Gradient descent: Difference between revisions
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{{works with|ALGOL 68G|Any - tested with release 2.8.3.win32}} |
{{works with|ALGOL 68G|Any - tested with release 2.8.3.win32}} |
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{{Trans|Go}} modified to use the actual gradient function - |
{{Trans|Go}} modified to use the actual gradient function - |
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{{Trans| |
{{Trans|Fortran}} |
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THe results agree with the Fortran sample and the Julia sample to 6 places. |
THe results agree with the Fortran sample and the Julia sample to 6 places. |
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<lang algol68>PROC steepest descent = ( REF[]LONG REAL x, LONG REAL alphap, tolerance )VOID: |
<lang algol68>PROC steepest descent = ( REF[]LONG REAL x, LONG REAL alphap, tolerance )VOID: |
Revision as of 11:25, 3 September 2020
Gradient descent (also known as steepest descent) is a first-order iterative optimization algorithm for finding the minimum of a function which is described in this Wikipedia article.
- Task
Use this algorithm to search for minimum values of the bi-variate function:
f(x, y) = (x - 1)(x - 1)e^(-y^2) + y(y+2)e^(-2x^2)
around x = 0.1 and y = -1.
This book excerpt shows sample C# code for solving this task.
ALGOL 68
modified to use the actual gradient function -
THe results agree with the Fortran sample and the Julia sample to 6 places. <lang algol68>PROC steepest descent = ( REF[]LONG REAL x, LONG REAL alphap, tolerance )VOID: BEGIN
LONG REAL alpha := alphap; LONG REAL g0 := g( x ); # Initial estimate of result. # # Calculate initial gradient. # [ LWB x : UPB x ]LONG REAL fi := grad g( x ); # Calculate initial norm. # LONG REAL del g := 0.0; FOR i FROM LWB x TO UPB x DO del g +:= fi[ i ] * fi[ i ] OD; del g := long sqrt( del g ); LONG REAL b := alpha / del g; # Iterate until value is <= tolerance. # WHILE del g > tolerance DO # Calculate next value. # FOR i FROM LWB x TO UPB x DO x[i] -:= b * fi[i] OD; # Calculate next gradient. # fi := grad g( x ); # Calculate next norm. # del g := 0; FOR i FROM LWB x TO UPB x DO del g +:= fi[ i ] * fi[ i ] OD; del g := long sqrt( del g ); IF del g > 0 THEN b := alpha / del g; # Calculate next value. # LONG REAL g1 := g( x ); # Adjust parameter. # IF g1 > g0 THEN alpha /:= 2 ELSE g0 := g1 FI FI OD
END # steepest descent # ;
- calculates the gradient of g(p). #
- The derivitives wrt x and y are (as in the Fortran sample ): #
- g' wrt x = 2( x - 1 )e^( - ( y^2 ) ) - 4xe^( -2( x^2) )y( y + 2 ) #
- g' wrt y = ( -2( x-1 )^2ye^( - (y^2) )) + e^(-2( x^2 ) )( y + 2 ) + e^( -2( x^2 ) )y #
PROC grad g = ( []LONG REAL p )[]LONG REAL: BEGIN
[ LWB p : UPB p ]LONG REAL z; LONG REAL x = p[ 0 ]; LONG REAL y = p[ 1 ]; z[ 0 ] := 2 * ( x - 1 ) * long exp( - ( y * y ) ) - 4 * x * long exp( -2 * ( x * x ) ) * y * ( y + 2 ); z[ 1 ] := ( -2 * ( x - 1 ) * ( x - 1 ) * y ) * long exp( - y * y ) + long exp( -2 * x * x ) * ( y + 2 ) + long exp( -2 * x * x ) * y; z
END # grad g # ;
- Function for which minimum is to be found. #
- g( x, y ) = ( ( x - 1 )^2 )e^( - ( x^2 ) ) + y( y + 2 )e^( - 2(x^2)) #
PROC g = ( []LONG REAL x )LONG REAL:
( x[ 0 ] - 1 ) * ( x[ 0 ] - 1 ) * long exp( - x[ 1 ] * x[ 1 ] ) + x[ 1 ] * ( x[ 1 ] + 2 ) * long exp( - 2 * x[ 0 ] * x[ 0 ] ) ;
BEGIN
LONG REAL tolerance := 0.0000006; LONG REAL alpha := 0.1; [ 0 : 1 ]LONG REAL x := ( []LONG REAL( 0.1, -1 ) )[ AT 0 ]; # Initial guess of location of minimum. # steepest descent( x, alpha, tolerance ); print( ( "Testing steepest descent method:", newline ) ); print( ( "The minimum is at x[0] = ", fixed( x[ 0 ], -10, 6 ), ", x[1] = ", fixed( x[ 1 ], -10, 6 ), newline ) )
