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I have started this code a month ago and after struggling with optimx and the function design finally I've managed to have it up and running, but the new issue is time needed to complete the processing as it takes almost 45 mins to complete 18 parameters on DualCore 3Ghz processor. My concerns are:

1- Is this time normal for R? if so what are the other options? I was talking with a professor from the statistics and he stated I might switch to Matlab but I am not sure and I don't want to start re-writing all the code in Matlab before I make sure from the experienced users that Matlab has more computational capacity and reliability in non-linear optimization problems for the same hardware setting.

2- If this time is not normal how can I speed it up and how difficult to run the code in parallel giving that I have 0 hands on parallelization, the code is a nonlinear optimization for 18 parameters and I expect them to be more than that.

The Code:

INJ.1<-"I01 I02 I03 I04 I05         
2.78E+02    1.82E+03    3.62E+02    2.90E+02    7.73E+02
7.92E+02    1.21E+03    9.33E+02    6.32E+02    5.10E+02
2.30E+03    7.54E+02    9.60E+02    6.29E+02    1.05E+03
3.61E+03    3.05E+02    7.77E+02    5.87E+02    1.02E+03
3.89E+02    1.35E+03    7.66E+02    4.00E+02    7.43E+02
1.31E+03    1.63E+03    8.95E+02    3.85E+02    1.10E+02
1.39E+03    1.16E+03    9.07E+02    4.99E+02    2.48E+02
1.94E+03    1.09E+03    8.34E+02    5.22E+02    2.48E+02
2.04E+03    1.11E+03    7.85E+02    2.67E+02    4.27E+02
1.06E+03    1.36E+03    8.80E+02    6.13E+02    7.16E+02
1.40E+03    1.29E+03    8.65E+02    6.17E+02    9.79E+02
1.20E+03    1.68E+03    6.78E+02    6.10E+02    9.30E+02
1.45E+03    1.49E+03    7.66E+02    3.81E+02    1.07E+03
1.16E+03    1.58E+03    1.09E+03    5.33E+02    8.38E+02
1.33E+03    1.38E+03    9.10E+02    6.29E+02    8.80E+02
1.33E+03  1.38E+03  9.10E+02    6.29E+02    8.80E+02
1.47E+03    1.33E+03    9.56E+02    5.79E+02    1.21E+03
1.87E+03    1.60E+03    1.08E+03    5.33E+02    1.22E+03
1.57E+03    1.76E+03    7.89E+02    5.87E+02    9.79E+02
9.68E+02    1.89E+03    8.08E+02    5.14E+02    1.08E+03
6.13E+02    1.79E+03    8.38E+02    5.37E+02    1.12E+03
1.38E+03    1.66E+03    8.19E+02    5.64E+02    9.90E+02
1.42E+03    1.55E+03    8.27E+02    5.79E+02    8.08E+02
1.35E+03    1.70E+03    9.37E+02    6.40E+02    6.82E+02
1.49E+03    1.70E+03    7.47E+02    6.86E+02    1.05E+03
7.62E+02    1.66E+03    7.01E+02    6.13E+02    7.92E+02
1.30E+03    1.62E+03    7.09E+02    6.13E+02    6.67E+02
1.47E+03    1.31E+03    6.55E+02    5.68E+02    7.16E+02
1.38E+03    1.56E+03    5.60E+02    6.97E+02    7.70E+02
1.40E+03    1.61E+03    6.82E+02    6.90E+02    7.89E+02
1.31E+03    1.58E+03    8.61E+02    7.20E+02    1.42E+03
8.80E+02    1.58E+03    8.38E+02    7.09E+02    1.46E+03
1.40E+03    1.57E+03    8.57E+02    6.74E+02    1.33E+03
1.15E+03    1.54E+03    7.85E+02    6.82E+02    1.44E+03
1.51E+03    1.53E+03    8.23E+02    6.74E+02    1.23E+03
1.08E+03    1.54E+03    8.04E+02    6.74E+02    1.19E+03
1.57E+03    1.54E+03    7.28E+02    7.01E+02    1.15E+03
1.78E+03    1.49E+03    7.85E+02    7.43E+02    1.20E+03
1.87E+03    1.46E+03    8.69E+02    8.57E+02    8.72E+02
2.14E+03    1.41E+03    1.01E+03    8.27E+02    1.78E+03
2.01E+03    1.46E+03    1.02E+03    7.73E+02    1.55E+03
1.99E+03    1.40E+03    1.11E+03    7.16E+02    1.39E+03
2.22E+03    1.44E+03    1.14E+03    7.01E+02    1.19E+03
2.11E+03    1.48E+03    9.03E+02    7.81E+02    1.21E+03
2.48E+03    1.28E+03    7.35E+02    7.28E+02    1.26E+03
2.40E+03    1.26E+03    1.07E+03    8.61E+02    1.07E+03
2.40E+03    1.17E+03    1.20E+03    8.50E+02    1.22E+03
2.43E+03    7.85E+02    1.26E+03    8.27E+02    1.07E+03
2.64E+03    6.55E+02    1.23E+03    8.15E+02    1.03E+03
2.60E+03    6.13E+02    8.27E+02    7.24E+02    9.41E+02
2.35E+03    6.74E+02    9.37E+02    6.55E+02    9.30E+02
2.77E+03    5.45E+02    1.01E+03    7.43E+02    1.14E+03
2.96E+03    6.13E+02    9.30E+02    8.42E+02    9.98E+02
3.15E+03    5.45E+02    8.95E+02    8.11E+02    1.21E+03
7.28E+02    6.06E+02    8.91E+02    8.57E+02    1.18E+03
1.59E+03    6.78E+02    8.76E+02    8.30E+02    1.23E+03
1.79E+03    4.23E+02    8.88E+02    8.19E+02    1.26E+03
4.50E+02    1.96E+03    8.38E+01    1.03E+03    1.94E+02
1.17E+03    8.65E+02    4.04E+02    7.31E+02    8.50E+02
1.68E+03    1.28E+03    1.49E+02    9.90E+02    1.58E+03
1.65E+03    1.43E+03    7.20E+02    1.19E+03    2.22E+03
1.71E+03    1.39E+03    8.30E+02    8.46E+02    2.01E+03
1.64E+03    5.83E+02    6.86E+02    9.75E+02    1.45E+03
1.57E+03    8.42E+02    5.18E+02    1.10E+03    1.19E+03
1.87E+03    1.10E+03    1.83E+02    1.13E+03    9.94E+02
1.82E+03    9.52E+02    2.32E+02    1.16E+03    1.22E+03
1.51E+03    0.00E+00    1.26E+02    1.68E+03    1.28E+03
1.39E+03    0.00E+00    2.48E+02    1.31E+03    1.10E+03
1.45E+03    0.00E+00    2.90E+02    1.24E+03    1.09E+03
1.43E+03    0.00E+00    4.19E+02    1.61E+03    1.28E+03
1.38E+03    0.00E+00    2.10E+02    1.68E+03    1.23E+03
1.07E+03    0.00E+00    5.03E+02    1.38E+03    1.21E+03
1.37E+03    0.00E+00    6.59E+02    1.44E+03    1.04E+03
1.37E+03    0.00E+00    9.45E+02    1.83E+03    1.28E+03
1.33E+03    0.00E+00    9.03E+02    1.66E+03    8.19E+02

