2

I'm working with the MF-DFA method in Matlab but I need to implement it in Julia. The goal is tho obtain the Hurst exponent of the S&P 500. The matlab code is as follows:

sp500 = readtable('sp500_Nasdaq.csv','PreserveVariableNames', true) ;
spClose = table2array(sp500(:,2))  ;

SP1=cumsum(spClose - mean(spClose)) ;
SP1_ordinary=sqrt(mean(SP1.^2));
X=cumsum(spClose-mean(spClose));
X=transpose(X);
scale=[16,32,64,128,256,512,1024];
q=[-5,-3,-1,0,1,3,5];
m=1;
for ns=1:length(scale),
segments(ns)=floor(length(X)/scale(ns));
for v=1:segments(ns)
  Index=( ( ( (v-1)*scale(ns) )+1):(v*scale(ns)));
  C = polyfit(Index,X(Index),m) ;
  fit=polyval(C,Index);
  RMS{ns}(v)=sqrt(mean((X(Index)-fit).^2));
end
for nq=1:length(q),
  qRMS{nq,ns}=RMS{ns}.^q(nq);
  Fq(nq,ns)=mean(qRMS{nq,ns}).^(1/q(nq));
end
  Fq(q==0,ns)=exp(0.5*mean(log(RMS{ns}.^2)));
end

The Julia the code looks like this:

using DelimitedFiles, TimeSeries, Plots, DelimitedFiles, Plots, StatsBase
using Polynomials, LinearAlgebra, CSV, DataFrames

sp500 = CSV.read("sp500_Nasdaq.csv", DataFrame) 
sp500_V = values(sp500[:,2]) 
SP1 = cumsum(sp500_V .- mean(sp500_V) ) ; 
SP1_Ord = sqrt(mean(SP1.^2)) ;
X = SP1 ;
X = X';
function polyfit(xVals,yVals)
   n = length(xVals)
   xBar, yBar = @fastmath mean(xVals), mean(yVals)
   sXX, sXY = @fastmath ones(n)'*(xVals.-xBar).^2 , dot(xVals.-xBar,yVals.-yBar)
   b1A = @fastmath sXY/sXX
   b0A = @fastmath yBar - b1A*xBar
return b0A, b1A
end

scales = [16,32,64,128,256,512,1024];
q = [-5,-3,-1,0,1,3,5] ;
segments = zeros(Int64, (1,length(scales)))
global qRMS = zeros( length(q) ,length(scales)  ) ;
global Fq = zeros( length(q) , length(scales) ) ;
@inbounds for ns = 1:length(scales)
global segments[ns] = Int(floor( length(X)/scales[ns] ) ) ;  
global Index = Array{UnitRange{Int128}}(undef, (segments[ns], length(scales))  ) ;
global ft = zeros(Float64, (segments[ns], length(scales) ) ) ;
global RMS = zeros(Float64, (length(scales) ,segments[ns] ) ) ;

@inbounds  for v=1:segments[ns]
    global RMSk = Array{Float64}[] ;
    Index =  ( ( (v-1)*scales[ns] ) + 1 ):( v*scales[ns] ) ;
    global C = polyfit( Index, X[Index]) ;
    global p = Polynomial(C)
    ft =p.(Index);
    RMS[ns,v] = sqrt(mean((X[Index] .- ft).^2));
    push!(RMSk,RMS )
end
@inbounds for nq = 1:length(q)
    qRMS[nq,ns] = RMS[ns].^q[nq];
    Fq[nq,ns] = mean( qRMS[nq,ns] ).^(1/q[nq] );
end
Fq[findall(x->x==0, q)[1], ns] = exp( 0.5*mean(log.(RMS[ns].^2) ) ) ;
end

The thing is that the array RMS in Matlab's code is an array of arrays like this:

RMS =

1×7 cell array

{1×159 double}    {1×79 double}    {1×39 double}    {1×19 double}    {1×9 double}    {1×4 double}    {1×2 double}

But Julia returns only the last array

RMS
7×2 Matrix{Float64}:
 0.0      0.0
 0.0      0.0
 0.0      0.0
 0.0      0.0
 0.0      0.0
 0.0      0.0
62178.0  18238.2

How can I obtain the same output as in Matlab? How can you store arrays into arrays in Julia?