END</lang>
- Output:
Testing steepest descent method: The minimum is at x[0] = 0.107627, x[1] = -1.223260
Fortran
Compiler: gfortran 8.3.0
The way a FORTRAN programmer would do this would be to automatically differentiate the function using the diff command in Maxima:
(%i3) (x-1)*(x-1)*exp(-y^2)+y*(y+2)*exp(-2*x^2); 2 2 2 - y - 2 x (%o3) (x - 1) %e + %e y (y + 2) (%i4) diff(%o3,x); 2 2 - y - 2 x (%o4) 2 (x - 1) %e - 4 x %e y (y + 2) (%i5) diff(%o3,y); 2 2 2 2 - y - 2 x - 2 x (%o5) (- 2 (x - 1) y %e ) + %e (y + 2) + %e y
and then have it automatically turned into statements with the fortran command:
(%i6) fortran(%o4); 2*(x-1)*exp(-y**2)-4*x*exp(-2*x**2)*y*(y+2) (%o6) done (%i7) fortran(%o5); (-2*(x-1)**2*y*exp(-y**2))+exp(-2*x**2)*(y+2)+exp(-2*x**2)*y (%o7) done
The optimization subroutine GD sets the reverse communication variable IFLAG. This allows the evaluation of the function and the gradient to be done separately. <lang Fortran> SUBROUTINE EVALFG (N, X, F, G)
IMPLICIT NONE INTEGER N REAL X(N), F, G(N) F = (X(1) - 1.)**2 * EXP(-X(2)**2) + $ X(2) * (X(2) + 2.) * EXP(-2. * X(1)**2) G(1) = 2. * (X(1) - 1.) * EXP(-X(2)**2) - 4. * X(1) * $ EXP(-2. * X(1)**2) * X(2) * (X(2) + 2.) G(2) = (-2. * (X(1) - 1.)**2 * X(2) * EXP(-X(2)**2)) + $ EXP(-2. * X(1)**2) * (X(2) + 2.) + $ EXP(-2. * X(1)**2) * X(2) RETURN END
- -----------------------------------------------------------------------
- gd - Gradient descent
- G must be set correctly at the initial point X.
- ___Name______Type________In/Out___Description_________________________
- N Integer In Number of Variables.
- X(N) Real Both Variables
- G(N) Real Both Gradient
- TOL Real In Relative convergence tolerance
- IFLAG Integer Both Reverse Communication Flag
- 0 on input: begin
- 0 on output: done
- 1 compute G
- -----------------------------------------------------------------------
SUBROUTINE GD (N, X, G, TOL, IFLAG) IMPLICIT NONE INTEGER N, IFLAG REAL X(N), G(N), TOL REAL ETA PARAMETER (ETA = 0.3) ! Learning rate INTEGER I REAL GNORM ! norm of gradient
IF (IFLAG .EQ. 1) GO TO 20
10 DO I = 1, N ! take step X(I) = X(I) - ETA * G(I) END DO IFLAG = 1 RETURN ! let main program evaluate G
20 GNORM = 0. ! convergence test DO I = 1, N GNORM = GNORM + G(I)**2 END DO GNORM = SQRT(GNORM) IF (GNORM < TOL) THEN IFLAG = 0 RETURN ! success END IF GO TO 10 END ! of gd
PROGRAM GDDEMO IMPLICIT NONE INTEGER N PARAMETER (N = 2) INTEGER ITER, J, IFLAG REAL X(N), F, G(N), TOL
X(1) = -0.1 ! initial values X(2) = -1.0 TOL = 1.E-6 IFLAG = 0 DO J = 1, 1 000 000 CALL GD (N, X, G, TOL, IFLAG) IF (IFLAG .EQ. 1) THEN CALL EVALFG (N, X, F, G) ELSE ITER = J GO TO 50 END IF END DO STOP 'too many iterations!'
50 PRINT '(A, I7, A, F10.6, A, F10.6, A, F10.6)', $ 'After ', ITER, ' steps, found minimum at x=', $ X(1), ' y=', X(2), ' of f=', F STOP 'program complete' END
</lang>
- Output:
After 14 steps, found minimum at x= 0.107627 y= -1.223260 of f= -0.750063 STOP program complete
Go
This is a translation of the C# code in the book excerpt linked to above and hence also of the first Typescript example below.
For some unknown reason the results differ from the other solutions after the first 4 decimal places but are near enough for an approximate method such as this. <lang go>package main
import (
"fmt" "math"
)
func steepestDescent(x []float64, alpha, tolerance float64) {
n := len(x) h := tolerance g0 := g(x) // Initial estimate of result.
