(42S) HP 42S/ DM42: Nelder Mead Optimization
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04-30-2020, 11:19 AM
(This post was last modified: 05-03-2020 07:37 PM by Gene.)
Post: #1
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(42S) HP 42S/ DM42: Nelder Mead Optimization
Nelder Mead Optimization of a function of 2 variables.
References: https://en.wikipedia.org/wiki/Nelder–Mead_method Application: Precondition: The function that is to be optimized is in the subroutine “FU”.’ Input of FU is value of variable X in the X register and of variable Y in the Y-register. Output of FU is f(X,Y) in the X-register. Note: NMO searches a minimum of f(X,Y). If a maximum has to be searched take the negative of f(X,Y) as output of FU. Program uses registers 00 and 05 until 19. Input: Termination criterion: (a small number, e.g. .0001) in register 00. Original length of search steps (the more shallow the function is the larger, e.g. .2 to .5): Register Z Starting point for variable Y: Register Y Starting point of variable X: Register X Output is on the stack: Z-register: Function value f(X,Y) at minimum Y-register: Y X-register: X Example: Use Function FU as listed below. This function is a banana-shaped function that is used in literature as a difficult to optimize function f(X,Y) = 100*(X²-Y)²+(1-X)² The minimum is at X=Y=1 and f(1,1)=0. We start with a first estimate of X=-2, Y=2 and a step width of 0.2. The termination criterion is .0001. Input is as follows: .0001 STO 00 .2 ENTER 2 ENTER -2 CATALOG – PGM – NMO Output: Z: 1.9662E-10 Estimate of function at minimum Y: 1.0000 Estimate of Y at minimum X: 1.0000 Estimate of X at minimum 00 { 274-Byte Prgm } 01▸LBL "NMO" 02 STO 05 03 STO 08 04 STO 11 05 R↓ 06 STO 06 07 STO 09 08 STO 12 09 R↓ 10 STO+ 08 11 2 12 ÷ 13 STO+ 11 14 3 15 SQRT 16 × 17 STO+ 12 18 RCL 06 19 RCL 05 20 XEQ "FU" 21 STO 07 22 XEQ 31 23 XEQ 11 24▸LBL 01 25 RCL 05 26 RCL 08 27 + 28 2 29 ÷ 30 STO 14 31 RCL 06 32 RCL 09 33 + 34 2 35 ÷ 36 STO 15 37 XEQ 21 38 RCL 05 39 RCL 08 40 - 41 X↑2 42 RCL 06 43 RCL 09 44 - 45 X↑2 46 + 47 SQRT 48 RCL 05 49 RCL 11 50 - 51 X↑2 52 RCL 06 53 RCL 12 54 - 55 X↑2 56 + 57 SQRT 58 + 59 2 60 ÷ 61 RCL 00 62 X<Y? 63 GTO 01 64 RCL 07 65 RCL 06 66 RCL 05 67 RTN 68▸LBL 11 69 RCL 10 70 RCL 07 71 X≤Y? 72 GTO 12 73 STO 10 74 X<>Y 75 STO 07 76 RCL 05 77 RCL 08 78 STO 05 79 X<>Y 80 STO 08 81 RCL 06 82 RCL 09 83 STO 06 84 X<>Y 85 STO 09 86▸LBL 12 87 RCL 13 88 RCL 10 89 X≤Y? 90 GTO 13 91 STO 13 92 X<>Y 93 STO 10 94 RCL 08 95 RCL 11 96 STO 08 97 X<>Y 98 STO 11 99 RCL 09 100 RCL 12 101 STO 09 102 X<>Y 103 STO 12 104 GTO 11 105▸LBL 13 106 RTN 107▸LBL 21 108 1 109 STO 19 110 XEQ 24 111 RCL 13 112 X<Y? 113 GTO 23 114 RCL 18 115 RCL 10 116 X>Y? 117 GTO 22 118 R↓ 119 RCL 07 120 X≤Y? 121 GTO 22 122 2 123 STO 19 124▸LBL 22 125 RCL 16 126 STO 11 127 RCL 17 128 STO 12 129 RCL 18 130 STO 13 131 XEQ 11 132 RTN 133▸LBL 23 134 0.5 135 STO 19 136 XEQ 24 137 RCL 13 138 X>Y? 139 GTO 22 140 2 141 STO÷ 08 142 STO÷ 09 143 STO÷ 11 144 STO÷ 12 145 RCL 05 146 2 147 ÷ 148 STO+ 08 149 STO+ 11 150 RCL 06 151 2 152 ÷ 153 STO+ 09 154 STO+ 12 155 XEQ 31 156 XEQ 11 157 RTN 158▸LBL 24 159 RCL 15 160 RCL 12 161 - 162 RCL 19 163 × 164 RCL 15 165 + 166 STO 17 167 RCL 14 168 RCL 11 169 - 170 RCL 19 171 × 172 RCL 14 173 + 174 STO 16 175 XEQ "FU" 176 STO 18 177 RTN 178▸LBL 31 179 RCL 09 180 RCL 08 181 XEQ "FU" 182 STO 10 183 RCL 12 184 RCL 11 185 XEQ "FU" 186 STO 13 187 RTN 188 END 00 { 24-Byte Prgm } 01▸LBL "FU" 02 STO 01 03 X↑2 04 X<>Y 05 STO 02 06 - 07 X↑2 08 100 09 × 10 1 11 RCL 01 12 - 13 X↑2 14 + 15 RTN 16 END |
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04-30-2020, 09:39 PM
Post: #2
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RE: HP 42S/ DM42: Nelder Mead Optimization
Very nice, thanks!
