang factor>: a-mean ( seq -- mean ) [ sum ] [ length ] bi / ;
[ product ] [ length recip ] bi ^ ;
[ length ] [ [ recip ] map-sum ] bi / ;</lang> ( scratchpad ) 10 [1,b] [ a-mean ] [ g-mean ] [ h-mean ] tri "%f >= %f >= %f\n" printf 5.500000 >= 4.528729 >= 3.414172 Fantom<lang fantom> class Main { static Float arithmeticMean (Int[] nums) { if (nums.size == 0) return 0.0f sum := 0 nums.each |n| { sum += n } return sum.toFloat / nums.size } static Float geometricMean (Int[] nums) { if (nums.size == 0) return 0.0f product := 1 nums.each |n| { product *= n } return product.toFloat.pow(1f/nums.size) } static Float harmonicMean (Int[] nums) { if (nums.size == 0) return 0.0f reciprocals := 0f nums.each |n| { reciprocals += 1f / n } return nums.size.toFloat / reciprocals } public static Void main () { items := (1..10).toList // display results echo (arithmeticMean (items)) echo (geometricMean (items)) echo (harmonicMean (items)) // check given relation if ((arithmeticMean (items) >= geometricMean (items)) && (geometricMean (items) >= harmonicMean (items))) echo ("relation holds") else echo ("relation failed") } } </lang> Forth<lang forth>: famean ( faddr n -- f ) 0e tuck floats bounds do i f@ f+ float +loop 0 d>f f/ ;
1e tuck floats bounds do i f@ f* float +loop 0 d>f 1/f f** ;
dup 0 d>f 0e floats bounds do i f@ 1/f f+ float +loop f/ ; create test 1e f, 2e f, 3e f, 4e f, 5e f, 6e f, 7e f, 8e f, 9e f, 10e f, test 10 famean fdup f. test 10 fgmean fdup fdup f. test 10 fhmean fdup f. ( A G G H ) f>= . f>= . \ -1 -1</lang> Fortran<lang fortran>program Mean real :: a(10) = (/ (i, i=1,10) /) real :: amean, gmean, hmean amean = sum(a) / size(a) gmean = product(a)**(1.0/size(a)) hmean = size(a) / sum(1.0/a) if ((amean < gmean) .or. (gmean < hmean)) then print*, "Error!" else print*, amean, gmean, hmean end if end program Mean</lang> FreeBASIC<lang freebasic> ' FB 1.05.0 Win64 Function ArithmeticMean(array() As Double) As Double Dim length As Integer = Ubound(array) - Lbound(array) + 1 Dim As Double sum = 0.0 For i As Integer = LBound(array) To UBound(array) sum += array(i) Next Return sum/length End Function Function GeometricMean(array() As Double) As Double Dim length As Integer = Ubound(array) - Lbound(array) + 1 Dim As Double product = 1.0 For i As Integer = LBound(array) To UBound(array) product *= array(i) Next Return product ^ (1.0 / length) End Function Function HarmonicMean(array() As Double) As Double Dim length As Integer = Ubound(array) - Lbound(array) + 1 Dim As Double sum = 0.0 For i As Integer = LBound(array) To UBound(array) sum += 1.0 / array(i) Next Return length / sum End Function Dim vector(1 To 10) As Double For i As Integer = 1 To 10 vector(i) = i Next Print "Arithmetic mean is :"; ArithmeticMean(vector()) Print "Geometric mean is :"; GeometricMean(vector()) Print "Harmonic mean is :"; HarmonicMean(vector()) Print Print "Press any key to quit the program" Sleep </lang>
Arithmetic mean is : 5.5 Geometric mean is : 4.528728688116765 Harmonic mean is : 3.414171521474055 FunL<lang funl>import lists.zip def mean( s, 0 ) = product( s )^(1/s.length()) mean( s, p ) = (1/s.length() sum( x^p | x <- s ))^(1/p) def monotone( [_], _ ) = true monotone( a1:a2:as, p ) = p( a1, a2 ) and monotone( a2:as, p ) means = [mean( 1..10, m ) | m <- [1, 0, -1]] for (m, l) <- zip( means, ['Arithmetic', 'Geometric', 'Harmonic'] ) println( "$l: $m" + (if m is Rational then " or ${m.doubleValue()}" else ) ) println( monotone(means, (>=)) )</lang>
Arithmetic: 11/2 or 5.5 Geometric: 4.528728688116765 Harmonic: 25200/7381 or 3.414171521474055 true Futhark<lang Futhark> fun arithmetic_mean(as: [n]f64): f64 = reduce (+) 0.0 (map (/f64(n)) as) fun geometric_mean(as: [n]f64): f64 = reduce (*) 1.0 (map (**(1.0/f64(n))) as) fun harmonic_mean(as: [n]f64): f64 = f64(n) / reduce (+) 0.0 (map (1.0/) as) fun main(as: [n]f64): (f64,f64,f64) = (arithmetic_mean as, geometric_mean as, harmonic_mean as) </lang> GAP<lang gap># The first two work with rationals or with floats
mean := v -> Sum(v) / Length(v); harmean := v -> Length(v) / Sum(v, Inverse); geomean := v -> EXP_FLOAT(Sum(v, LOG_FLOAT) / Length(v)); mean([1 .. 10]);
harmean([1 .. 10]);
v := List([1..10], FLOAT_INT);; mean(v);
harmean(v);
geomean(v);
Go<lang go>package main import ( "fmt" "math" ) func main() { sum, sumr, prod := 0., 0., 1. for n := 1.; n <= 10; n++ { sum += n sumr += 1 / n prod *= n } a, g, h := sum/10, math.Pow(prod, .1), 10/sumr fmt.Println("A:", a, "G:", g, "H:", h) fmt.Println("A >= G >= H:", a >= g && g >= h) }</lang>
A: 5.5 G: 4.528728688116765 H: 3.414171521474055 A >= G >= H: true GroovySolution: <lang groovy>def arithMean = { list -> list == null \ ? null \ : list.empty \ ? 0 \ : list.sum() / list.size() } def geomMean = { list -> list == null \ ? null \ : list.empty \ ? 1 \ : list.inject(1) { prod, item -> prod*item } ** (1 / list.size()) } def harmMean = { list -> list == null \ ? null \ : list.empty \ ? 0 \ : list.size() / list.collect { 1.0/it }.sum() }</lang> Test: <lang groovy>def list = 1..10 def A = arithMean(list) def G = geomMean(list) assert A >= G def H = harmMean(list) assert G >= H println """ list: ${list} A: ${A} G: ${G} H: ${H} """</lang>
list: [1, 2, 3, 4, 5, 6, 7, 8, 9, 10] A: 5.5 G: 4.528728688116765 H: 3.4141715214 HaskellOne generalized functionThe general function given here yields an arithmetic mean when its first argument is <lang haskell>import Data.List (genericLength) import Control.Monad (zipWithM_) mean :: Double -> [Double] -> Double mean 0 xs = product xs ** (1 / genericLength xs) mean p xs = (1 / genericLength xs * sum (map (** p) xs)) ** (1/p) main = do let ms = zipWith ((. flip mean [1..10]). (,)) "agh" [1, 0, -1] mapM_ (\(t,m) -> putStrLn $ t : ": " ++ show m) ms putStrLn $ " a >= g >= h is " ++ show ((\(_,[a,g,h])-> a>=g && g>=h) (unzip ms))</lang> Three applicatively defined functionsThese three functions (each combining the length of a list with some kind of fold over the elements of that same list), all share the same general liftM2 structure, which can be expressed applicatively as pure f <*> f1 <*> f2 <lang haskell>import Data.List (genericLength) -- ARITHMETIC, GEOMETRIC AND HARMONIC MEANS ----------------------- arithmetic, geometric, harmonic :: [Double] -> Double arithmetic = liftM2 (/) sum genericLength geometric = liftM2 (**) product ((1 /) . genericLength) harmonic = liftM2 (/) genericLength (foldr ((+) . (1 /)) 0) -- GENERIC -------------------------------------------------------- liftM2 f g h = pure f <*> g <*> h -- TEST ----------------------------------------------------------- xs :: [Double] xs = [arithmetic, geometric, harmonic] <*> 1 .. 10 main :: IO () main = (putStrLn . unlines) [ zip ["Arithmetic", "Geometric", "Harmonic"] xs >>= show , mappend "\n A >= G >= H is " $ -- (show . and) $ zipWith (>=) xs (tail xs) ]</lang>
