[VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math"
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02-14-2021, 08:58 PM
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[VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math"
Hi, all ! Happy San Valentín 2021 to all of you ! Almost a year has elapsed since my previous S&SMC, exactly 6 years 6 since I registered in this new-style forum, and today it's San Valentin's Day so here you are, a brand-new Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math", once again intended to give you a chance to dust off your chosen HP calculator and actually use it, while also flexing your HP-programming muscle *and* your HP-assisted sleuthing abilities (*NOT* your Google Search proficiency). Try all 6 Concoctions 6 below and see what you can do about them ! Rules:
Concoction the First: Weird limit [MRM: HP-11C and up] Many HP calculators have a function that returns a (pseudo-)random number uniformly distributed between 0 (inclusive) and 1 (exclusive), such as RND in the HP-11C, HP-15C, HP-71B and many other models, and RAN in the HP-42S. Now get your calc and conduct a test where you generate a couple of random numbers and add them up, then if the sum is less than 1 you continue generating and adding up more random numbers one at a time until the sum eventually exceeds 1, while keeping count of just how many random numbers did you generate. For instance, suppose your first test generates 0.87 and 0.65 and their sum is 1.52, which is greater than 1 already so the test is over and 2 random numbers were generated in all. Now you conduct another test and the sequence of random numbers is 0.21, 0.07, 0.16, 0.35, 0.19 and finally 0.58, which makes the sum (1.56) exceed 1, so the test is over and we had to generate 6 random numbers in all. The Challenge: Write a program that simulates the process for a given number of tests and outputs the average count of random numbers generated per test, and then (the sleuthing part) use the program to help you answer these questions:
Surprising, isn't it ? But there's more surprises: now get a suitably fast HP model (physical or virtual) and conduct a sizable number of tests (say ~100,000) to find the average count for sums exceeding 3, 4, 5 and 5+1/6 (no kidding, try it) on the one hand, and for sums exceeding 10, 15 and 20 on the other, and analyze the results you get, in order to answer these additional questions:
Use a seed of 1 for the random number generator at the very start of your program (for instance, RANDOMIZE 1 on the HP-71B and 1, SEED on the HP-42S) and give your answers accurate to at least 2-3 digits. Please do not use/post any theoretical formulas to get the results for now, do it empirically by just generating and using actual random numbers. I'll give my original solutions for both the HP-42S and the HP-71B, as well as my comments on the results. Concoction the Second: Weird Sum [MRM: HP-11C and up] Consider the following infinite Albillo sum: where, other than 2021, the coefficients are the prime numbers pk in order: p1 = 2, p2 = 3, p3 = 5, p4 = 7, ... Note: Observe that for k=1 in the sum above, the product in the numerator is the empty product, thus equal to 1 by definition. The Challenge: Write a program to compute and output the sum as accurately as possible, and then (the sleuthing part) use your HP calc (perhaps conduct some experiments) to try and attempt to answer this question: What's so weird about this sum ? (BTW, forget about Googling for it because I concocted it myself and it's nowhere else to be found AFAIK.) I'll give my original solution for the HP-71B, as well as my comments on the result. Concoction the Third: Weird Integral [MRM: HP-15C and up] Consider the following definite Albillo integral: where Γ is the Gamma function, ln is the natural logarithm (i.e., base e) and φ is the Golden Ratio = (1+ √5)/2. The Challenge: Use your HP calc to compute (either manually or writing a program to do it) and output the value of the definite integral as accurately as possible, and then (the sleuthing part) use your HP calc (perhaps conduct some experiments) to try and attempt to answer this nagging question: What's so weird about this integral ?. (Again, forget about Googling for it because I concocted it myself and it's nowhere else to be found either.) I'll give my original solution for the HP-71B, as well as my comments on the result. Concoction the Fourth: Weird Graph [MRM: HP-PRIME and other graphing models] Consider the following polynomial in two real variables x, y: P(x, y) = 9 x8 + 9 y8 + 36 x2 y6 + 54 x4 y4 + 36 x6 y2 - 100 x6 - 4 y6 - 108 x2 y4 - 204 x4 y2 + 182 x4 - 10 y4 - 84 x2 y2 - 100 x2 - 4 y2 + 9 The Challenge: Use your graphing calc (remember: no Wolfram Alpha, etc), either by writing and running some program or manually (but then succintly specify the operations performed) to accurately plot the resulting 2D graph for P(x, y) = 0, and somewhat describe what you see in the graph you get, giving also relevant parameters (say ranges for x and y, or maybe things like centers or focii or radii or asymptotes or intersections or zeros/poles, whatever. If you think it might help, you may also attempt to factorize the polynomial, but in any case the main question is: What's so weird about this graph ? I wont post code or manual operations as I don't own any graphing calculators but I'll give the resultant graphic you should get, as well as extensive commentary. Concoction the Fifth: Weird Primes [MRM: any fast physical or virtual HP calc] In Milos Forman's 1984 "Amadeus" film (winner of 8 Academy Awards {aka Oscars}, including Best Picture) Salieri comments on the perfection of Mozart's music: "Displace one note and there would be diminishment, displace one phrase and the structure would fall." Now let's bring that observation to the realm of prime numbers and consider a prime number so 'Perfectly Prime' (a PP for short, pronounced "Pepe") that changing any single digit would diminish its primeness by turning it into