Could you please give us a few comments about the code: - expand, contract, shrink (etc) functions (ie LBLs in the code?) - use of the registers (simplex coordinates, number of iterations) There should also be a way for DM42 users to draw the simplex evolutions, or at least print the steps used. Regards, Thibault |
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05-01-2020, 05:14 AM
(This post was last modified: 05-01-2020 03:13 PM by rawi.)
Post: #3
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RE: HP 42S/ DM42: Nelder Mead Optimization
Hi,
Thank you very much for your interest. First some explanation concerning the code: Use of registers: 00 --> Minimum termination criterion 19 --> Factor for reflection ______Simplex___*)_new point x_____05_08_11_14_16 y_____06_09_12_15_17 f(x,y)__07_10_13____18 *) center for reflection: Mean of best and second best value Values of simplex are sorted so that 07 is the minimum and 13 the maximum The code: Steps 2 to 17: Building the simplex 18 - 22: Computing function values 23: Sorting the simplex so that 05, 06, 07 is the minimum 11, 12, 13 the maximum 25 - 36: computing the center for reflection 37: Optimization explanation see later 38 - 60: computing of termination criterion This is a change to the original Nelder Mead method, where the termination criterion is the differences in function values f(x,y). I thought it is better to take the differences of the x and y values instead. 61 - 63: Comparison of termination criterion with minimum termination criterion. Continue process if not yet reached. 64 - 67: final steps and end of program 68 - 106: Sorting the points of the simplex. 107 - 157: Optimization procedure 108 - 109: Sets reflection factor to standard 110: Subroutine 24 does the reflection. New x an y are stored in 16 and 17 and new function value is in 18 111 - 113: If the new value is worse than the worst of the simplex goto 23 line 133ff (explanation see later) 114 - 121: If new value is better than the worst but not better than the best the new value replaces the worst value and the simplex is sorted and the process continued (line 124-132) 122 - 123: If the new value is better than the old best value reflection factor is doubled and process continues with replacing the worst value by the new one (line 124-132) 133 ff is the routine when the new value is the worst. 134 -139: Reflection factor is halved and a new try with the new reflection factor is done. If the result is better than the worst value of the simplex the new value replaces the old worst value of the simplex (124 - 132) 140 - 157: If the new value is worse than the worst value of the simplex the size of the simplex is halved, the function values of the new simplex points is computed and the simplex is sorted. With the new simplex a new try is started. 158 - 177: The reflection of the worst value at the mean of the two best using the reflection factor in Reg 19 and computing the new function value. Results are stored in 16, 17 and 18. 178 - 187: Computing the function values of the second best and worst point of the simplex. Concerning printing: This is difficult because there are changes at many points of the code as shown. If you restrict to complete optimization steps you could add printing commands after step 37. I hope this helps a bit. Best regards Raimund Wildner |
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05-01-2020, 06:36 AM
Post: #4
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RE: HP 42S/ DM42: Nelder Mead Optimization
Yes it helps, vielen dank! (Thanks a lot)
I added a counter line 37 before the call of the optimisation procedure, it’s quite funny to see that 2140 iterations are needed for a .0001 precision, but “only” 2191 for a precision of 10^-9 About you criterion calculation: so you use the distances between the original points of the simplex and not their image through FU. It must be faster, but I’m really wondering about the consequences of this method, especially for non derivable functions. Another question: you don’t care about the domain of FU? Inserting for example a square root in FU should create random comportment with complex values, don’t you think? Regards, Thibault |
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05-01-2020, 07:10 AM
Post: #5
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RE: HP 42S/ DM42: Nelder Mead Optimization
Hi,
concerning the termination criterion: I do not think that it is faster to use the differences in the X and Y than in the f(X,Y). Near the optimum most derivable functions are rather flat with a derivate well below 1, so that the differences in the function are smaller than the differences in the variables. So it should be slower. But I thought if you set a threshold you want to set the exactness of your input factors. Concerning the domain of FU you are right. If the square route would be negative the procedure would stop. I put not enough care on the function which was just for demonstration purposes. Concerning not derivable functions: These are a problem to all optimization functions. It can be that the simplex does not get along the valley and the size of the simplex is shrinked to virtually zero. But in this case both termination criteria would stop the procedure. A possible way to handle such cases is to start the procedure again at the solution reached so far. Best Raimund |
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05-01-2020, 04:37 PM
Post: #6
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RE: HP 42S/ DM42: Nelder Mead Optimization
Maybe the best way to proceed with the domain of FU is to let the function handle the out of bounds values, ie by returning 9E99, then the NMO routine keeps simple and will avoid those regions.