"
INJ<-as.matrix(read.table(text=INJ.1, header=T))
PRD.1<-"P01                
981.32019             
1062.5702             
1439.7673             
1694.0723             
1085.1016             
1243.6089             
1191.5941             
1302.2167             
1333.5266             
1242.0212             
1342.6954             
1371.2767             
1394.1171             
1400.7926             
1373.1791
1194.7649
1289.6071
1413.0968
1313.444
1243.9548
1187.6825
1225.5112
1186.6755
1195.6844
1290.3555
1107.2397
1100.14
1075.3673
1121.7092
1168.071
1377.4421
1354.8871
1375.5179
1363.9353
1355.4352
1287.1311
1317.6824
1383.2178
1365.5146
1658.0327
1625.3192
1568.1354
1542.4583
1511.9888
1493.4116
1529.6499
1590.22
1516.1698
1489.6599
1344.8517
1294.4697
1416.6488
1446.6407
1513.5117
1218.4484
1266.1337
1281.0219
915.39948
966.0614
1309.4725
1736.4828
1685.2651
1416.7249
1316.5566
1260.5198
1309.8859
1282.8658
1124.2899
1090.3422
1259.1481
1243.2527
1170.8752
1197.361
1434.2209
1291.3245
"
PRD<-as.matrix(read.table(text=PRD.1, header=T))