a composite number. Note: We're talking about base-10 digits here. The Challenge: Write a program (the faster & shorter, the better) for your HP calc to compute: (a) the 5 smallest PP, (b) the first PP greater than 500 million, (c) the first PP greater than 777,777,777 and only for very fast programs/devices, the second PP greater than 666,666,666. I'll give my original solution for the HP-71B, as well as my comments on the results. Concoction the Sixth: Weird Year [MRM: HP-11C and up] Note: All that follows is stated utterly tongue-in-cheek, not to be taken seriously at all. No offence whatsoever is meant to anyone who's been negatively affected during 2020. Unless you've been hiding under a rock last year, surely you're sorely aware that 2020 was a catastrophic year and many of you might wonder why did it came that way. I know I did, and being fully convinced that this Universe of ours is a mathematical entity subject to mathematical rules, I have been analyzing the matter exhaustively using my trusty HP calculators and have finally succeeded in unraveling the mystery !! At long last, I now know the reason why 2020 was a catastrophic year and of course the reason is of a mathematical nature, as expected. To wit, the reason is that 2020 shares a very striking numeric property with many other catastrophic years such as, e.g.: the year 662 (the Damghan earthquake killed 40,000 people), the year 458 (the Antioch earthquake killed 80,000), the year 1348 (the Black Death plague, which killed up to 200 million, was at its apogee), the year 1556 (the Shaanxi earthquake killed 830,000) or the year 1849 (the Great Irish Famine killed ~1,500,000), to name but a few. That can't be a mere coincidence ! Moreover and just in case this wasn't evidence enough, the number 666 (the infamous Number of the Beast of apocalyptic fame) also shares that very property as well. The Challenge: Use your trusty HP calculator to assist you in your sleuthing to try and discover what simple but highly remarkable (striking, in fact) numeric property all the aforementioned numbers have in common, and then write a program to find out and output a listing of all years between AD 4 and AD 5000 (both included) which have this property (hint: less than 100). Of course the listing should include all mentioned past years as well as future years thus predicted to be potentially catastrophic, up to that limit. The questions are: (a) How many years will be listed in the output ? (b) What will be the next predicted potentially catastrophic year after 2020 ?, and (c) Should we be concerned ? As an additional hint to help finding the remarkable shared property, remember Occam's Razor: the property can be unambiguously stated by saying that the year's number is a "(five words)". I'll give my solution, two short programs (6 and 7 lines resp.) for the HP-71B which produce the listing and also accept a given year in range and demonstrate* whether it has the required numeric property (thus, if it indeed was/might be catastrophic) or not.
And last but certainly not least, a couple' important caveats:
I'll post my original solutions in a week or so, for you to have enough time (and no excuses) to try them all. That is, if you've got what it takes ... That's all. Enjoy ! ... and that's an order ! V. All My Articles & other Materials here: Valentin Albillo's HP Collection |
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02-15-2021, 05:43 PM
(This post was last modified: 02-15-2021 06:37 PM by Vincent Weber.)
Post: #2
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
Hi Valentin,
Is the Python syntax available on the HP Prime CAS allowed ? I kind of fell in love with Python, now that it is the mandatory language on educational calculators in France (starting in 2017 with the awesome Numworks, then Casio, then TI, with HP supporting its syntax along with HPPL on the Prime). I am teaching my kids programming with both Scratch and Python, and I have to admit that I like it a lot - Scratch gives the youngest good ideas of structural programming with friendly drag and drop graphical blocks, and Python is quite easy to catch up for older kids. I find Python more elegant and expressive than any Basic, even the massively enhanced 71B one (but granted, the 71B can interact seamlessly with advanced mathematical features such as matrices. To compete that, Python calculators should provide Numpy, which is not the case yet). On the Numworks (did I say how much I love this tiny, stylish, fast, well designed machine with awesome software ? Valentin you should love it, as you love beautiful objects ) the Python menus allow you to generate skeletons of code with utmost ease. Anyway... I already got the (surprising indeed !) answer for #1. If you ban Python altogether, I shall try with RPN on Free42 Cheers, Vincent |
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02-15-2021, 07:14 PM
Post: #3
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
I don't know the reason but I'm particularly attracted by the integral problems (like this previous challenge).
So I tested the "weird" integral: (02-14-2021 08:58 PM)Valentin Albillo Wrote: The expression to integrate looks complicate, although without any trap, it is not defined at the integral boundaries but that's not a problem with the Romberg algorithm. I took my old trusted HP-32S and entered the program: LBL I RCL X LN 1 - x! RCL F x² RCL X - LN 1 - x! + LASTx x<>y / RTN Then: FIX 11 put the golden ratio in F: 5 SQRT 1 + 2 / STO F FN= I 1 RCL F ∫FN dX and quickly got the answer up to at least 11 places. So what's special? It was fast and easy, without any problem. Oh wait, it was too easy, too fast. That's weird. [...Investigating a bit...] Now that I think I found what is "weird", I can even do the calculation by hand, and get the symbolic result without having to identify the numeric result: [... hidden for now ...] J-F |
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02-15-2021, 08:51 PM
(This post was last modified: 03-01-2021 06:15 PM by robve.)