// Calculate initial gradient. fi := gradG(x, h)
// Calculate initial norm. delG := 0.0 for i := 0; i < n; i++ { delG += fi[i] * fi[i] } delG = math.Sqrt(delG) b := alpha / delG
// Iterate until value is <= tolerance. for delG > tolerance { // Calculate next value. for i := 0; i < n; i++ { x[i] -= b * fi[i] } h /= 2
// Calculate next gradient. fi = gradG(x, h)
// Calculate next norm. delG = 0 for i := 0; i < n; i++ { delG += fi[i] * fi[i] } delG = math.Sqrt(delG) b = alpha / delG
// Calculate next value. g1 := g(x)
// Adjust parameter. if g1 > g0 { alpha /= 2 } else { g0 = g1 } }
}
// Provides a rough calculation of gradient g(x). func gradG(x []float64, h float64) []float64 {
n := len(x) z := make([]float64, n) y := make([]float64, n) copy(y, x) g0 := g(x)
for i := 0; i < n; i++ { y[i] += h z[i] = (g(y) - g0) / h } return z
}
// Function for which minimum is to be found. func g(x []float64) float64 {
return (x[0]-1)*(x[0]-1)* math.Exp(-x[1]*x[1]) + x[1]*(x[1]+2)* math.Exp(-2*x[0]*x[0])
}
func main() {
tolerance := 0.0000006 alpha := 0.1 x := []float64{0.1, -1} // Initial guess of location of minimum.
steepestDescent(x, alpha, tolerance) fmt.Println("Testing steepest descent method:") fmt.Println("The minimum is at x[0] =", x[0], "\b, x[1] =", x[1])
} </lang>
- Output:
Testing steepest descent method: The minimum is at x[0] = 0.10764302056464771, x[1] = -1.223351901171944
Julia
<lang julia>using Optim, Base.MathConstants
f(x) = (x[1] - 1) * (x[1] - 1) * e^(-x[2]^2) + x[2] * (x[2] + 2) * e^(-2 * x[1]^2)
println(optimize(f, [0.1, -1.0], GradientDescent()))
</lang>
- Output:
Results of Optimization Algorithm * Algorithm: Gradient Descent * Starting Point: [0.1,-1.0] * Minimizer: [0.107626844383003,-1.2232596628723371] * Minimum: -7.500634e-01 * Iterations: 14 * Convergence: true * |x - x'| ≤ 0.0e+00: false |x - x'| = 2.97e-09 * |f(x) - f(x')| ≤ 0.0e+00 |f(x)|: true |f(x) - f(x')| = 0.00e+00 |f(x)| * |g(x)| ≤ 1.0e-08: true |g(x)| = 2.54e-09 * Stopped by an increasing objective: false * Reached Maximum Number of Iterations: false * Objective Calls: 35 * Gradient Calls: 35
Perl
Calculate with bignum
for numerical stability.
<lang perl>use strict; use warnings; use bignum;
sub steepestDescent {
my($alpha, $tolerance, @x) = @_; my $N = @x; my $h = $tolerance; my $g0 = g(@x) ; # Initial estimate of result.
my @fi = gradG($h, @x) ; # Calculate initial gradient
# Calculate initial norm. my $delG = 0; for (0..$N-1) { $delG += $fi[$_]**2 } my $b = $alpha / sqrt($delG);
while ( $delG > $tolerance ) { # Iterate until value is <= tolerance. # Calculate next value. for (0..$N-1) { $x[$_] -= $b * $fi[$_] } $h /= 2;
@fi = gradG($h, @x); # Calculate next gradient. # Calculate next norm. $delG = 0; for (0..$N-1) { $delG += $fi[$_]**2 } $b = $alpha / sqrt($delG);
my $g1 = g(@x); # Calculate next value.
$g1 > $g0 ? ($alpha /= 2) : ($g0 = $g1); # Adjust parameter. } @x
}
- Provides a rough calculation of gradient g(x).
sub gradG {
my($h, @x) = @_; my $N = @x; my @y = @x; my $g0 = g(@x); my @z; for (0..$N-1) { $y[$_] += $h ; $z[$_] = (g(@y) - $g0) / $h } return @z
}
- Function for which minimum is to be found.
sub g { my(@x) = @_; ($x[0]-1)**2 * exp(-$x[1]**2) + $x[1]*($x[1]+2) * exp(-2*$x[0]**2) };
my $tolerance = 0.0000001; my $alpha = 0.01; my @x = <0.1 -1>; # Initial guess of location of minimum.