("Arithmetic",5.5)("Geometric",4.528728688116765)("Harmonic",3.414171521474055) a >= g >= h is True HicEst<lang HicEst>AGH = ALIAS( A, G, H ) ! named vector elements AGH = (0, 1, 0) DO i = 1, 10 A = A + i G = G * i H = H + 1/i ENDDO AGH = (A/10, G^0.1, 10/H) WRITE(ClipBoard, Name) AGH, "Result = " // (A>=G) * (G>=H)</lang> |
A=5.5; G=4.528728688; H=3.414171521; Result = 1;
Icon and Unicon<lang Icon>link numbers # for a/g/h means procedure main() every put(x := [], 1 to 10) writes("x := [ "); every writes(!x," "); write("]") write("Arithmetic mean:", a := amean!x) write("Geometric mean:",g := gmean!x) write("Harmonic mean:", h := hmean!x) write(" a >= g >= h is ", if a >= g >= h then "true" else "false") end </lang> numbers:amean, numbers:gmean, and numbers:hmean are shown below: <lang Icon>procedure amean(L[]) #: arithmetic mean local m if *L = 0 then fail m := 0.0 every m +:= !L return m / *L end procedure gmean(L[]) #: geometric mean local m if *L = 0 then fail m := 1.0 every m *:= !L m := abs(m) if m > 0.0 then return exp (log(m) / *L) else fail end procedure hmean(L[]) #: harmonic mean local m, r if *L = 0 then fail m := 0.0 every r := !L do { if r = 0.0 then fail else m +:= 1.0 / r } return *L / m end</lang>
#means.exe x := [ 1 2 3 4 5 6 7 8 9 10 ] Arithmetic mean:5.5 Geometric mean:4.528728688116765 Harmonic mean:3.414171521474055 a >= g >= h is true IS-BASIC<lang IS-BASIC>100 PROGRAM "Averages.bas" 110 NUMERIC ARR(1 TO 10) 120 FOR I=LBOUND(ARR) TO UBOUND(ARR) 130 LET ARR(I)=I 140 NEXT 150 PRINT "Arithmetic mean =";ARITHM(ARR) 160 PRINT "Geometric mean =";GEOMETRIC(ARR) 170 PRINT "Harmonic mean =";HARMONIC(ARR) 180 DEF ARITHM(REF A) 190 LET T=0 200 FOR I=LBOUND(A) TO UBOUND(A) 210 LET T=T+A(I) 220 NEXT 230 LET ARITHM=T/SIZE(A) 240 END DEF 250 DEF GEOMETRIC(REF A) 260 LET T=1 270 FOR I=LBOUND(A) TO UBOUND(A) 280 LET T=T*A(I) 290 NEXT 300 LET GEOMETRIC=T^(1/SIZE(A)) 310 END DEF 320 DEF HARMONIC(REF A) 330 LET T=0 340 FOR I=LBOUND(A) TO UBOUND(A) 350 LET T=T+(1/A(I)) 360 NEXT 370 LET HARMONIC=SIZE(A)/T 380 END DEF</lang> JSolution: <lang j>amean=: +/ % # gmean=: # %: */ hmean=: amean&.:%</lang> Example Usage: <lang j> (amean , gmean , hmean) >: i. 10 5.5 4.528729 3.414172 assert 2 >:/\ (amean , gmean , hmean) >: i. 10 NB. check amean >= gmean and gmean >= hmean</lang> Note that gmean could have instead been defined as mean under logarithm, for example: <lang j>gmean=:amean&.:^.</lang> (and this variant should probably be preferred - especially if the argument list is long, to avoid problems with floating point infinity.) Java<lang java>import java.util.Arrays; import java.util.List; public class PythagoreanMeans { public static double arithmeticMean(List<Double> numbers) { if (numbers.isEmpty()) return Double.NaN; double mean = 0.0; for (Double number : numbers) { mean += number; } return mean / numbers.size(); } public static double geometricMean(List<Double> numbers) { if (numbers.isEmpty()) return Double.NaN; double mean = 1.0; for (Double number : numbers) { mean *= number; } return Math.pow(mean, 1.0 / numbers.size()); } public static double harmonicMean(List<Double> numbers) { if (numbers.isEmpty() || numbers.contains(0.0)) return Double.NaN; double mean = 0.0; for (Double number : numbers) { mean += (1.0 / number); } return numbers.size() / mean; } public static void main(String[] args) { Double[] array = {1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0}; List<Double> list = Arrays.asList(array); double arithmetic = arithmeticMean(list); double geometric = geometricMean(list); double harmonic = harmonicMean(list); System.out.format("A = %f G = %f H = %f%n", arithmetic, geometric, harmonic); System.out.format("A >= G is %b, G >= H is %b%n", (arithmetic >= geometric), (geometric >= harmonic)); } }</lang>
A = 5.500000 G = 4.528729 H = 3.414172 A >= G is true, G >= H is true We can rewrite the 3 methods using the new JAVA Stream API: <lang java> public static double arithmAverage(double array[]){ if (array == null ||array.length == 0) { return 0.0; } else { return DoubleStream.of(array).average().getAsDouble(); } } public static double geomAverage(double array[]){ if (array == null ||array.length == 0) { return 0.0; } else { double aver = DoubleStream.of(array).reduce(1, (x, y) -> x * y); return Math.pow(aver, 1.0 / array.length); } } public static double harmAverage(double array[]){ if (array == null ||array.length == 0) { return 0.0; } else { double aver = DoubleStream.of(array) // remove null values .filter(n -> n > 0.0) // generate 1/n array .map( n-> 1.0/n) // accumulating .reduce(0, (x, y) -> x + y); // just this reduce is not working- need to do in 2 steps // .reduce(0, (x, y) -> 1.0/x + 1.0/y); return array.length / aver ; } } </lang> JavaScriptES5<lang javascript>(function () { 'use strict'; // arithmetic_mean :: [Number] -> Number function arithmetic_mean(ns) { return ( ns.reduce( // sum function (sum, n) { return (sum + n); }, 0 ) / ns.length ); } // geometric_mean :: [Number] -> Number function geometric_mean(ns) { return Math.pow( ns.reduce( // product function (product, n) { return (product * n); }, 1 ), 1 / ns.length ); } // harmonic_mean :: [Number] -> Number function harmonic_mean(ns) { return ( ns.length / ns.reduce( // sum of inverses function (invSum, n) { return (invSum + (1 / n)); }, 0 ) ); } var values = [arithmetic_mean, geometric_mean, harmonic_mean] .map(function (f) { return f([1, 2, 3, 4, 5, 6, 7, 8, 9, 10]); }), mean = { Arithmetic: values[0], // arithmetic Geometric: values[1], // geometric Harmonic: values[2] // harmonic } return JSON.stringify({ values: mean, test: "is A >= G >= H ? " + ( mean.Arithmetic >= mean.Geometric && mean.Geometric >= mean.Harmonic ? "yes" : "no" ) }, null, 2); })(); </lang>