Post: #4
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
Challenge one
Note: code indent replaced by U+00A0 (NO-BREAK SPACE) by hand and may not be copyable/usable. HP PRIME -------- EXPORT MC() BEGIN LOCAL SUM, N, TRIALS; RANDSEED(1); N := 0; FOR TRIALS FROM 1 TO 100000 DO SUM := 0; WHILE SUM <= 1 DO SUM := SUM + RANDOM(); N := N + 1; END; END; MSGBOX(N/100000); END; BASIC ----- randomize 1 n=0 for t=1 to 100000 sum=0 while sum<=1 sum=sum+rnd(0) n=n+1 wend next t print n/100000 Python ------ import random def MC(): random.seed(1) n = 0 for t in range(100000): sum = 0 while sum <= 1: sum = sum + random.random() n += 1 print(n/100000) if __name__ == "__main__": MC() a. What do you think is, in the limit, the average count of generated random numbers for their sum to exceed 1 ? Can you recognize what the exact value would be? 2.71959 when trials approaches infinity the exact value is e b. What would the average count be for the sum to exceed 2 ? To exceed 2.021 ? To exceed Pi? 2 -> 4.67827 2.021 -> 4.71806 3 -> 6.66808 pi -> 6.95027 4 -> 8.66601 5 -> 10.66641 5+1/6 -> 10.99947 10 -> 20.65914 15 -> 30.66700 20 -> 40.66927 c. What do you think is the asymptotic expression for the average count needed to exceed large values of the sum? I have an idea what kind of inequality in probability theory applies here, which uses EXP() but cannot recall from the top of my head without looking it up. The value appears to be converging to a value between 2k+1/6 and 2(k-1)+e. d. Can you explain the constant component of said expression? Working on this... Challenge two HP PRIME -------- EXPORT WS2021() BEGIN LOCAL I,J,F,P,SUM,PROD; L0 := [2,3,5,7,11,13,17,19]; FOR P FROM 23 TO 99999 STEP 2 DO F := 0; FOR I FROM 1 TO SIZE(L0) DO IF P MOD L0[ I] = 0 THEN F := 1; BREAK; END; END; IF F = 0 THEN L0 := append(L0, P); END; END; SUM := 0; PROD := 1; FOR I FROM 1 TO SIZE(L0) DO PROD := PROD*L0[ I]/(2021+L0[ I]); SUM := SUM + PROD; END; MSGBOX(SUM); END; This program displays the value 9.90099737136E-4 for primes up to 99999 (and also for smaller bounds than 99999, such as 97 which is weird). EDIT Oops, double check: I read the sum wrong, for the term's numerator has k-1 while the denominator has k. Here is the simple correction. This gives 4.94804552201E-4 and does not change for primes >11 (this sum should converge quickly): EXPORT WS2021() BEGIN LOCAL I,J,F,P,SUM,PROD; L0 := [2,3]; FOR P FROM 5 TO 17 STEP 2 DO F := 0; FOR I FROM 1 TO SIZE(L0) DO IF P MOD L0[ I] = 0 THEN F := 1; BREAK; END; END; IF F = 0 THEN L0 := append(L0, P); END; END; SUM := 0; PROD := 1; FOR I FROM 1 TO SIZE(L0) DO SUM := SUM + PROD/(2021+L0[ I]); PROD := PROD*L0[ I]/(2021+L0[ I]); END; MSGBOX(SUM); END; Interesting to observe is that the reciprocal of the sum 1 / 4.94804552201E-4 = 2021. /EDIT Challenge three Evaluated on the HP PRIME displays 0.309016994375 (updated to correct a typo in the input). I don't have the HP-71B (love it), but could use my other BASIC pocket computers since I wrote my own Romberg integration program and Gamma Lanczos approximation in BASIC some time ago. But alas, non-HP machines are not allowed. EDIT: anyway, let me add this SHARP PC-1350 BASIC program (Valentin, your favorite sharp calc) that produces the answer 0.3090169944 which is perfect to the full 10 digits (updated to correct a typo): ' ROMBERG QUADRATURE WITH HIGH PRECISION - Numerical recipes qromb + polint p.134 ' see also https://en.wikipedia.org/wiki/Romberg's_...ementation ' Functions to integrate are defined with label "F1", "F2", etc. ' VARIABLES ' A,B range ' F$,F function label (or number) to integrate ' Y result ' E relative error: integral = Y with precision E (attempts E = 1E-10) ' H step size ' N max number of Romberg steps (=10) ' I iteration step ' U current row ' O previous row ' J,S,X scratch ' A(27..26+2*N) scratch auto-array 100 INPUT "a=";A 110 INPUT "b=";B 120 INPUT "F";F 130 E=1E-9,N=10,F$="F"+STR$ F,X=A: GOSUB F$: S=Y,X=B: GOSUB F$ 140 H=B-A,O=27,U=O+N,A(O)=H*(S+Y)/2,I=1 