printf "The minimum is at x[0] = %.6f, x[1] = %.6f", steepestDescent($alpha, $tolerance, @x);</lang>
- Output:
The minimum is at x[0] = 0.107653, x[1] = -1.223370
Phix
... and just like Go, the results don't quite match anything else. <lang Phix>-- Function for which minimum is to be found. function g(sequence x)
atom {x0,x1} = x return (x0-1)*(x0-1)*exp(-x1*x1) + x1*(x1+2)*exp(-2*x0*x0)
end function
-- Provides a rough calculation of gradient g(x). function gradG(sequence x, atom h)
integer n = length(x) sequence z = repeat(0, n) atom g0 := g(x) for i=1 to n do x[i] += h z[i] = (g(x) - g0) / h end for return z
end function
function steepestDescent(sequence x, atom alpha, tolerance)
integer n = length(x) atom h = tolerance, g0 = g(x) -- Initial estimate of result.
-- Calculate initial gradient. sequence fi = gradG(x, h)
-- Calculate initial norm. atom delG = sqrt(sum(sq_mul(fi,fi))), b = alpha / delG
-- Iterate until value is <= tolerance. while delG>tolerance do -- Calculate next value. x = sq_sub(x,sq_mul(b,fi)) h /= 2 -- Calculate next gradient. fi = gradG(x, h) -- Calculate next norm. delG = sqrt(sum(sq_mul(fi,fi))) b = alpha / delG -- Calculate next value. atom g1 = g(x) -- Adjust parameter. if g1>g0 then alpha /= 2 else g0 = g1 end if end while return x
end function
constant tolerance = 0.0000006, alpha = 0.1 sequence x = steepestDescent({0.1,-1}, alpha, tolerance) printf(1,"Testing steepest descent method:\n") printf(1,"The minimum is at x[1] = %.16f, x[1] = %.16f\n", x)</lang>
- Output:
Testing steepest descent method: The minimum is at x[1] = 0.1076572080934996, x[1] = -1.2232976080475890 -- (64 bit) The minimum is at x[1] = 0.1073980565405569, x[1] = -1.2233251778997771 -- (32 bit)
Racket
Note the different implementation of grad
. I believe that the vector should be reset and only the partial derivative in a particular dimension is to be used. For this reason, I've _yet another_ result!
I could have used ∇ and Δ in the variable names, but it looked too confusing, so I've gone with grad- and del-
<lang racket>#lang racket
(define (apply-vector f v)
(apply f (vector->list v)))
- Provides a rough calculation of gradient g(v).
(define ((grad/del f) v δ #:fv (fv (apply-vector f v)))
(define dim (vector-length v)) (define tmp (vector-copy v)) (define grad (for/vector #:length dim ((i dim) (v_i v)) (vector-set! tmp i (+ v_i δ)) (define ∂f/∂v_i (/ (- (apply-vector f tmp) fv) δ)) (vector-set! tmp i v_i) ∂f/∂v_i)) (values grad (sqrt (for/sum ((∂_i grad)) (sqr ∂_i)))))
(define (steepest-descent g x α tolerance)
(define grad/del-g (grad/del g))
(define (loop x δ α gx grad-gx del-gx b) (cond [(<= del-gx tolerance) x] [else (define δ´ (/ δ 2)) (define x´ (vector-map + (vector-map (curry * (- b)) grad-gx) x)) (define gx´ (apply-vector g x´)) (define-values (grad-gx´ del-gx´) (grad/del-g x´ δ´ #:fv gx´)) (define b´ (/ α del-gx´)) (if (> gx´ gx) (loop x´ δ´ (/ α 2) gx grad-gx´ del-gx´ b´) (loop x´ δ´ α gx´ grad-gx´ del-gx´ b´))]))
(define gx (apply-vector g x)) (define δ tolerance) (define-values (grad-gx del-gx) (grad/del-g x δ #:fv gx)) (loop x δ α gx grad-gx del-gx (/ α del-gx)))
(define (Gradient-descent)
(steepest-descent (λ (x y) (+ (* (- x 1) (- x 1) (exp (- (sqr y)))) (* y (+ y 2) (exp (- (* 2 (sqr x))))))) #(0.1 -1.) 0.1 0.0000006))
(module+ main
(Gradient-descent))
</lang>
- Output:
'#(0.10760797905122492 -1.2232993981966753)
Raku
(formerly Perl 6)
<lang perl6>use v6.d;
sub steepestDescent(@x, $alpha is copy, $h is copy) {
my $g0 = g(@x) ; # Initial estimate of result.
my @fi = gradG(@x, $h, $g0) ; # Calculate initial gradient
# Calculate initial norm. my $b = $alpha / sqrt(my $delG = sum(map {$_²}, @fi));
while ( $delG > $h ) { # Iterate until value is <= tolerance.
for @fi.kv -> $i, $j { @x[$i] -= $b * $j } # Calculate next value. # Calculate next gradient and next value @fi = gradG(@x, $h /= 2, my $g1 = g(@x));
$b = $alpha / sqrt($delG = sum(map {$_²}, @fi) ); # Calculate next norm.