0

The solutions for this is to use RMScell = Array{Float64}[] is equivalent to a Matlab cell array

using DelimitedFiles, TimeSeries, Plots, DelimitedFiles, Plots
using Polynomials, LinearAlgebra, CSV, DataFrames, StatsBase

sp500 = CSV.read("sp500_Nasdaq.csv", DataFrame) ;
sp500_V = values(sp500[:,2]) ;
SP1 = cumsum( sp500_V .- mean(sp500_V) ) ; 
SP1_Ord = sqrt( mean(SP1.^2) ) ;

X = SP1 ;
X = X' ;
function polyfit(xVals,yVals)
   n = length(xVals)
   xBar, yBar = @fastmath mean(xVals), mean(yVals)
   sXX, sXY = @fastmath ones(n)'*(xVals.-xBar).^2 , dot(xVals.-  xBar,yVals.-yBar)
   b1A = @fastmath sXY/sXX
   b0A = @fastmath yBar - b1A*xBar
return b0A, b1A
end
""" Multifractal detrended fluctuation analysis of time series """
scales = [16,32,64,128,256,512,1024];
q = [-5,-3,-1,0,1,3,5] ;
segments = zeros(Int64, (1,length(scales))) ;
global qRMS = zeros( length(q) ,length(scales)  ) ;
global Fq = zeros( length(q) , length(scales) ) ;
global RMScell = Array{Float64}[] ;
global qRMScell =[] ;
global segmentsFq = [] ;
@inbounds for ns = 1:length(scales)
global segments[ns] = Int(floor( length(X)/scales[ns] ) ) ;  
global ft = zeros(Float64, (segments[ns], length(scales) ) ) ;
global RMS = zeros(Float64, segments[ns]);
@inbounds  for v=1:segments[ns]
    global Index = ( (v-1)*scales[ns] ) + 1: v*scales[ns] ;
    global C = polyfit( Index, X[Index]) ;
    global p = Polynomial(C) ;
    ft =p.(Index) ;
    RMS[v] = sqrt(mean((X[Index] .- ft).^2))  ;
    end
    l = deepcopy(RMS)
    push!(RMScell,l)
    global IndexFq = ((ns-1)*length(q) ) + 1 : ns*length(q) ;
    push!(segmentsFq, IndexFq) ;
@inbounds for nq = 1:length(q)
    l = RMScell[ns].^q[nq]
    r = deepcopy(l) ;
    push!(qRMScell, r) ;
    end
@inbounds for nq = 1: length(scales)
    Fq[nq,ns] = mean( qRMScell[segmentsFq[ns]][nq] ).^(1/q[nq] ) ;
    end
Fq[findall(x->x==0, q)[1], ns] = exp( 0.5*mean(log.(RMScell[ns].^2) ) ) ;

end

Hq = zeros( Float64,length(q) ) ;
global qRegLine = Array{Float64}[] ;
for  nq = 1:length(q)
global C = polyfit( log2.(scales),log2.(Fq[nq,:]) ) ;
Hq[nq] = C[2] ;
global p = Polynomial(C) ;
push!( qRegLine, p.( log2.(scales) ) )
end


tq = Hq.*q .- 1 ;
hq = diff(tq)./(q[2]-q[1]) ;
Dq = ( q[1:end-1].*hq ) - tq[1:end-1] ;
1
  • You almost certainly don't want Array{Float64}[]. You probably want Vector{Float64}[] or Matrix{Float64}[]. Nov 24 '21 at 1:13

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.