<lang JavaScript>{ "values": { "Arithmetic": 5.5, "Geometric": 4.528728688116765, "Harmonic": 3.414171521474055 }, "test": "is A >= G >= H ? yes" }</lang> ES6<lang JavaScript>(() => { // arithmeticMean :: [Number] -> Number const arithmeticMean = xs => foldl((sum, n) => sum + n, 0, xs) / length(xs); // geometricMean :: [Number] -> Number const geometricMean = xs => raise(foldl((product, x) => product * x, 1, xs), 1 / length(xs)); // harmonicMean :: [Number] -> Number const harmonicMean = xs => length(xs) / foldl((invSum, n) => invSum + (1 / n), 0, xs); // GENERIC FUNCTIONS ------------------------------------------------------ // A list of functions applied to a list of arguments // <*> :: [(a -> b)] -> [a] -> [b] const ap = (fs, xs) => // [].concat.apply([], fs.map(f => // [].concat.apply([], xs.map(x => [f(x)])))); // foldl :: (b -> a -> b) -> b -> [a] -> b const foldl = (f, a, xs) => xs.reduce(f, a); // length :: [a] -> Int const length = xs => xs.length; // mapFromList :: [(k, v)] -> Dictionary const mapFromList = kvs => foldl((a, [k, v]) => (a[(typeof k === 'string' && k) || show(k)] = v, a), {}, kvs); // raise :: Num -> Int -> Num const raise = (n, e) => Math.pow(n, e); // show :: a -> String // show :: a -> Int -> String const show = (...x) => JSON.stringify.apply( null, x.length > 1 ? [x[0], null, x[1]] : x ); // zip :: [a] -> [b] -> [(a,b)] const zip = (xs, ys) => xs.slice(0, Math.min(xs.length, ys.length)) .map((x, i) => [x, ys[i]]); // TEST ------------------------------------------------------------------- // mean :: Dictionary const mean = mapFromList(zip( ['Arithmetic', 'Geometric', 'Harmonic'], ap([arithmeticMean, geometricMean, harmonicMean], [ [1, 2, 3, 4, 5, 6, 7, 8, 9, 10] ]) )); return show({ values: mean, test: `is A >= G >= H ? ${mean.Arithmetic >= mean.Geometric && mean.Geometric >= mean.Harmonic ? "yes" : "no"}` }, 2); })();</lang>
<lang JavaScript>{ "values": { "Arithmetic": 5.5, "Geometric": 4.528728688116765, "Harmonic": 3.414171521474055 }, "test": "is A >= G >= H ? yes" }</lang> jq<lang jq>def amean: add/length; def logProduct: map(log) | add; def gmean: (logProduct / length) | exp; def hmean: length / (map(1/.) | add);
[range(1;11) ] | [amean, gmean, hmean] as $ans |
( $ans[],
"amean > gmean > hmean => \($ans[0] > $ans[1] and $ans[1] > $ans[2] )" ) </lang>
5.5 4.528728688116766 3.414171521474055 "amean > gmean > hmean => true" JuliaJulia has a `mean` function to compute the arithmetic mean of a collections of numbers. We can redefine it as follows. <lang Julia>amean(A) = sum(A)/length(A) gmean(A) = prod(A)^(1/length(A)) hmean(A) = length(A)/sum(1./A)</lang>
julia> map(f-> f(1:10), [amean, gmean, hmean]) 3-element Array{Float64,1}: 5.5 4.52873 3.41417 julia> ans[1] > ans[2] > ans[3] true K<lang K> am:{(+/x)%#x} gm:{(*/x)^(%#x)} hm:{(#x)%+/%:'x} {(am x;gm x;hm x)} 1+!10 5.5 4.528729 3.414172 </lang> Kotlin<lang scala>fun Collection<Double>.geometricMean() = if (isEmpty()) Double.NaN else Math.pow(reduce { n1, n2 -> n1 * n2 }, 1.0 / size) fun Collection<Double>.harmonicMean() = if (isEmpty() || contains(0.0)) Double.NaN else size / reduce { n1, n2 -> n1 + 1.0 / n2 } fun main(args: Array<String>) { val list = listOf(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0) val a = list.average() // arithmetic mean val g = list.geometricMean() val h = list.harmonicMean() println("A = %f G = %f H = %f".format(a, g, h)) println("A >= G is %b, G >= H is %b".format(a >= g, g >= h)) require(g in h..a) }</lang>
A = 5.500000 G = 4.528729 H = 3.414172 A >= G is true, G >= H is true Lasso<lang Lasso>define arithmetic_mean(a::staticarray)::decimal => { //sum of the list divided by its length return (with e in #a sum #e) / decimal(#a->size) } define geometric_mean(a::staticarray)::decimal => { // The geometric mean is the nth root of the product of the list local(prod = 1) with e in #a do => { #prod *= #e } return math_pow(#prod,1/decimal(#a->size)) } define harmonic_mean(a::staticarray)::decimal => { // The harmonic mean is n divided by the sum of the reciprocal of each item in the list return decimal(#a->size)/(with e in #a sum 1/decimal(#e)) } arithmetic_mean(generateSeries(1,10)->asStaticArray) geometric_mean(generateSeries(1,10)->asStaticArray) harmonic_mean(generateSeries(1,10)->asStaticArray)</lang>
5.500000 4.528729 3.414172 Liberty BASIC<lang lb>for i = 1 to 10 a = a + i next ArithmeticMean = a/10 b = 1 for i = 1 to 10 b = b * i next GeometricMean = b ^ (1/10) for i = 1 to 10 c = c + (1/i) next HarmonicMean = 10/c print "ArithmeticMean: ";ArithmeticMean print "Geometric Mean: ";GeometricMean print "Harmonic Mean: ";HarmonicMean if (ArithmeticMean>=GeometricMean) and (GeometricMean>=HarmonicMean) then print "True" else print "False" end if </lang> Logo<lang logo>to compute_means :count local "sum make "sum 0 local "product make "product 1 local "reciprocal_sum make "reciprocal_sum 0 repeat :count [ make "sum sum :sum repcount make "product product :product repcount make "reciprocal_sum sum :reciprocal_sum (quotient repcount) ] output (sentence (quotient :sum :count) (power :product (quotient :count)) (quotient :count :reciprocal_sum)) end make "means compute_means 10 print sentence [Arithmetic mean is] item 1 :means print sentence [Geometric mean is] item 2 :means print sentence [Harmonic mean is] item 3 :means bye</lang> Lua<lang lua>function fsum(f, a, ...) return a and f(a) + fsum(f, ...) or 0 end function pymean(t, f, finv) return finv(fsum(f, unpack(t)) / #t) end nums = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10} --arithmetic a = pymean(nums, function(n) return n end, function(n) return n end) --geometric g = pymean(nums, math.log, math.exp) --harmonic h = pymean(nums, function(n) return 1/n end, function(n) return 1/n end) print(a, g, h) assert(a >= g and g >= h)</lang> M2000 InterpreterDimension(m,0) is the base (lower bound) for each dimension in an array, and can be 0 or 1. Len(a) or len(M()) return length of a pointer to array and an array, as number of array elements. For one dimension arrays len() is equal to Dimension(m(),1) where 1 is the first dimension Dim A(10,10) : Print Len(A())=100