$g1 > $g0 ?? ( $alpha /= 2 ) !! ( $g0 = $g1 ) # Adjust parameter. }
}
sub gradG(@x is copy, $h, $g0) { # gives a rough calculation of gradient g(x).
return map { $_ += $h ; (g(@x) - $g0) / $h }, @x
}
- Function for which minimum is to be found.
sub g(\x) { (x[0]-1)² * exp(-x[1]²) + x[1]*(x[1]+2) * exp(-2*x[0]²) }
my $tolerance = 0.0000006 ; my $alpha = 0.1;
my @x = 0.1, -1; # Initial guess of location of minimum.
steepestDescent(@x, $alpha, $tolerance);
say "Testing steepest descent method:"; say "The minimum is at x[0] = ", @x[0], ", x[1] = ", @x[1]; </lang>
- Output:
Testing steepest descent method: The minimum is at x[0] = 0.10743450794656964, x[1] = -1.2233956711774543
REXX
<lang rexx>/*REXX pgm searches for minimum values of the bi─variate function (AKA steepest descent)*/ numeric digits length( e() ) % 2 tolerance= 0.0000006
alpha= 0.1 x.0= 0.1; x.1= -1; n= 2
say center(' testing for the steepest descent method ', 79, "═") call steepestD say 'The minimum is at: x[0]=' format(x.0,,4) " x[1]=" format(x.1,,4) exit /*stick a fork in it, we're all done. */ /*──────────────────────────────────────────────────────────────────────────────────────*/ gx: return (x.0-1)**2 * exp(- (x.1**2) ) + x.1 * (x.1 + 2) * exp(-2 * x.0**2) gy: return (y.0-1)**2 * exp(- (y.1**2) ) + y.1 * (y.1 + 2) * exp(-2 * y.0**2) /*──────────────────────────────────────────────────────────────────────────────────────*/ gradG: do j=0 for n; y.j= x.j /*copy X ──► Y */
end /*j*/ g0= gx() do j=0 for n; y.j= y.j + h z.j= (gy() - g0) / h end /*j*/ return
/*──────────────────────────────────────────────────────────────────────────────────────*/ steepestD: h= tolerance
g0= gx() call gradG delG= 0 do j=0 for n; delG= delG + z.j**2 end /*j*/ delG= sqrt(delG) b= alpha / delG
do while delG>tolerance do j=0 for n; x.j= x.j - b*z.j end /*j*/ h= h / 2 call gradG delG= 0 do j=0 for n; delG= delG + z.j**2 end /*j*/ delG= sqrt(delG) if delG=0 then return b= alpha / delG g1= gx() if g1>g0 then alpha= alpha / 2 else g0= g1 end /*while*/ return
/*──────────────────────────────────────────────────────────────────────────────────────*/ e: e= 2.7182818284590452353602874713526624977572470936999595749669676277240766303 || ,
535475945713821785; return e
/*──────────────────────────────────────────────────────────────────────────────────────*/ exp: procedure; parse arg x; ix= x%1; if abs(x-ix)>.5 then ix= ix + sign(x); x= x - ix
z=1; _=1; w=z; do j=1; _= _*x/j; z= (z+_)/1; if z==w then leave; w= z; end if z\==0 then z= z * e() ** ix; return z/1
/*──────────────────────────────────────────────────────────────────────────────────────*/ sqrt: procedure; parse arg x; if x=0 then return 0; d= digits(); numeric digits; h= d+6
numeric form; m.=9; parse value format(x,2,1,,0) 'E0' with g "E" _ .; g=g *.5'e'_ %2 do j=0 while h>9; m.j=h; h= h % 2 + 1; end /*j*/ do k=j+5 to 0 by -1; numeric digits m.k; g=(g+x/g)*.5; end /*k*/; return g</lang>
- output when using the internal default inputs:
═══════════════════ testing for the steepest descent method ═══════════════════ The minimum is at: x[0]= 0.1062 x[1]= -1.2264
Scala
<lang scala>object GradientDescent {
/** Steepest descent method modifying input values*/ def steepestDescent(x : Array[Double], learningRate : Double, tolerance : Double) = { val n = x.size var h = tolerance var alpha = learningRate var g0 = g(x) // Initial estimate of result.