150 H=H/2,S=0 160 FOR J=2 TO 2^I STEP 2: X=A+J*H-H: GOSUB F$: S=S+Y: NEXT J 170 A(U)=H*S+A(O)/2,S=4 180 FOR J=1 TO I: A(U+J)=(S*A(U+J-1)-A(O+J-1))/(S-1),S=4*S: NEXT J 190 IF I>1 IF ABS(A(U+I)-A(O+I-1))<E*A(O+I-1) LET Y=A(U+I): PRINT Y: END 200 S=O,O=U,U=S,I=I+1: IF I<N GOTO 150 210 Y=A(O+N-1),S=U+N-2,E=ABS((Y-A(S))/A(S)): PRINT Y,E: END 300 "F1" V=X,X=1.618033989,X=LN(X*X-V): GOSUB "GAMMA": W=Y 310 X=LN V: GOSUB "GAMMA": Z=Y,X=1.618033989,X=LN(X*X-V): GOSUB "GAMMA" 320 Y=W/(Z+Y): RETURN ' gamma(X) -> Y using Lanczos approximation 400 "GAMMA" IF X<=0 LET Y=9E99: RETURN 410 Y=1+76.18009173/(X+1)-86.50532033/(X+2)+24.01409824/(X+3) 420 Y=Y-1.231739572/(X+4)+1.208650974E-3/(X+5)-5.395239385E-6/(X+6) 430 Y=EXP(LN(Y*2.506628275/X)+(X+.5)*LN(X+5.5)-X-5.5): RETURN /EDIT Challenge four Plot with HP PRIME shows two (cross) eyes. Very funny! I used the advanced graphing app to enter the X-Y equation. The "eyes" radii are close to the root of 17/6 (updated) and centered at (±4/3,0). The two "pupils" centered at (±1,0) take some time to converge. They may never computationally converge exactly to a single point. Now on to the last two challenges. But some information is missing about the PP definition: do you mean that changing any digit to any other digit ALWAYS produces a composite number? So for example 17 is not a PP because 7->9 gives 19? EDIT Challenge five PP #1: 294001 PP #2: 505447 PP #3: 584141 PP #4: 604171 PP #5: 971767 I wrote a Sieve of Eratosthenes program with an addition to filter perfect primes. The big problem is that HPPL does not permit lists lengths exceeding 20K. So unfortunately I had to rewrite the program in C and run it. I wish HPPL has bitvectors or efficient sets! EXPORT PP() BEGIN LOCAL I,J,K,N,M; LOCAL F,D,P,Q,R; N := 9999; // INIT LIST OF 0 (COMPOSITE) OR 1 (PRIME) L0 := MAKELIST(odd(I),I,1,N,1) // SIEVE PRIMES I := 3; WHILE 1 DO WHILE I < N AND L0[ I] = 0 DO I := I+1; END; IF I = N THEN BREAK; END; FOR J FROM 2*I TO N STEP I DO L0[J] := 0; END; I := I+2; END; // FILTER PERFECT PRIMES P := 3; WHILE 1 DO WHILE P < N AND L0[P] = 0 DO P := P+1; END; IF P = N THEN BREAK; END; M := FLOOR(LOG(P)); F := 1; FOR J FROM 0 TO M DO I := 10^J; // Q = P WITH JTH DIGIT SET TO 0 Q := FLOOR(P/I/10)*I*10+ROUND(FP(P/I)*I); // D = JTH DIGIT OF P (0 to 9) D := FLOOR(P/I) MOD 10; FOR K FROM 0 TO 9 DO IF K <> D AND L0[Q+K*I] THEN F := 0; END; END; END; IF F THEN PRINT("PERFECT "+P); END; P := P+2; END; END; I spent a lot of time typing this program in on my HP PRIME (and the other ones). This challenge is meant to enter programs on the HP machine! Note that the program checks for PP by changing digits. This includes changing the leading digit to any digit 0 to 9, including 0. So for example, 199 -> 099 is not PP. It seems odd to me to change the leading digit to 0 to check for PP. The second HPPL program is less efficient, but permits a lower bound B and upper bound E for the search: EXPORT WPP() BEGIN LOCAL B,D,E,F,I; LOCAL J,K,P,Q; // BEGIN SEARCH AT B B := 11; // END SEARCH AT E E := 9999999; FOR P FROM B TO E STEP 2 DO IF isprime(P) THEN M := FLOOR(LOG(P)); F := 1; FOR J FROM 0 TO M DO I := 10^J; // Q = P WITH JTH DIGIT SET TO 0 Q := FLOOR(P/I/10)*I*10+ROUND(FP(P/I)*I); // D = JTH DIGIT OF P (0 to 9) D := FLOOR(P/I) MOD 10; FOR K FROM 0 TO 9 DO IF K <> D AND isprime(Q+K*I) THEN F := 0; BREAK; END; END; IF F=0 THEN BREAK; END; END; IF F THEN PRINT("PERFECT "+P); END; END; END; END; The first method (sieving) is more efficient. The asymptotic running time is linear in the max perfect prime p we're hunting for, but requires memory of size p. The asymptotic running time of the second method is roughly square in p but requires constant memory. It takes a few minutes to find the first five perfect primes. My Cheat program gives an answer in a fraction of a second: #include <stdio.h> #include <stdlib.h> #include <math.h> int main() { long i, j, k, n = 1000000; // sieve (0 = composite, 1 = prime) char *s = (char*)malloc(n); // init sieve, we