<lang M2000 Interpreter> Module CheckIt { sum=lambda -> { Read m as array if len(m)=0 then =0 : exit sum=Array(m, Dimension(m,0)) If len(m)=1 then =sum : exit k=each(m,2,-1) While k { sum+=Array(k) } =sum } mean=lambda sum (a as array) ->{ =sum(a)/len(a) } prod=lambda -> { m=array if len(m)=0 then =0 : exit prod=Array(m, Dimension(m,0)) If len(m)=1 then =prod : exit k=each(m,2,-1) While k { prod*=Array(k) } =prod } geomean=lambda prod (a as array) -> { =prod(a)^(1/len(a)) } harmomean=lambda (a as array) -> { if len(a)=0 then =0 : exit sum=1/Array(a, Dimension(a,0)) If len(a)=1 then =1/sum : exit k=each(a,2,-1) While k { sum+=1/Array(k) } =len(a)/sum } Print sum((1,2,3,4,5))=15 Print prod((1,2,3,4,5))=120 Print mean((1,2,3,4,5))==3 \\ use == to apply rounding before comparison Print geomean((1,2,3,4,5))==2.60517108469735 Print harmomean((1,2,3,4,5))==2.18978102189784 Generator =lambda x=1 ->{=x : x++} dim a(10)<<Generator() Print mean(a())==5.5 Print geomean(a())==4.52872868811677 Print harmomean(a())==3.41417152147412 } CheckIt </lang> Maple<lang Maple>x := [ seq( 1 .. 10 ) ]; Means := proc( x ) uses Statistics; return Mean( x ), GeometricMean( x ), HarmonicMean( x ); end proc: Arithmeticmean, Geometricmean, Harmonicmean := Means( x ); is( Arithmeticmean >= Geometricmean and Geometricmean >= Harmonicmean ); </lang>
Arithmeticmean, Geometricmean, Harmonicmean := 5.50000000000000, 4.52872868811677, 3.41417152147406 true Mathematica / Wolfram Language<lang Mathematica>Print["{Arithmetic Mean, Geometric Mean, Harmonic Mean} = ", N@Through[{Mean, GeometricMean, HarmonicMean}[Range@10]]]</lang>
{Arithmetic Mean, Geometric Mean, Harmonic Mean} = {5.5,4.52873,3.41417} MATLAB<lang MATLAB>function [A,G,H] = pythagoreanMeans(list) A = mean(list); G = geomean(list); H = harmmean(list); end</lang> A solution that works for both, Matlab and Octave, is this <lang MATLAB>function [A,G,H] = pythagoreanMeans(list) A = mean(list); % arithmetic mean G = exp(mean(log(list))); % geometric mean H = 1./mean(1./list); % harmonic mean end</lang> Solution: <lang MATLAB>>> [A,G,H]=pythagoreanMeans((1:10)) A = 5.500000000000000
4.528728688116765
3.414171521474055</lang> Maxima<lang maxima>/* built-in */ L: makelist(i, i, 1, 10)$ mean(L), numer; /* 5.5 */ geometric_mean(L), numer; /* 4.528728688116765 */ harmonic_mean(L), numer; /* 3.414171521474055 */</lang> Modula-2<lang modula2>MODULE PythagoreanMeans; FROM FormatString IMPORT FormatString; FROM LongMath IMPORT power; FROM LongStr IMPORT RealToStr; FROM Terminal IMPORT WriteString,WriteLn,ReadChar; PROCEDURE ArithmeticMean(numbers : ARRAY OF LONGREAL) : LONGREAL; VAR i,cnt : CARDINAL; mean : LONGREAL; BEGIN mean := 0.0; cnt := 0; FOR i:=0 TO HIGH(numbers) DO mean := mean + numbers[i]; INC(cnt); END; RETURN mean / LFLOAT(cnt) END ArithmeticMean; PROCEDURE GeometricMean(numbers : ARRAY OF LONGREAL) : LONGREAL; VAR i,cnt : CARDINAL; mean : LONGREAL; BEGIN mean := 1.0; cnt := 0; FOR i:=0 TO HIGH(numbers) DO mean := mean * numbers[i]; INC(cnt); END; RETURN power(mean, 1.0 / LFLOAT(cnt)) END GeometricMean; PROCEDURE HarmonicMean(numbers : ARRAY OF LONGREAL) : LONGREAL; VAR i,cnt : CARDINAL; mean : LONGREAL; BEGIN mean := 0.0; cnt := 0; FOR i:=0 TO HIGH(numbers) DO mean := mean + ( 1.0 / numbers[i]); INC(cnt); END; RETURN LFLOAT(cnt) / mean END HarmonicMean;
VAR buf : ARRAY[0..63] OF CHAR; array : DA; arithmetic,geometric,harmonic : LONGREAL; BEGIN array := DA{1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0}; arithmetic := ArithmeticMean(array); geometric := GeometricMean(array); harmonic := HarmonicMean(array); WriteString("A = "); RealToStr(arithmetic, buf); WriteString(buf); WriteString(" G = "); RealToStr(geometric, buf); WriteString(buf); WriteString(" H = "); RealToStr(harmonic, buf); WriteString(buf); WriteLn; FormatString("A >= G is %b, G >= H is %b\n", buf, arithmetic >= geometric, geometric >= harmonic); WriteString(buf); ReadChar END PythagoreanMeans.</lang> MUMPS<lang MUMPS>Pyth(n) New a,ii,g,h,x For ii=1:1:n set x(ii)=ii ; ; Average Set a=0 For ii=1:1:n Set a=a+x(ii) Set a=a/n ; ; Geometric Set g=1 For ii=1:1:n Set g=g*x(ii) Set g=g**(1/n) ; ; Harmonic Set h=0 For ii=1:1:n Set h=1/x(ii)+h Set h=n/h ; Write !,"Pythagorean means for 1..",n,":",! Write "Average = ",a," >= Geometric ",g," >= harmonic ",h,! Quit Do Pyth(10) Pythagorean means for 1..10: Average = 5.5 >= Geometric 4.528728688116178495 >= harmonic 3.414171521474055006</lang> NetRexx<lang NetRexx>/* NetRexx */ options replace format comments java crossref symbols nobinary numeric digits 20 a1 = ArrayList(Arrays.asList([Rexx 1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0])) say "Arithmetic =" arithmeticMean(a1)", Geometric =" geometricMean(a1)", Harmonic =" harmonicMean(a1) return -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ method arithmeticMean(numbers = java.util.List) public static returns Rexx -- somewhat arbitrary return for ooRexx if numbers.isEmpty then return "NaN" mean = 0 number = Rexx loop number over numbers mean = mean + number end return mean / numbers.size -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ method geometricMean(numbers = java.util.List) public static returns Rexx -- somewhat arbitrary return for ooRexx if numbers.isEmpty then return "NaN" mean = 1 number = Rexx loop number over numbers mean = mean * number end return Math.pow(mean, 1 / numbers.size) -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ method harmonicMean(numbers = java.util.List) public static returns Rexx -- somewhat arbitrary return for ooRexx if numbers.isEmpty then return "NaN" mean = 0 number = Rexx loop number over numbers if number = 0 then return "Nan" mean = mean + (1 / number) end -- problem here... return numbers.size / mean </lang>
Arithmetic = 5.5, Geometric = 4.528728688116765, Harmonic = 3.4141715214740550062 Nim<lang nim>import math, sequtils, future proc amean(num: seq[float]): float = sum(num) / float(len(num)) proc gmean(num: seq[float]): float = result = 1 for n in num: result *= n result = pow(result, 1.0 / float(num.len)) proc hmean(num: seq[float]): float = for n in num: result += 1.0 / n result = float(num.len) / result proc ameanFunctional(num: seq[float]): float = sum(num) / float(num.len) proc gmeanFunctional(num: seq[float]): float = num.foldl(a * b).pow(1.0 / float(num.len)) proc hmeanFunctional(num: seq[float]): float = float(num.len) / sum(num.mapIt(float, 1.0 / it)) let numbers = toSeq(1..10).map((x: int) => float(x)) echo amean(numbers), " ", gmean(numbers), " ", hmean(numbers)</lang>