PR.1<-"P01  P02 P03 P04
998.5638    810 528 689
999.5638    857 985 880
1000.5638   841 552 625
1001.5638   835 742 546
1002.5638   565 745 872
1003.5638   752 957 964
1004.5638   726 987 737
1005.5638   861 695 845
1006.5638   919 938 577
1007.5638   721 631 854
1008.5638   820 702 631
1009.5638   879 648 744
1010.5638   698 820 783
1011.5638   772 679 536
1012.5638   767 785 803
1012.56378  767 785 803
1013.56378  910 775 513
1014.56378  540 828 770
1015.56378  581 723 695
1016.56378  759 580 895
1017.56378  640 863 936
1018.56378  554 735 979
1019.56378  920 748 684
1020.56378  812 613 511
1021.56378  877 851 988
1022.56378  525 894 585
1023.56378  772 534 839
1024.56378  907 631 976
1025.56378  699 724 774
1026.56378  844 647 881
1027.56378  953 885 811
1028.56378  690 776 836
1029.56378  712 660 617
1030.56378  648 669 966
1031.56378  880 525 507
1032.56378  773 700 702
1033.56378  504 541 570
1034.56378  793 860 652
1035.56378  809 766 649
1036.56378  860 847 677
1037.56378  757 909 932
1038.56378  900 594 509
1039.56378  962 987 994
1040.56378  648 958 675
1041.56378  952 971 800
1042.56378  917 900 840
1043.56378  791 553 721
1044.56378  782 615 640
1045.56378  674 563 504
1046.56378  637 988 595
1047.56378  671 809 812
1048.56378  639 786 558
1049.56378  837 610 505
1050.56378  752 950 524
1051.56378  831 807 622
1052.56378  547 949 864
1053.56378  755 839 534
1054.56378  500 517 724
1055.56378  644 507 867
1056.56378  692 804 891
1057.56378  713 726 800
1058.56378  898 952 777
1059.56378  761 587 670
1060.56378  959 847 949
1061.56378  562 667 678
1062.56378  643 863 513
1063.56378  672 996 638
1064.56378  707 890 723
1065.56378  878 794 629
1066.56378  719 512 859
1067.56378  672 944 794
1068.56378  727 963 613
1069.56378  589 831 675
1070.56378  621 945 953
1071.56378  561 796 563

"

PR<-as.matrix(read.table(text=PR.1, header=T))
lambda=c(0.0865382447763093, 0.0548765126242383, 
         0.0931262173744562, 0.106388796980127, 
         0.14140614108626,0.6326083, 0.3616249, 
         0.4217125, 0.3821551, 0.5059075,1,1,1,1,1,
         0.0171603825377974, 0.00298285562229438, 
         0.000573790646237408)
#const. i.dash
fn1 <- function (lambda){
  #const. i.dash
  i.dash=matrix(ncol=ncol(INJ), nrow=(nrow(INJ)))
  for (i in 1:ncol(INJ)){
    for (j in 1:nrow (INJ)){
      temp=0
      for (k in 1:j){
        temp=(1/lambda[ncol(INJ)+i])*exp((k-j)/lambda[ncol(INJ)+i])*INJ[k,i]+temp
      }
      i.dash[j,i]=temp
    }
  }
  ### preparing the i dash X lambda matrix
  lambda.i=matrix(ncol=ncol(INJ),nrow=nrow(INJ))
  for (i in 1: ncol(INJ)){
    lambda.i[,i]=lambda[i+1]*i.dash[,i]
  }
  q.hat=matrix(1,nrow=nrow(i.dash), data=rowSums(lambda.i))