should keep only odd values for (i = 0; i < n; ++i) s[i] = (i & 1); // seive for primes for (i = 3; i < n; i += 2) { while (i < n && s[i] == 0) ++i; for (j = 2*i; j < n; j += i) s[j] = 0; } // sieve for perfect primes for (i = 3; i < n; i += 2) { while (i < n && s[i] == 0) ++i; if (i < n) { long m = floor(log10(i)); long p = 1; // p = 10^j char h = 1; // h = 1 if i is perfect // for each digit in prime i, from least to most significant for (j = 0; j <= m; ++j, p *= 10) { // q = prime i with jth digit zero long q = i%p + i/p/10*p*10; // d = jth digit of prime i long d = i/p%10; // twiddle jth digit and check for prime for (k = 0; k <= 9; ++k) if (k != d && s[q+k*p]) h = 0; } if (h) printf("perfect %ld\n", i); } } free(s); } b. 500004469 (first PP > 500000000) c. 777781429 (first PP > 777777777) d. 666999929 (second PP > 666666666) For small primes with k digits such as k=1, k=2, …, k=5 digits there are no perfect primes in base 10, because primes with k digits are "too close" (as in a Hamming distance kind of way). The prime number theorem tells us that primes are distributed roughly as N/log(N) so that a randomly picked integer not greater than N has a probability of 1/log(N) to be prime. A perfect prime of k digits can be perturbed by its definition to generate 9k distinct composite integers. Roughly, the chance that an integer of k digits is prime is 1/log(10^k)=0.43/k. The chance that the 9k integers are all composite is (1-0.4343/k)^(9k), assuming k is sufficiently large. It turns out that the chance approaches 2% for large k and is half that for small k (though the log constant is somewhat arbitrary). More importantly, there are also far more integers to pick as potential perfect primes for large k. Based on this, it seems reasonable to see perfect primes for large k and there are infinitely many of them. /EDIT "I count on old friends to remain rational" |
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02-15-2021, 09:20 PM
(This post was last modified: 02-15-2021 10:06 PM by J-F Garnier.)
Post: #5
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math... | |||
02-15-2021, 10:08 PM
(This post was last modified: 02-15-2021 11:03 PM by ramon_ea1gth.)
Post: #6
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
I tried the weird limit in my physical HP 50g in User-RPL, reaching 100,000 iterations. When I saw the outcome going to e, some kind of law of large numbers came to my mind.
Input stack: 2: number of tests, CNT 1: limit to exceed, XCD (e.g., 1, pi) My code: « 0 → CNT XCD TOT « 1 RDZ 1 CNT FOR I RAND 1 → TMP NR « DO RAND 'TMP' STO+ 1 'NR' STO+ UNTIL TMP XCD > END NR 'TOT' STO+ » NEXT TOT CNT / » » Ramón Valladolid, Spain TI-50, Casio fx-180P, HP48GX, HP50g, HP Prime G2 |
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02-15-2021, 10:14 PM
(This post was last modified: 02-15-2021 10:32 PM by Valentin Albillo.)
Post: #7
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
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Thanks for your interest and for participating, some quick answers to your questions: Vincent Weber Wrote:Is the Python syntax available on the HP Prime CAS allowed ? Smile [...] If you ban Python altogether, I shall try with RPN on Free42 Smile If it's available for the HP Prime then it's technically allowed but I'd rather have a program in Hppl for the Prime or in RPN/RPL/BASIC/FORTH/Assembler/etc. for any other HP calc. Anyway, your choice. robve Wrote:But some information is missing about the PP definition: do you mean that changing any digit to any other digit ALWAYS produces a composite number? So for example 17 is not a PP because 7->9 gives 19? Yep. If changing any single digit to any other digit results in a prime number, the original one is not a PP. Regards. V. All My Articles & other Materials here: Valentin Albillo's HP Collection |
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02-16-2021, 08:34 AM
Post: #8
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
Thanks Valentin.