// Calculate initial gradient. var fi = gradG(x,h)
// Calculate initial norm. var delG = 0.0 for (i <- 0 until n by 1) delG += fi(i) * fi(i) delG = math.sqrt(delG) var b = alpha / delG
// Iterate until value is <= tolerance. while(delG > tolerance){ // Calculate next value. for (i <- 0 until n by 1) x(i) -= b * fi(i) h /= 2
// Calculate next gradient. fi = gradG(x,h)
// Calculate next norm. delG = 0.0 for (i <- 0 until n by 1) delG += fi(i) * fi(i) delG = math.sqrt(delG) b = alpha / delG
// Calculate next value. var g1 = g(x)
// Adjust parameter. if(g1 > g0) alpha = alpha / 2 else g0 = g1 }
}
/** Gradient of the input function given in the task*/ def gradG(x : Array[Double], h : Double) : Array[Double] = { val n = x.size val z : Array[Double] = Array.fill(n){0} val y = x val g0 = g(x)
for(i <- 0 until n by 1){ y(i) += h z(i) = (g(y) - g0) / h }
z
}
/** Bivariate function given in the task*/ def g( x : Array[Double]) : Double = { ( (x(0)-1) * (x(0)-1) * math.exp( -x(1)*x(1) ) + x(1) * (x(1)+2) * math.exp( -2*x(0)*x(0) ) ) }
def main(args: Array[String]): Unit = { val tolerance = 0.0000006 val learningRate = 0.1 val x = Array(0.1, -1) // Initial guess of location of minimum.
steepestDescent(x, learningRate, tolerance) println("Testing steepest descent method") println("The minimum is at x : " + x(0) + ", y : " + x(1)) }
} </lang>
- Output:
Testing steepest descent method The minimum is at x : 0.10756393294495799, y : -1.2234116852966237
TypeScript
- Translation of
- [Numerical Methods, Algorithms and Tools in C# by Waldemar Dos Passos (18.2 Gradient Descent Method]
<lang Typescript> // Using the steepest-descent method to search // for minimum values of a multi-variable function export const steepestDescent = (x: number[], alpha: number, tolerance: number) => {
let n: number = x.length; // size of input array let h: number = 0.0000006; //Tolerance factor let g0: number = g(x); //Initial estimate of result
//Calculate initial gradient let fi: number[] = [n];
//Calculate initial norm fi = GradG(x, h); // console.log("fi:"+fi);
//Calculate initial norm let DelG: number = 0.0;
for (let i: number = 0; i < n; ++i) { DelG += fi[i] * fi[i]; } DelG = Math.sqrt(DelG); let b: number = alpha / DelG;
//Iterate until value is <= tolerance limit while (DelG > tolerance) { //Calculate next value for (let i = 0; i < n; ++i) { x[i] -= b * fi[i]; } h /= 2;
//Calculate next gradient fi = GradG(x, h); //Calculate next norm DelG = 0; for (let i: number = 0; i < n; ++i) { DelG += fi[i] * fi[i]; }
DelG = Math.sqrt(DelG); b = alpha / DelG;
//Calculate next value let g1: number = g(x);
//Adjust parameter if (g1 > g0) alpha /= 2; else g0 = g1; }
}
// Provides a rough calculation of gradient g(x). export const GradG = (x: number[], h: number) => {
let n: number = x.length; let z: number[] = [n]; let y: number[] = x; let g0: number = g(x);
// console.log("y:" + y);
for (let i = 0; i < n; ++i) { y[i] += h; z[i] = (g(y) - g0) / h; } // console.log("z:"+z); return z;
}
// Method to provide function g(x). export const g = (x: number[]) => {
return (x[0] - 1) * (x[0] - 1) * Math.exp(-x[1] * x[1]) + x[1] * (x[1] + 2) * Math.exp(-2 * x[0] * x[0]);
}
export const gradientDescentMain = () => {
let tolerance: number = 0.0000006; let alpha: number = 0.1; let x: number[] = [2];
//Initial guesses x[0] = 0.1; //of location of minimums x[1] = -1; steepestDescent(x, alpha, tolerance);
console.log("Testing steepest descent method"); console.log("The minimum is at x[0] = " + x[0] + ", x[1] = " + x[1]); // console.log("");
}
gradientDescentMain();
</lang>
- Output:
Testing steepest descent method The minimum is at x[0] = 0.10768224291553158, x[1] = -1.2233090211217854
Linear Regression
- Translation of
- [Linear Regression using Gradient Descent by Adarsh Menon]
<lang Typescript>
let data: number[][] =