5.5000000000000000e+00 4.5287286881167654e+00 3.4141715214740551e+00 Oberon-2Oxford Oberon-2 <lang oberon2> MODULE PythMean; IMPORT Out, ML := MathL; PROCEDURE Triplets(a: ARRAY OF INTEGER;VAR triplet: ARRAY OF LONGREAL); VAR i: INTEGER; BEGIN triplet[0] := 0.0;triplet[1] := 0.0; triplet[2] := 0.0; FOR i:= 0 TO LEN(a) - 1 DO triplet[0] := triplet[0] + a[i]; triplet[1] := triplet[1] + ML.Ln(a[i]); triplet[2] := triplet[2] + (1 / a[i]) END END Triplets; PROCEDURE Means*(a: ARRAY OF INTEGER); VAR triplet: ARRAY 3 OF LONGREAL; BEGIN Triplets(a,triplet); Out.String("A(1 .. 10): ");Out.LongReal(triplet[0] / LEN(a));Out.Ln; Out.String("G(1 .. 10): ");Out.LongReal(ML.Exp(triplet[1]/ LEN(a)));Out.Ln; Out.String("H(1 .. 10): ");Out.LongReal(LEN(a) / triplet[2]);Out.Ln; END Means; VAR nums: ARRAY 10 OF INTEGER; i: INTEGER; BEGIN FOR i := 0 TO LEN(nums) - 1 DO nums[i] := i + 1 END; Means(nums) END PythMean. </lang>
A(1 .. 10): 5.50000000000 G(1 .. 10): 4.52872868812 H(1 .. 10): 3.41417152147 Objeck<lang objeck>class PythagMeans { function : Main(args : String[]) ~ Nil { array := [1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0]; arithmetic := ArithmeticMean(array); geometric := GeometricMean(array); harmonic := HarmonicMean(array); arith_geo := arithmetic >= geometric; geo_harm := geometric >= harmonic; "A = {$arithmetic}, G = {$geometric}, H = {$harmonic}"->PrintLine(); "A >= G is {$arith_geo}, G >= H is {$geo_harm}"->PrintLine(); } function : native : ArithmeticMean(numbers : Float[]) ~ Float { if(numbers->Size() = 0) { return -1.0; }; mean := 0.0; each(i : numbers) { mean += numbers[i]; }; return mean / numbers->Size(); } function : native : GeometricMean(numbers : Float[]) ~ Float { if(numbers->Size() = 0) { return -1.0; }; mean := 1.0; each(i : numbers) { mean *= numbers[i]; }; return mean->Power(1.0 / numbers->Size()); } function : native : HarmonicMean(numbers : Float[]) ~ Float { if(numbers->Size() = 0) { return -1.0; }; mean := 0.0; each(i : numbers) { mean += (1.0 / numbers[i]); }; return numbers->Size() / mean; } }</lang> Output: A = 5.500, G = 4.529, H = 3.414 A >= G is true, G >= H is true OCamlThe three means in one function <lang ocaml>let means v = let n = Array.length v and a = ref 0.0 and b = ref 1.0 and c = ref 0.0 in for i=0 to n-1 do a := !a +. v.(i); b := !b *. v.(i); c := !c +. 1.0/.v.(i); done; let nn = float_of_int n in (!a /. nn, !b ** (1.0/.nn), nn /. !c)
means (Array.init 10 (function i -> (float_of_int (i+1)))) ;; (* (5.5, 4.5287286881167654, 3.4141715214740551) *) Another implementation using <lang ocaml>let means v = let (a, b, c) = Array.fold_left (fun (a, b, c) x -> (a+.x, b*.x, c+.1./.x)) (0.,1.,0.) v in let n = float_of_int (Array.length v) in (a /. n, b ** (1./.n), n /. c)
Octave<lang Octave> A = mean(list); % arithmetic mean G = mean(list,'g'); % geometric mean H = mean(list,'a'); % harmonic mean </lang> See also Matlab implementation #MATLAB Oforth<lang Oforth>import: mapping
x sum x size dup ifZero: [ 2drop null ] else: [ >float / ]
|
"Geometric mean :" . 10 seq G dup .cr ->g "Arithmetic mean :" . 10 seq A dup . g >= ifTrue: [ " ==> A >= G" .cr ] "Harmonic mean :" . 10 seq H dup . g <= ifTrue: [ " ==> G >= H" .cr ]
Geometric mean : 4.52872868811677 Arithmetic mean : 5.5 ==> A >= G Harmonic mean : 3.41417152147406 ==> G >= H ooRexx<lang ooRexx>a = .array~of(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0) say "Arithmetic =" arithmeticMean(a)", Geometric =" geometricMean(a)", Harmonic =" harmonicMean(a)
use arg numbers -- somewhat arbitrary return for ooRexx if numbers~isEmpty then return "NaN" mean = 0 loop number over numbers mean += number end return mean / numbers~items
use arg numbers -- somewhat arbitrary return for ooRexx if numbers~isEmpty then return "NaN" mean = 1 loop number over numbers mean *= number end return rxcalcPower(mean, 1 / numbers~items)
use arg numbers -- somewhat arbitrary return for ooRexx if numbers~isEmpty then return "NaN" mean = 0 loop number over numbers if number = 0 then return "Nan" mean += 1 / number end -- problem here.... return numbers~items / mean
Arithmetic = 5.5, Geometric = 4.52872869, Harmonic = 3.41417153 Oz<lang oz>declare %% helpers fun {Sum Xs} {FoldL Xs Number.'+' 0.0} end fun {Product Xs} {FoldL Xs Number.'*' 1.0} end fun {Len Xs} {Int.toFloat {Length Xs}} end fun {AMean Xs} {Sum Xs} / {Len Xs} end fun {GMean Xs} {Pow {Product Xs} 1.0/{Len Xs}} end fun {HMean Xs} {Len Xs} / {Sum {Map Xs fun {$ X} 1.0 / X end}} end Numbers = {Map {List.number 1 10 1} Int.toFloat} [A G H] = [{AMean Numbers} {GMean Numbers} {HMean Numbers}] in {Show [A G H]} A >= G = true G >= H = true</lang> PARI/GPGeneral implementations: <lang parigp>arithmetic(v)={ sum(i=1,#v,v[i])/#v }; geometric(v)={ prod(i=1,#v,v[i])^(1/#v) }; harmonic(v)={ #v/sum(i=1,#v,1/v[i]) }; v=vector(10,i,i); [arithmetic(v),geometric(v),harmonic(v)]</lang> Specific to the first n positive integers: <lang parigp>arithmetic_first(n)={ (n+1)/2 }; geometric_first(n)={ n!^(1/n) }; harmonic_first(n)={ n/if(n>1000, log(n)+Euler+1/(n+n)+1/(12*n^2)-1/(120*n^4)+1/(252*n^6)-1/(240*n^8)+1/(132*n^10) , n/sum(k=1,n,1/k) ) }; [arithmetic_first(10),geometric_first(10),harmonic_first(10)] %[1]>=%[2] && %[2] >= %[3]</lang> These are, asymptotically, n/2, n/e, and n/log n. PascalSee Delphi Perl<lang perl>sub A { my $a = 0; $a += $_ for @_; return $a / @_; } sub G { my $p = 1; $p *= $_ for @_; return $p**(1/@_); # power of 1/n == root of n } sub H { my $h = 0; $h += 1/$_ for @_; return @_/$h; } my @ints = (1..10); my $a = A(@ints); my $g = G(@ints); my $h = H(@ints); print "A=$a\nG=$g\nH=$h\n"; die "Error" unless $a >= $g and $g >= $h;</lang> Perl 6<lang perl6>sub A { ([+] @_) / @_ } sub G { ([*] @_) ** (1 / @_) } sub H { @_ / [+] 1 X/ @_ } say "A(1,...,10) = ", A(1..10); say "G(1,...,10) = ", G(1..10); say "H(1,...,10) = ", H(1..10); </lang>