Anyway it seems that similar solutions to mine have already been posted. This one is actually fairly easy, from a programming perspective, if not from a theorical perspective - but you didn't allow theory here Cheers, Vincent |
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02-16-2021, 09:56 AM
Post: #9
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
Free42 code for challenges 1,2 and 3:
VA#1: average nr of random numbers in X runs to sum over Y e.g. 2 ENTER 100000 XEQ"VA1" -> 4.67827 00 { 39-Byte Prgm } 01▸LBL "VA1" 02 LSTO "X" 03 LSTO "C" 04 SIGN 05 SEED 06 CLX 07 STO ST Z 08▸LBL 02 09 ISG ST Z 10 X<>Y 11 RAN 12 + 13 X≤Y? 14 GTO 02 15 CLX 16 DSE "C" 17 GTO 02 18 R^ 19 RCL÷ "X" 20 END results identical to robve's post. I would say that for 'larger' n, the limit is 2(n+1/3).. 00 { 73-Byte Prgm } 01▸LBL "VA2" 02 1 03 LSTO "P" @ term 04 CLX 05 LSTO "S" @ sum 06 2 07 XEQ 14 08 3 09▸LBL 03 10 XEQ "P?" 11 X=0? 12 GTO 00 13 R↓ 14 XEQ 14 15 X=Y? 16 RTN 17 R↓ 18▸LBL 00 19 R↓ 20 2 21 + 22 GTO 03 23▸LBL 14 24 RCL "P" 25 2021 26 RCL ST Z 27 + 28 ÷ 29 × 30 STO "P" 31 X<> ST L 32 X<> "S" 33 STO+ "S" 34 RCL "S" 35 END The P? primality testing program returns X and 0 when not prime, 1 when prime. You may use eg 00 { 114-Byte Prgm } 01>LBL "P?" 02 ENTER 03 STO ST Z 04 2 05 X=Y? 06 GTO 01 07 X>Y? 08 SIGN 09 MOD 10 X=0? 11 RTN 12 CLX 13 3 14 X=Y? 15 GTO 01 16 MOD 17 X=0? 18 RTN 19 CLX 20 5 21 X=Y? 22 GTO 01 23 MOD 24 X=0? 25 RTN 26 CLX 27 7 28>LBL 03 29 X^2 30 X>Y? 31 GTO 01 32 SQRT 33 MOD 34 X=0? 35 RTN 36 CLX 37 4 38 LASTX 39 + 40 MOD 41 X=0? 42 RTN 43 CLX 44 2 45 LASTX 46 + 47 MOD 48 X=0? 49 RTN 50 CLX 51 4 52 LASTX 53 + 54 MOD 55 X=0? 56 RTN 57 CLX 58 2 59 LASTX 60 + 61 MOD 62 X=0? 63 RTN 64 CLX 65 4 66 LASTX 67 + 68 MOD 69 X=0? 70 RTN 71 CLX 72 6 73 LASTX 74 + 75 MOD 76 X=0? 77 RTN 78 CLX 79 2 80 LASTX 81 + 82 MOD 83 X=0? 84 RTN 85 CLX 86 6 87 LASTX 88 + 89 GTO 03 90>LBL 01 91 SIGN 92 END @robve: you made the same mistake I did at first.. read the formula carefully, the nominator goes to pk-1 and the denominator to pk. The sum converges quickly to 4.948045522...E-04, which is exactly 1/2021. Why? I'm sure Valentin will enlighten us in a few days ;-) VA#3: integral Program to be used with INTEG 00 { 37-Byte Prgm } 01▸LBL "VA3" 02 MVAR "X" 03 1.25 04 SQRT 05 1.5 06 + 07 RCL- "X" 08 LN 09 GAMMA 10 RCL "X" 11 LN 12 GAMMA 13 RCL+ ST Y 14 ÷ 15 END Making use of the fact that φ^2 = φ+1 Same observations as J-F.. though the fact that it's easy to see what the value is, does not explain (to me) why it converges so quickly. Cheers, Werner 41CV†,42S,48GX,49G,DM42,DM41X,17BII,15CE,DM15L,12C,16CE |
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02-16-2021, 02:11 PM
Post: #10
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
(02-16-2021 09:56 AM)Werner Wrote: The sum converges quickly to 4.948045522...E-04, which is exactly 1/2021. Why? I'm sure Valentin will enlighten us in a few days ;-) The first S&S Math Challenge in 2021? --Bob Prosperi |
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02-16-2021, 09:12 PM
Post: #11
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
Regarding the weird sum that uses primes, I used Matlab to calculate each term and the updated sum. The sum seems to reach the asymptotic value of 9.90099737e-04.
The value of 2021, which I will call the Albillo Parameter helps the summation to reach the assumptotic value at the prime of 7. The smaller values of the Albillo Parameter will delay the summation from reach an assymptotic value (which depends on the Albillo Parameter). For example if the Albillo Parameter is, say, 101, the summation reaches the assymptotic value of 2.00059191e-02 at prime of 23. My main focus is on the sumamtion in general and the role that the Albillo Parameter plays. My own question is what is the relationship between the summation's assymptotic value and the value of the Albillo Parameter? Cool summation!!!! :-) Namir |
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02-17-2021, 08:44 PM
Post: #12
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
For challenge five, which I have finished, it does not seem possible to implement efficient sets on the HP PRIME because lists are limited to only 20K elements. There is no bitvector or efficient set type that we can use.
Because of this limitation I rewrote the program in C (sorry for Cheating...). With this I found: perfect 294001 perfect 505447 perfect 584141 perfect 604171 perfect 971767 Note that the program checks for PP by changing one digit of a prime at a time to check if that number is prime or not. This includes changing the leading digit to any digit 0 to 9, including 0. So for example, 199 -> 099 is not PP. It seems odd to me to change the leading digit to 0 to check for PP. I updated my post with EDITs to add my answer as well as make a correction to the weird sum (I misread k-1). - Rob "I count on old friends to remain rational" |
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02-18-2021, 08:22 AM
(This post was last modified: 02-18-2021 08:27 AM by J-F Garnier.)