I should try this. I also tried (x+1)^2+(y+1)^2, it worked perfectly! |
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05-02-2020, 05:14 AM
Post: #7
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RE: HP 42S/ DM42: Nelder Mead Optimization
Hi,
I once more thought about the square roots and I do not see that there can be a problem. In the function FU there is no square root. And concerning the computation of the termination criterion in line 47 and 57 these are square roots of squares of differences of real numbers which cannot be negative. So there is no need to work with penalty functions etc. Best Raimund |
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05-02-2020, 12:38 PM
Post: #8
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RE: HP 42S/ DM42: Nelder Mead Optimization
I hope you’re not bothered by my questions, your program is really interesting and I am investigating the N-M optimization, thanks to you.
I used it for the following formula for FU: Code:
Gives nice results when starting from (-3,0): With original length set to .2 the simplex gets stuck in the wrong valley, and the result (-3.811,0) is a local minimum. If original length is set to .5 then the steps are bigger enough for the simplex to « find » the right valley in (1.312,0). Then I entered a small pitfall in FU: Code:
As you guess I had to insert a simple rule to avoid values of x below -5, giving 50 as a result (dummy management of out of function’s domain values). With length of .2 or .5 starting in (-3,0) I get stuck in the wrong valley (-3.778,0). Using length of 1 and starting from (-2,0) I find the right minimum. I will investigate more, but I think it is the good way to manage the domain in a tricky way. Using length of 2 and starting from -3 I suppose the simplex gets stuck on the Z=50 wall, missing the exit... Once again thanks for this interesting program. Regards, Thibault |
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05-02-2020, 02:02 PM
(This post was last modified: 05-02-2020 02:03 PM by pinkman.)
Post: #9
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RE: HP 42S/ DM42: Nelder Mead Optimization
Me again!
I changed the behavior of my FU, creating a gradient for values of x<(-5) It returns 10*(-x). Starting from (-30,0) with length of .5, 1 or 2 the simplex stays in the wrong valley (-3.778,0). With length of 50 (zum beispiel), the right valley is found (1.227,0). Your algorithm is really well built. Regards. |
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05-02-2020, 03:39 PM
Post: #10
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RE: HP 42S/ DM42: Nelder Mead Optimization
Hi Thibault,
first: I like the discussion and I am not bothered at all. Your experience with the local minimum shows a problem that comes with all numerical optimization procedures. That is the reason why it is recommended to start the procedure from several starting points. If you are interested in numerical optimization procedures I can recommend the book by Ulrich Hoffmann and Hanns Hofmann "Einführung in die Optimierung mit Anwendungsbeispielen aus dem Chemie-Ingenieur-Wesen", Weinheim / Bergstr. 1971. It is in German but I got the impression that you understand German. Best Raimund |
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05-02-2020, 10:03 PM
Post: #11
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RE: HP 42S/ DM42: Nelder Mead Optimization
Sure I could order some food in Germany, or maybe talk with someone in the street, but no and I regret I could not read such a book! And I did not find any translation. Anyway thanks for the advice, I could read some other books to improve my knowledge about optimization, it has not been in my current matters since 20 years (and I was working with experts, I was not one of them).
Anyway, playing with N-M-O is funny because 1) you have to find an interesting function z=f(x,y) that shows particularities, and 2) you have to search for initial values and to try several times, hoping, like always in numerical optimization, that you will not miss the minimum. Regards. |
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