A(1,...,10) = 5.5 G(1,...,10) = 4.52872868811677 H(1,...,10) = 3.41417152147406 Phix(note to self: iff should really be a builtin) <lang Phix>function arithmetic_mean(sequence s) return sum(s)/length(s) end function function geometric_mean(sequence s) atom p = 1 for i=1 to length(s) do p *= s[i] end for return power(p,1/length(s)) end function function harmonic_mean(sequence s) atom rsum = 0 for i=1 to length(s) do rsum += 1/s[i] end for return length(s)/rsum end function function iff(integer condition, object Tval, object Fval) if condition then return Tval else return Fval end if end function constant s = {1,2,3,4,5,6,7,8,9,10} constant arithmetic = arithmetic_mean(s), geometric = geometric_mean(s), harmonic = harmonic_mean(s) printf(1,"Arithmetic: %.10g\n", arithmetic) printf(1,"Geometric: %.10g\n", geometric) printf(1,"Harmonic: %.10g\n", harmonic) printf(1,"Arithmetic>=Geometric>=Harmonic: %s\n", {iff((arithmetic>=geometric and geometric>=harmonic),"true","false")})</lang>
Arithmetic: 5.5 Geometric: 4.528728688 Harmonic: 3.414171521 Arithmetic>=Geometric>=Harmonic: true PHP<lang PHP><?php // Created with PHP 7.0 function ArithmeticMean(array $values) { return array_sum($values) / count($values); } function GeometricMean(array $values) { return array_product($values) ** (1 / count($values)); } function HarmonicMean(array $values) { $sum = 0; foreach ($values as $value) { $sum += 1 / $value; } return count($values) / $sum; } $values = array(1, 2, 3, 4, 5, 6, 7, 8, 9, 10); echo "Arithmetic: " . ArithmeticMean($values) . "\n"; echo "Geometric: " . GeometricMean($values) . "\n"; echo "Harmonic: " . HarmonicMean($values) . "\n"; </lang>
Arithmetic: 5.5 Geometric: 4.5287286881168 Harmonic: 3.4141715214741 PicoLisp<lang PicoLisp>(load "@lib/math.l") (let (Lst (1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0 9.0 10.0) Len (length Lst)) (prinl "Arithmetic mean: " (format (/ (apply + Lst) Len) *Scl ) ) (prinl "Geometric mean: " (format (pow (*/ (apply * Lst) (** 1.0 (dec Len))) (/ 1.0 Len)) *Scl ) ) (prinl "Harmonic mean: " (format (*/ (* 1.0 Len) 1.0 (sum '((N) (*/ 1.0 1.0 N)) Lst)) *Scl ) ) )</lang>
Arithmetic mean: 5.500000 Geometric mean: 4.528729 Harmonic mean: 3.414172 PL/I<lang PL/I> declare n fixed binary, (Average, Geometric, Harmonic) float; declare A(10) float static initial (1,2,3,4,5,6,7,8,9,10); n = hbound(A,1); /* compute the average */ Average = sum(A)/n; /* Compute the geometric mean: */ Geometric = prod(A)**(1/n); /* Compute the Harmonic mean: */ Harmonic = n / sum(1/A); put skip data (Average); put skip data (Geometric); put skip data (Harmonic); if Average < Geometric then put skip list ('Error'); if Geometric < Harmonic then put skip list ('Error'); </lang> Results: AVERAGE= 5.50000E+0000; GEOMETRIC= 4.52873E+0000; HARMONIC= 3.41417E+0000; PostScript<lang> /pythamean{ /x exch def /sum 0 def /prod 1 def /invsum 0 def /i 1 def x{ /sum sum i add def /prod prod i mul def /invsum invsum i -1 exp add def /i i 1 add def }repeat (Arithmetic Mean : ) print sum x div = (Geometric Mean : ) print prod x -1 exp exp = (Harmonic Mean : ) print x invsum div = }def 10 pythamean </lang>
Arithmetic Mean : 5.5 Geometric Mean : 4.52873 Harmonic Mean : 3.41417 <lang postscript> /numbers {[1 10] 1 range}. /recip {1 exch div}. % Arithmetic mean numbers dup 0 {+} fold exch length div % Geometric mean numbers dup 1 {*} fold exch length recip exp % Harmonic mean numbers dup 0 {recip +} fold exch length exch div </lang> PowerShell<lang PowerShell>$A = 0 $LogG = 0 $InvH = 0 $ii = 1..10 foreach($i in $ii) { # Arithmetic mean is computed directly $A += $i / $ii.Count # Geometric mean is computed using Logarithms $LogG += [Math]::Log($i) / $ii.Count # Harmonic mean is computed using its inverse $InvH += 1 / ($i * $ii.Count) } $G = [Math]::Exp($LogG) $H = 1/$InvH write-host "Arithmetic mean: A = $A" write-host "Geometric mean: G = $G" write-host "Harmonic mean: H = $H" write-host "Is A >= G ? $($A -ge $G)" write-host "Is G >= H ? $($G -ge $H)"</lang>
Arithmetic mean: A = 5.5 Geometric mean: G = 4.52872868811676 Harmonic mean: H = 3.41417152147405 Is A >= G ? True Is G >= H ? True PureBasic<lang PureBasic>Procedure.d ArithmeticMean() For a = 1 To 10 mean + a Next ProcedureReturn mean / 10 EndProcedure Procedure.d GeometricMean() mean = 1 For a = 1 To 10 mean * a Next ProcedureReturn Pow(mean, 1 / 10) EndProcedure Procedure.d HarmonicMean() For a = 1 To 10 mean.d + 1 / a Next ProcedureReturn 10 / mean EndProcedure If HarmonicMean() <= GeometricMean() And GeometricMean() <= ArithmeticMean() Debug "true" EndIf Debug ArithmeticMean() Debug GeometricMean() Debug HarmonicMean()</lang> Python<lang Python>from operator import mul from functools import reduce def amean(num): return sum(num)/len(num) def gmean(num): return reduce(mul, num, 1)**(1/len(num)) def hmean(num): return len(num)/sum(1/n for n in num) numbers = range(1,11) # 1..10 a, g, h = amean(numbers), gmean(numbers), hmean(numbers) print(a, g, h) assert( a >= g >= h ) </lang>
5.5 4.52872868812 3.41417152147 These are the same in Python 2 apart from requiring explicit float division (either through RInitialise x <lang R> x <- 1:10 </lang> Arithmetic mean <lang R> a <- sum(x)/length(x) </lang> or <lang R> a <- mean(x) </lang> The geometric mean <lang R> g <- prod(x)^(1/length(x)) </lang> The harmonic mean (no error checking that ) <lang R> h <- length(x)/sum(1/x) </lang> Then: <lang R> a > g </lang> and <lang R> g > h </lang> give both [1] TRUE Racket<lang racket>
(define (arithmetic xs) (/ (for/sum ([x xs]) x) (length xs))) (define (geometric xs) (expt (for/product ([x xs]) x) (/ (length xs)))) (define (harmonic xs) (/ (length xs) (for/sum ([x xs]) (/ x)))) (define xs (range 1 11)) (arithmetic xs) (geometric xs) (harmonic xs) (>= (arithmetic xs) (geometric xs) (harmonic xs)) </lang>
5 1/2 4.528728688116765 3 3057/7381 #t REXXREXX doesn't have a POW function, so an IROOT (integer root) function is included here; it includes an