Post: #13
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
(02-16-2021 09:56 AM)Werner Wrote: VA#3: integral I thought the other way around: I understood that it's so fast because each sample set used by the algorithm gives the exact value of the integral, so the algorithm terminates after just the first 2 estimations (7 samples used). Then I thought that even one sample is enough to give the exact value, using the midpoint that contributes to 1/2, hence the result. And yes, φ^2 = φ+1 is the key :-) J-F |
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02-18-2021, 09:28 AM
Post: #14
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
The key to the value of the integral in #3 is to realize that the integral is symmetric in the integral boundaries. Basically it is
integral(a,b,f(a+b-x)/(f(x) + f(a+b-x)),dx) if you substitute y = a+b-x, dy=-dx, you get integral(b,a,-f(y)/((y) + f(a+b-y)),dy) = integral(a,b,f(y)/((y) + f(a+b-y)),dy) Meaning the value of the integral is the sum of both divided by two, or (b-a)/2, whatever f(x) is. So here it is (φ-1)/2. Cheers, Werner 41CV†,42S,48GX,49G,DM42,DM41X,17BII,15CE,DM15L,12C,16CE |
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02-18-2021, 01:41 PM
Post: #15
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
This should provide all the answers to #6:
20 « { } 1 DUP2 ROT 5 ROLL START NEXTPRIME + LASTARG NIP NEXT DROP SQ DUP SIZE 2 SWAP FOR i 1 OVER SIZE 1 + i - FOR j DUP j DUP i + 1 - SUB ∑LIST ROT + SWAP NEXT NEXT + SORT » EVAL « REVLIST 1 119 START TAIL NEXT SORT » EVAL Perhaps 19 or less would suffice as the argument for the first program, but I have not enough time to check this out right now. Best regards, Gerson. |
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02-18-2021, 06:46 PM
(This post was last modified: 02-19-2021 03:10 PM by Nihotte(lma).)
Post: #16
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
(02-14-2021 08:58 PM)Valentin Albillo Wrote: UPDATED 2021.02.19 - 04.10PM to comply with the mention : Please do NOT include CODE panels in your replies to this thread Hi, Just to say, I've taken part of the challenge too ! However, I've progressed more slowly than you all... For a. and b. points I began with my HP35s : ** LBL V INPUT S // 1 for stop INPUT L // 100000 for loops CLΣ 1 SEED RCL L STO I 009 CLx STO J STO C 012 1 STO + J RANDOM STO + C RCL C RCL S x > y GTO V012 0 RCL J Σ+ DSE I GTO V009 RCL L RCL S x-mean RTN XEQ V001 with S=1 and L=1E5 gave 2.71959 about 6 hours later Then, I've brought out my 48G << DEPTH DROPN 0 'SUM' STO SEED RDZ 1 LOOPS FOR i 0 DUP DO SWAP 1 + SWAP RAND + DUP TOP UNTIL >= END DROP 'SUM' STO+ NEXT TOP LOOPS SUM OVER / >> with : VAW is the program above 1 'TOP' STO // 1, 2 .. 20 1 'SEED' STO 100000 'LOOPS' STO And the run of VAW gives 1 100000 2.71959 in the stack and SUM is 271959 The result appears more rapidly than with the HP35s, of course 6x faster, perhaps Unsurprisingly, my results match those of robve's post for the successive limit values 1, 2 .. 20 retained ------ The result for a limit of 1 seems to be close to e. But, I've tested something on my HP10BII+ I decided to enter all couple of result by Σ+ in the calculator C STAT 1 INPUT 2.71959 and Σ+ 2 INPUT 4.67827 and Σ+ 2.021 INPUT 4.71806 and Σ+ 3 INPUT 6.66808 and Σ+ pi INPUT 6.95027 and Σ+ 4 INPUT 8.66601 and Σ+ 5 INPUT 10.66641 and Σ+ 5+1/6 INPUT 10.99947 and Σ+ 10 INPUT 20.65914 and Σ+ 15 INPUT 30.66700 and Σ+ 20 INPUT 40.66927 and Σ+ then, [BLUE] REGR and [-] to select 0 - bESt Fit [INPUT] and, 2 [ORANGE] ŷ,m displaying bESt Fit with the choice of 1 - LinEAr and the result of 4.6773856... followed by [ORANGE] ^x,r resulting in 2 and [SWAP] giving 0,999999... as a correlation coefficient to describe the goodness of the fit. Now here is where I am going with my initial idea : 1000 [ORANGE] ŷ,m 1999.68225... 100000 [ORANGE] ŷ,m 199900.966545... 200000 [ORANGE] ŷ,m 399801.25371... 1E9 [ORANGE] ŷ,m 1999002872.33... 9999999999 [ORANGE] ŷ,m 19990028715,2... I don't know what to think but, it's giving a result near of 2*x decreased by something that is proportional to x (based on m, in fact) !!! |
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02-18-2021, 11:23 PM
(This post was last modified: 02-19-2021 10:23 PM by Gerson W. Barbosa.)