[[32.5023452694530, 31.70700584656990], [53.4268040332750, 68.77759598163890], [61.5303580256364, 62.56238229794580], [47.4756396347860, 71.54663223356770], [59.8132078695123, 87.23092513368730], [55.1421884139438, 78.21151827079920], [52.2117966922140, 79.64197304980870], [39.2995666943170, 59.17148932186950], [48.1050416917682, 75.33124229706300], [52.5500144427338, 71.30087988685030], [45.4197301449737, 55.16567714595910], [54.3516348812289, 82.47884675749790], [44.1640494967733, 62.00892324572580], [58.1684707168577, 75.39287042599490], [56.7272080570966, 81.43619215887860], [48.9558885660937, 60.72360244067390], [44.6871962314809, 82.89250373145370], [60.2973268513334, 97.37989686216600], [45.6186437729558, 48.84715331735500], [38.8168175374456, 56.87721318626850], [66.1898166067526, 83.87856466460270], [65.4160517451340, 118.59121730252200], [47.4812086078678, 57.25181946226890], [41.5756426174870, 51.39174407983230], [51.8451869056394, 75.38065166531230], [59.3708220110895, 74.76556403215130], [57.3100034383480, 95.45505292257470], [63.6155612514533, 95.22936601755530], [46.7376194079769, 79.05240616956550], [50.5567601485477, 83.43207142132370], [52.2239960855530, 63.35879031749780], [35.5678300477466, 41.41288530370050], [42.4364769440556, 76.61734128007400], [58.1645401101928, 96.76956642610810], [57.5044476153417, 74.08413011660250], [45.4405307253199, 66.58814441422850], [61.8962226802912, 77.76848241779300], [33.0938317361639, 50.71958891231200], [36.4360095113868, 62.12457081807170], [37.6756548608507, 60.81024664990220], [44.5556083832753, 52.68298336638770], [43.3182826318657, 58.56982471769280], [50.0731456322890, 82.90598148507050], [43.8706126452183, 61.42470980433910], [62.9974807475530, 115.24415280079500], [32.6690437634671, 45.57058882337600], [40.1668990087037, 54.08405479622360], [53.5750775316736, 87.99445275811040], [33.8642149717782, 52.72549437590040], [64.7071386661212, 93.57611869265820], [38.1198240268228, 80.16627544737090], [44.5025380646451, 65.10171157056030], [40.5995383845523, 65.56230126040030], [41.7206763563412, 65.28088692082280], [51.0886346783367, 73.43464154632430], [55.0780959049232, 71.13972785861890], [41.3777265348952, 79.10282968354980], [62.4946974272697, 86.52053844034710], [49.2038875408260, 84.74269780782620], [41.1026851873496, 59.35885024862490], [41.1820161051698, 61.68403752483360], [50.1863894948806, 69.84760415824910], [52.3784462192362, 86.09829120577410], [50.1354854862861, 59.10883926769960], [33.6447060061917, 69.89968164362760], [39.5579012229068, 44.86249071116430], [56.1303888168754, 85.49806777884020], [57.3620521332382, 95.53668684646720], [60.2692143939979, 70.25193441977150], [35.6780938894107, 52.72173496477490], [31.5881169981328, 50.39267013507980], [53.6609322616730, 63.64239877565770], [46.6822286494719, 72.24725106866230], [43.1078202191024, 57.81251297618140], [70.3460756150493, 104.25710158543800], [44.4928558808540, 86.64202031882200], [57.5045333032684, 91.48677800011010], [36.9300766091918, 55.23166088621280], [55.8057333579427, 79.55043667850760], [38.9547690733770, 44.84712424246760], [56.9012147022470, 80.20752313968270], [56.8689006613840, 83.14274979204340], [34.3331247042160, 55.72348926054390], [59.0497412146668, 77.63418251167780], [57.7882239932306, 99.05141484174820], [54.2823287059674, 79.12064627468000], [51.0887198989791, 69.58889785111840], [50.2828363482307, 69.51050331149430], [44.2117417520901, 73.68756431831720], [38.0054880080606, 61.36690453724010], [32.9404799426182, 67.17065576899510], [53.6916395710700, 85.66820314500150], [68.7657342696216, 114.85387123391300], [46.2309664983102, 90.12357206996740], [68.3193608182553, 97.91982103524280], [50.0301743403121, 81.53699078301500], [49.2397653427537, 72.11183246961560], [50.0395759398759, 85.23200734232560], [48.1498588910288, 66.22495788805460], [25.1284846477723, 53.45439421485050]];
function lossFunction(arr0: number[], arr1: number[], arr2: number[]) {