sum = sum + # /*compute the sum of all the elements. */ prod= prod * # /*compute the product of all elements. */ rSum= rSum + 1/# /*compute the sum of the reciprocals. */ end /*#*/ say ' list ='$ /*display the list of numbers used. */ say 'Amean =' sum / n /*calculate & display arithmetic mean.*/ say 'Gmean =' Iroot(prod, n) /* " " " geometric " */ say 'Hmean =' n / rSum /* " " " harmonic " */ exit /*stick a fork in it, we're all done. */ /*──────────────────────────────────────────────────────────────────────────────────────*/ Iroot: procedure; arg x 1 ox, y 1 oy /*get both args, and also a copy of X&Y*/ if x=0 | x=1 | y=1 then return x /*handle special case of zero and unity*/ if y=0 then return 1 /* " " " " a zero root.*/ if x<0 & y//2==0 then return IrootErr() x=abs(x); y=abs(y); m=y - 1 /*use the absolute value for X and Y. */ oDigs=digits(); a=oDigs + 5 /*save original digits; add five digs.*/ g=(x+1) / y**y /*use this as the first guesstimate. */ d=5 /*start with 5 dec digs, saves CPU time*/ do until d==a /*keep going as digits are increased. */ d=min(d+d, a); numeric digits d; f=d-2 /*limit digits to original digits + 5.*/ og= /*use a non-guess for the old G (guess)*/ do forever; gm=g**m /*keep computing at the Yth root. */ _=format( (m*g*gm + x) / (y*gm), , f) /*this is the nitty─gritty calculation.*/ if _=g | _=og then leave /*are we close enough yet? */ og=g; g=_ /*save guess ──► OG; set the new guess.*/ end /*forever*/ end /*until */ if oy<0 then g=1/g /*use reciprocal when Y is negative. */ numeric digits oDigs; return sign(ox)*g/1 /*normalize to original decimal digits.*/ /*──────────────────────────────────────────────────────────────────────────────────────*/ IrootErr: say '***error*** (from Iroot): root' y "can't be even if 1st argument is < 0." return '[n/a]' /*return a "not applicable" string. */</lang> output using the default inputs: list = 1 2 3 4 5 6 7 8 9 10 Amean = 5.5 Gmean = 4.5287286881167647622 Hmean = 3.4141715214740550062 Ring<lang ring> decimals(8) array = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10] see "arithmetic mean = " + arithmeticMean(array) + nl see "geometric mean = " + geometricMean(array) + nl see "harmonic mean = " + harmonicMean(array) + nl func arithmeticMean a return summary(a) / len(a) func geometricMean a b = 1 for i = 1 to len(a) b *= a[i] next return pow(b, (1/len(a))) func harmonicMean a b = list(len(a)) for nr = 1 to len(a) b[nr] = 1/a[nr] next return len(a) / summary(b) func summary s sum = 0 for n = 1 to len(s) sum += s[n] next return sum </lang> Output: arithmetic mean = 5.50000000 geometric mean = 4.52872869 harmonic mean = 3.41417152 Ruby<lang ruby>class Array def arithmetic_mean inject(0.0, :+) / length end def geometric_mean inject(:*) ** (1.0 / length) end def harmonic_mean length / inject(0.0) {|s, m| s + 1.0/m} end end class Range def method_missing(m, *args) case m when /_mean$/ then to_a.send(m) else super end end end p a = (1..10).arithmetic_mean p g = (1..10).geometric_mean p h = (1..10).harmonic_mean
p g.between?(h, a)</lang>
5.5 4.528728688116765 3.414171521474055 true Run BASIC<lang runbasic>bXsum = 1 for i = 1 to 10 sum = sum + i ' sum of 1 -> 10 bXsum = bXsum * i ' sum i * i sum1i = sum1i + (1/i) ' sum 1/i next average = sum / 10 geometric = bXsum ^ (1/10) harmonic = 10/sum1i print "ArithmeticMean:";average print "Geometric Mean:";geometric print " Harmonic Mean:";harmonic if (average >= geometric) and (geometric >= harmonic) then print "True" else print "False"</lang>
Arithmetic Mean:5.5 Geometric Mean:4.52872869 Harmonic Mean:3.41417132 True Rust<lang rust>fn main() { let mut sum = 0.0; let mut prod = 1; let mut recsum = 0.0; for i in 1..11{ sum += i as f32; prod *= i; recsum += 1.0/(i as f32); } let avg = sum/10.0; let gmean = (prod as f32).powf(0.1); let hmean = 10.0/recsum; println!("Average: {}, Geometric mean: {}, Harmonic mean: {}", avg, gmean, hmean); assert!( ( (avg >= gmean) && (gmean >= hmean) ), "Incorrect calculation"); } </lang>
Average: 5.5, Geometric mean:4.528729, Harmonic mean: 3.4141712 Scala<lang scala>def arithmeticMean(n: Seq[Int]) = n.sum / n.size.toDouble def geometricMean(n: Seq[Int]) = math.pow(n.foldLeft(1.0)(_*_), 1.0 / n.size.toDouble) def harmonicMean(n: Seq[Int]) = n.size / n.map(1.0 / _).sum var nums = 1 to 10 var a = arithmeticMean(nums) var g = geometricMean(nums) var h = harmonicMean(nums) println("Arithmetic mean " + a) println("Geometric mean " + g) println("Harmonic mean " + h) assert(a >= g && g >= h)</lang>
Arithmetic mean 5.5 Geometric mean 4.528728688116765 Harmonic mean 3.414171521474055 Scheme<lang scheme>(define (a-mean l) (/ (apply + l) (length l))) (define (g-mean l) (expt (apply * l) (/ (length l)))) (define (h-mean l) (/ (length l) (apply + (map / l)))) (define (iota start stop) (if (> start stop) (list) (cons start (iota (+ start 1) stop)))) (let* ((l (iota 1 10)) (a (a-mean l)) (g (g-mean l)) (h (h-mean l))) (display a) (display " >= ") (display g) (display " >= ") (display h) (newline) (display (>= a g h)) (newline))</lang>
<lang>11/2 >= 4.528728688116765 >= 25200/7381
Seed7<lang seed7>$ include "seed7_05.s7i"; include "float.s7i"; const array float: numbers is [] (1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0); const func proc: main is func local var float: number is 0.0; var float: sum is 0.0; var float: product is 1.0; var float: reciprocalSum is 0.0; begin for number range numbers do sum +:= number; product *:= number; reciprocalSum +:= 1.0 / number; end for; writeln("Arithmetic mean: " <& sum / flt(length(numbers))); writeln("Geometric mean: " <& product ** (1.0 / flt(length(numbers)))); writeln("Harmonic mean: " <& flt(length(numbers)) / reciprocalSum); end func;</lang>
Arithmetic mean: 5.5 Geometric mean: 4.528728961944580078125 Harmonic mean: 3.4141712188720703125 Sidef<lang sidef>func A(a) { a.sum / a.len } func G(a) { a.prod.root(a.len) } func H(a) { a.len / a.map{1/_}.sum }</lang> The same thing, using hyper-operators: <lang sidef>func A(a) { a«+» / a.len } func G(a) { a«*» ** (1/a.len) } func H(a) { a.len / (a«/«1 «+») }</lang> Calling the functions: <lang sidef>say("A(1,...,10) = ", A(1..10)); say("G(1,...,10) = ", G(1..10)); say("H(1,...,10) = ", H(1..10));</lang>
A(1,...,10) = 5.5 G(1,...,10) = 4.528728688116764762203309337195508793499 H(1,...,10) = 3.414171521474055006096734859775098225173 SQLIt may not be possible to calculate a geometric mean in a query, but the other two are easy enough. <lang sql> --setup create table averages (val integer); insert into averages values (1); insert into averages values (2); insert into averages values (3); insert into averages values (4); insert into averages values (5); insert into averages values (6); insert into averages values (7); insert into averages values (8); insert into averages values (9); insert into averages values (10); -- calculate means select 1/avg(1/val) as harm, avg(val) as arith from averages; </lang>