Post: #17
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
(02-18-2021 01:41 PM)Gerson W. Barbosa Wrote: Perhaps 19 or less would suffice as the argument for the first program... Indeed 19 is enough: 19 « { } 1 DUP2 ROT 5 ROLL START NEXTPRIME + LASTARG NIP NEXT DROP SQ DUP SIZE 2 SWAP FOR i 1 OVER SIZE 1 + i - FOR j DUP j DUP i + 1 - SUB ∑LIST ROT + SWAP NEXT NEXT + SORT » EVAL « REVLIST 1 99 START TAIL NEXT SORT » EVAL → { 4 9 13 25 34 38 49 74 83 87 121 169 170 195 204 208 289 290 339 361 364 373 377 458 529 579 628 650 653 662 666 819 841 890 940 961 989 1014 1023 1027 1179 1348 1369 1370 1469 1518 1543 1552 1556 1681 1731 1802 1849 2020 2189 2209 2310 2330 2331 2359 2384 2393 2397 2692 2809 2981 3050 3150 3171 3271 3320 3345 3354 3358 3481 3530 3700 3721 4011 4058 4061 4350 4489 4519 4640 4689 4714 4723 4727 4852 4899 } P. S.: 2020 is in the list because 2020 = 17² + 19² + 23² + 29². In fact every number in the list is either a squared prime or the sum of an ordered sequence thereof. The number of consecutive prime squares starting with 4 (2²) required to safely producing a list of all years that share this property, up to a certain year, can be mathematically determined, but that’s way beyond my math skills. The following program uses a borrowed formula. 5000 « DUPDUP 4 * SWAP LN SQ / 3 XROOT 3 * CEIL { } 1 DUP2 ROT 5 ROLL START NEXTPRIME + LASTARG NIP NEXT DROP SQ DUP SIZE 2 SWAP FOR i 1 OVER SIZE 1 + i - FOR j DUP j DUP i + 1 - SUB ∑LIST ROT + SWAP NEXT NEXT + SORT REVLIST WHILE DUP HEAD PICK3 > REPEAT TAIL END REVLIST NIP » EVAL Checksum: # 180Ch Length: 213.5 bytes This will return a list with 91 elements, same as above. |
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02-19-2021, 08:15 PM
Post: #18
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
(02-14-2021 08:58 PM)Valentin Albillo Wrote: Hi, all ! Happy San Valentín 2021 to all of you ! Here is the program I used on my HP35s for the Concoction the Third and the Weird Integral: LBL W RCL P x² RCL X - LN ! ENTER ENTER // 2 times because ENTER has disabled moves in the stack... RCL X LN ! + / RTN With FN= W 1 and RCL P (where P is 1.61803398875) ∫FN d X INTEGRATING gives 3.09016994375E-1 and it seems to be 1/(2*φ) |
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02-19-2021, 11:32 PM
Post: #19
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
Hi, all: First of all, thanks a lot for your interest and your participation in this challenge, really much appreciated. As stated in my OP, I'll post my original solutions and extensive comments in a few days but as there's still a number of questions left unanswered so far, I'll give you all a Last Chance to address and complete them before I do. This includes the following: Concoction the First: Weird limit Point d is still unaddressed: d. Can you explain the constant component of said [asymptotic] expression ? Concoction the Second: Weird Sum The main question is wholly unaddressed: What's so weird about this sum ?. Perhaps a little sleuthing (i.e.: conducting some experiments) would be of help. Concoction the Fourth: Weird Graph This is mostly unaddressed. In particular no program or description of the operations required to produce the graph have been posted so far and worse, no one has produced and posted the graph itself, i.e.: an actual image of it. This is the kind of functionality for which graphics calculators are intended and I included this part specifically to give HP Prime's or RPL-models' users some opportunity to show off their calculator's worthiness for this challenge. Also, no attempts to factorize the polynomial have been reported, either successful or unsuccessful. This is the kind of functionality for which CAD is intended. Why don't you give it a try ? Hint: It would help to answer the main question. Finally, as for the main question proper, What's so weird about this graph?, it's still left unanswered. Apart from its so-described "funny" appearance, there's more to the graph than it seems at first sight. Some sleuthing would surely help. Concoction the Sixth: Weird Year Both RPL code and the resulting list of the years have been produced (without comments or explanation), but nearly all the questions have been left unanswered, i.e.:
* E.g.: For property "The year's number is a factorial" and year 720 you would output "720 = 1x2x3x4x5x6" demonstrating the property, while for year 721 you would ouput "721 = not a factorial" Finally, programs written in other than RPL would be welcome for variety and to let readers better understand what the code does and how their RPN calcs (say) would deal with the problem. As stated, Last Chance. Thanks and best regards. V. All My Articles & other Materials here: Valentin Albillo's HP Collection |
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02-20-2021, 03:45 AM
Post: #20
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RE: [VA] Short & Sweet Math Challenge #25 "San Valentin's Special: Weird Math...
For challenge two (weird sum), 1 / 4.94804552201E-4 = 2021.
Pretty neat! - Rob "I count on old friends to remain rational" |
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