  #########################constructing BHP matrix #####################

  #######################preparing the BHP matrix#######################

  ##Preparing the 1st term (Pwf(n0)e)

  bhp.1term=matrix(ncol=ncol(PR), nrow=nrow(PR))
  for ( k in 1: ncol(PR))
    for (i in 1: nrow(PR)){
      bhp.1term[i,k]=PR[1,k]*exp((1-i)/lambda[((2*ncol(INJ))+k)])
    }
  ##Preparing the 2nd  term (Pwfkj) 
  bhp.2term=matrix(ncol=ncol(PR), nrow=nrow(PR))
  bhp.2term=PR
  bhp.3term=matrix(ncol=ncol(PR), nrow=nrow(PR))
  ## Preparing the 3rd term(P'wfkj)
  for ( k in 1: ncol(PR)){
    for (l in 1: nrow(PR)){
      temp=0
      for (m in 1:l){
        temp=(1/lambda[((2*ncol(INJ))+k)]*exp((m-l)/lambda[((2*ncol(INJ))+k)])*PR[m,k]+temp)
      }
      bhp.3term[l,k]=temp
    }
  }
  #################### wrapping up ##############################
  bhp.master=matrix(ncol=ncol(PR), nrow=nrow(PR))
  bhp.master=bhp.3term+bhp.2term+bhp.1term
  BHP.nue=matrix(ncol=ncol(PR), nrow=nrow(PR), data =0)
  for ( i in 1: nrow (PR)){
    for ( j in 1: ncol (PR)){
      BHP.nue[i,j]=bhp.master[i,j]*lambda[(2*ncol(INJ))+ncol(PR)+j]+BHP.nue[i,j]
    }
  }  

  q.hat=q.hat+rowSums(BHP.nue)

  #################################################################
  mini=(PRD-q.hat)^2
  final=sum(mini)
  return(final)
}
ini=lambda
mm=fn1(ini)
lamb=optimx(ini,fn1,hessian=T,itnmax=100,method=c("BFGS"), control=list(trace=5))
share|improve this question
    
You are basically throwing the kitchen sink at the problem with optimx. The header of the help page says it calls: "spg from the BB package, ucminf, nlm, and nlminb... [and] optim() itself". The complexity of your objective function will also affect execution time. You need to include that if you want advice. You should also consider using the results of the first run to determine which methods are most effective. –  BondedDust Sep 6 '13 at 5:31
    
@DWin I checked all the methods and it seems that the BFGS works best although my function is not analytic. It might a mistake that I kept using optimx other than optim as I understood that optimx is a wrapper function only, even with optim I am still experiencing long processing time. Is there any way to parallize the code and will that work, if there is no hope what are the available options that you may recommend. –  Athii Sep 6 '13 at 5:50
    
Read my second and third sentences again. –  BondedDust Sep 6 '13 at 13:43
    
I read your comment already and I am asking this question "Is there any way to parallize the code and will that work, if there is no hope what are the available options that you may recommend" –  Athii Sep 6 '13 at 17:55

1 Answer 1

I am having a similar problem with the speed of optim() and it is taking much longer than 45 minutes - which doesn't seem too bad but I will try to help you out anyway!

I don't believe that you can an optimization function in parallel in any case since it takes steps sequentially towards a supposed max or min. If you figure that out, let me know!

I just saw this post about using the different optimization methods with optimx() and this might speed the process up. Have you tried this:

https://stat.ethz.ch/pipermail/r-help/2011-February/267999.html

If that doesn't help, I would suggest reading the Performance Criteria and Nonconvergence section of this IBM article:

http://www.ibm.com/developerworks/library/ba-optimR-john-nash/

It suggests this:

"You want to spend your effort on speeding up the objective function. It is sometimes worth putting the objective function in Fortran. The optim() function can accept a .Call expression to compiled code instead of an R function (to evaluate the objective function). Write the optimizer in R so everyone can see the implementation. The R package that is called microbenchmark runs something like a hundred times and gives you the distribution of times taken. This information is useful if you want to see where a problem is taking time."

R can compile code in Fortran and C which will run much faster. This is a nice trick for speeding up FOR loops in R and they are saying that writing the function you are optimizing in either of these languages will likely speed it up.

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