HARM ARITH ---------- ---------- 3.41417152 5.5 SmalltalkThis extends the class Collection, so these three methods can be called over any kind of collection, it is enough the the objects of the collection understand +, *, raisedTo, reciprocal and /. <lang smalltalk>Collection extend [ arithmeticMean [ ^ (self fold: [:a :b| a + b ]) / (self size) ] geometricMean [ ^ (self fold: [:a :b| a * b]) raisedTo: (self size reciprocal) ] harmonicMean [ ^ (self size) / ((self collect: [:x|x reciprocal]) fold: [:a :b| a + b ] ) ] ] |
a := #(1 2 3 4 5 6 7 8 9 10). a arithmeticMean asFloat displayNl. a geometricMean asFloat displayNl. a harmonicMean asFloat displayNl. ((a arithmeticMean) >= (a geometricMean)) displayNl. ((a geometricMean) >= (a harmonicMean)) displayNl.</lang>
5.5 4.528728688116765 3.414171521474055 true true StataThe command ameans prints the arithmetic, geometric and harmonic means, together with confidence intervals. <lang>clear all set obs 10 gen x=_n ameans x Variable | Type Obs Mean [95% Conf. Interval] +--------------------------------------------------------------- x | Arithmetic 10 5.5 3.334149 7.665851 |
Geometric 10 4.528729 2.680672 7.650836 | Harmonic 10 3.414172 2.035664 10.57602
</lang> Tcl<lang tcl>proc arithmeticMean list { set sum 0.0 foreach value $list { set sum [expr {$sum + $value}] } return [expr {$sum / [llength $list]}] } proc geometricMean list { set product 1.0 foreach value $list { set product [expr {$product * $value}] } return [expr {$product ** (1.0/[llength $list])}] } proc harmonicMean list { set sum 0.0 foreach value $list { set sum [expr {$sum + 1.0/$value}] } return [expr {[llength $list] / $sum}] } set nums {1 2 3 4 5 6 7 8 9 10} set A10 [arithmeticMean $nums] set G10 [geometricMean $nums] set H10 [harmonicMean $nums] puts "A10=$A10, G10=$G10, H10=$H10" if {$A10 >= $G10} { puts "A10 >= G10" } if {$G10 >= $H10} { puts "G10 >= H10" }</lang>
A10=5.5, G10=4.528728688116765, H10=3.414171521474055 A10 >= G10 G10 >= H10 Ursala<lang Ursala>#import std
data = ari10(1.,10.) # arithmetic progression, length 10 with endpoints 1 and 10 a = mean data g = exp mean ln* data h = div/1. mean div/*1. data
main = ^(~&,ordered not fleq) <a,g,h></lang>
( <5.500000e+00,4.528729e+00,3.414172e+00>, true) ValaMost valac setups will need "-X -lm" added to the compile command to include the C math library. <lang vala> double arithmetic(int[] list){ double mean; double sum = 0; foreach(int number in list){ sum += number; } // foreach mean = sum / list.length; return mean; } // end arithmetic mean double geometric(int[] list){ double mean; double product = 1; foreach(int number in list){ product *= number; } // foreach mean = Math.pow(product, (1 / (double) list.length)); return mean; } // end geometric mean double harmonic(int[] list){ double mean; double sum_inverse = 0; foreach(int number in list){ sum_inverse += (1 / (double) number); } // foreach mean = (double) list.length / sum_inverse; return mean; } // end harmonic mean public static void main(){ int[] list = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10}; double arithmetic_mean = arithmetic(list); double geometric_mean = geometric(list); double harmonic_mean = harmonic(list); // should be 5.5 stdout.printf("Arithmetic mean: %s\n", arithmetic_mean.to_string()); // should be 4.528728688116765 stdout.printf("Geometric mean: %s\n", geometric_mean.to_string()); // should be 4.528728688116765 stdout.printf("Harmonic mean: %s\n", harmonic_mean.to_string()); } </lang>
Arithmetic mean: 5.5 Geometric mean: 4.5287286881167654 Harmonic mean: 3.4141715214740551 VBAUses Excel VBA. <lang vb>Private Function arithmetic_mean(s() As Variant) As Double arithmetic_mean = WorksheetFunction.sum(s) / UBound(s) End Function Private Function geometric_mean(s() As Variant) As Double geometric_mean = WorksheetFunction.Power( _ WorksheetFunction.Product(s), 1 / UBound(s)) End Function Private Function harmonic_mean(s() As Variant) As Double harmonic_mean = WorksheetFunction.HarMean(s) End Function Public Sub pythagorean_means() Dim s() As Variant s = [{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}] Debug.Print "A ="; arithmetic_mean(s) Debug.Print "G ="; geometric_mean(s) Debug.Print "H ="; harmonic_mean(s)End Sub</lang>
A = 5,5 G = 4,52872868811677 H = 3,41417152147406 VBScript<lang vb> Function arithmetic_mean(arr) sum = 0 For i = 0 To UBound(arr) sum = sum + arr(i) Next arithmetic_mean = sum / (UBound(arr)+1) End Function Function geometric_mean(arr) product = 1 For i = 0 To UBound(arr) product = product * arr(i) Next geometric_mean = product ^ (1/(UBound(arr)+1)) End Function Function harmonic_mean(arr) sum = 0 For i = 0 To UBound(arr) sum = sum + (1/arr(i)) Next harmonic_mean = (UBound(arr)+1) / sum End Function WScript.StdOut.WriteLine arithmetic_mean(Array(1,2,3,4,5,6,7,8,9,10)) WScript.StdOut.WriteLine geometric_mean(Array(1,2,3,4,5,6,7,8,9,10)) WScript.StdOut.WriteLine harmonic_mean(Array(1,2,3,4,5,6,7,8,9,10)) </lang>
5.5 4.52872868811677 3.41417152147406 XPL0<lang XPL0>include c:\cxpl\codes; func real Power(X, Y); \X raised to the Y power real X, Y; \ (from StdLib.xpl) return Exp(Y * Ln(X)); int N, Order; real R, A, A1, G, G1, H, H1; [A1:= 0.0; G1:= 1.0; H1:= 0.0; Order:= true; for N:= 1 to 10 do [R:= float(N); \convert integer N to real R A1:= A1 + R; A:= A1/R; \arithmetic mean G1:= G1 * R; G:= Power(G1, 1.0/R); \geometric mean (Nth root of G1) if G>A then Order:= false; H1:= H1 + 1.0/R; H:= R/H1; \harmonic mean if H>G then Order:= false; ]; RlOut(0, A); CrLf(0); RlOut(0, G); CrLf(0); RlOut(0, H); CrLf(0); if not Order then Text(0, "NOT "); Text(0, "ALWAYS DECREASING ORDER "); ]</lang>
5.50000 4.52873 3.41417 ALWAYS DECREASING ORDER zkl<lang zkl>ns:=T(1,2,3,4,5,6,7,8,9,10); ns.sum(0.0)/ns.len(); // Arithmetic mean ns.reduce('*,1.0).pow(1.0/ns.len()); // Geometric mean ns.len().toFloat() / ns.reduce(fcn(p,n){ p + 1.0/n },0.0); // Harmonic mean</lang>
5.5 4.52873 3.41417 |
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