let n: number = arr0.length; // Number of elements in X
//D_m = (-2/n) * sum(X * (Y - Y_pred)) # Derivative wrt m let a: number = (-2 / n) * (arr0.map((a, i) => a * (arr1[i] - arr2[i]))).reduce((sum, current) => sum + current); //D_c = (-2/n) * sum(Y - Y_pred) # Derivative wrt c let b: number = (-2 / n) * (arr1.map((a, i) => (a - arr2[i]))).reduce((sum, current) => sum + current); return [a, b];
}
export const gradientDescentMain = () => {
// Building the model let m: number = 0; let c: number = 0; let X_arr: number[]; let Y_arr: number[]; let Y_pred_arr: number[]; let D_m: number = 0; let D_c: number = 0;
let L: number = 0.00000001; // The learning Rate let epochs: number = 10000000; // The number of iterations to perform gradient descent
//Initial guesses for (let i = 0; i < epochs; i++) { X_arr = data.map(function (value, index) { return value[0]; }); Y_arr = data.map(function (value, index) { return value[1]; });
// The current predicted value of Y Y_pred_arr = X_arr.map((a) => ((m * a) + c));
let all = lossFunction(X_arr, Y_arr, Y_pred_arr); D_m = all[0]; D_c = all[1];
m = m - L * D_m; // Update m c = c - L * D_c; // Update c }
console.log("m: " + m + " c: " + c);
}
gradientDescentMain(); </lang>
Wren
Slightly different result but close enough. <lang ecmascript>import "/math" for Math import "/fmt" for Fmt
// Function for which minimum is to be found. var f = Fn.new { |x, y| (x-1)*(x-1)*Math.exp(-y*y) + y*(y+2)*Math.exp(-2*x*x) }
// Provides a rough calculation of gradient f(x, y). var gradG = Fn.new { |f, x, y, h|
var g0 = f.call(x, y) return [(f.call(x + h, y) - g0) / h, (f.call(x, y + h) - g0) / h]
}
var steepestDescent = Fn.new { |f, x, y, alpha, h|
var g0 = f.call(x, y) // Initial estimate of result. var gra = gradG.call(f, x, y, h) // Calculate initial gradient. var fix = gra[0] var fiy = gra[1]
// Calculate initial norm. var delG = (fix*fix + fiy*fiy).sqrt var b = alpha/delG
// Iterate until value is <= tolerance. while (delG > h) { x = x - b*fix y = y - b*fiy
// Calculate next gradient and next value. h = h / 2 gra = gradG.call(f, x, y, h) fix = gra[0] fiy = gra[1]
// Calculate next norm. delG = (fix*fix + fiy*fiy).sqrt b = alpha/delG
// Adjust parameter. var g1 = f.call(x, y) if (g1 > g0) { alpha = alpha / 2 } else { g0 = g1 } } return [x, y]
}
var tolerance = 0.0000006 var alpha = 0.1
// Initial guess of location of minimum. var x = 0.1 var y = -1 var sd = steepestDescent.call(f, x, y, alpha, tolerance) x = sd[0] y = sd[1] System.print("Testing steepest descent method:") Fmt.print("The minimum is at (x, y) = ($f, $f). f(x, y) = $f", x, y, f.call(x, y))</lang>
- Output:
Testing steepest descent method: The minimum is at (x, y) = (0.107612, -1.223291). f(x, y) = -0.750063
zkl
with tweaked gradG
<lang zkl>fcn steepestDescent(f, x,y, alpha, h){
g0:=f(x,y); # Initial estimate of result. fix,fiy := gradG(f,x,y,h); # Calculate initial gradient # Calculate initial norm. b:=alpha / (delG := (fix*fix + fiy*fiy).sqrt()); while(delG > h){ # Iterate until value is <= tolerance. x,y = x - b*fix, y - b*fiy; # Calculate next gradient and next value fix,fiy = gradG(f,x,y, h/=2); b=alpha / (delG = (fix*fix + fiy*fiy).sqrt()); # Calculate next norm. if((g1:=f(x,y)) > g0) alpha/=2 else g0 = g1; # Adjust parameter. } return(x,y)
}
fcn gradG(f,x,y,h){ # gives a rough calculation of gradient f(x,y).
g0:=f(x,y); return((f(x + h, y) - g0)/h, (f(x, y + h) - g0)/h)
}</lang> <lang zkl>fcn f(x,y){ # Function for which minimum is to be found.
(x - 1).pow(2)*(-y.pow(2)).exp() + y*(y + 2)*(-2.0*x.pow(2)).exp()
}
tolerance,alpha := 0.0000006, 0.1;
x,y := 0.1, -1.0; # Initial guess of location of minimum. x,y = steepestDescent(f,x,y,alpha,tolerance);
println("Testing steepest descent method:"); println("The minimum is at (x,y) = (%f,%f). f(x,y) = %f".fmt(x,y,f(x,y)));</lang>
- Output:
Testing steepest descent method: The minimum is at (x,y) = (0.107608,-1.223299). f(x,y) = -0.750063