(15C) Halley's Method
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02-26-2022, 11:09 AM
(This post was last modified: 06-18-2022 10:01 AM by Thomas Klemm.)
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(15C) Halley's Method
Halley's Method
References
Formula We start with Halley's Irrational Formula: \(C_f(x)=x-\frac{2f(x)}{f{'}(x)+\sqrt{[f{'}(x)]^2-2f(x)f{''}(x)}}\) However, we reduce the fraction with \(f{'}(x)\) to get: \(C_f(x)=x-\frac{\frac{2f(x)}{f{'}(x)}}{1 + \sqrt{1 - \frac{2f(x)f{''}(x)}{[f{'}(x)]^2}}}\) This allows us to reuse the following expression: \(\frac{2f(x)}{f{'}(x)}\) Also the expression avoids cancellation if \(f(x) \to 0\). This is not the case for the alternative expression: \(C_f(x)=x-\frac{1 - \sqrt{1 - \frac{2f(x)f{''}(x)}{[f{'}(x)]^2}}}{\frac{f{''}(x)}{f{'}(x)}}\) Definitions These definitions are used:
Registers Intermediate results are kept in these registers: \(\begin{matrix} R_0 & h \\ R_1 & x \\ R_2 & y \\ R_3 & f^{-}_x \\ R_4 & f^{-}_y \\ R_5 & f_x \\ R_6 & f_y \\ I & \text{program} \\ \end{matrix}\) Description These are the steps of program A: 002 - 004: store \(z\) 005 - 062: calculate the next approximation 006 - 011: \(f(z - h)\) 012 - 016: \(f(z)\) 017 - 018: \(f(z + h)\) 019 - 029: \(f{'}\) 030 - 036: \(f{''}\) 037 - 040: \(2f \div f{'}\) 041 - 043: \(f{''} \div f{'}\) 045 - 053: \(dz\) 054 - 056: \(z = z - dz\) 057 - 062: loop until it is good enough 063 - 066: return \(z\) 067 - 075: calculate \(f(z + w) | w \in \{-h, 0, h\}\) The programs B - E are examples from Valentin's article. Example The step-size h is stored in register 0, while the name/number of the program is specified in the variable I. So let's assume we want to solve program B with step-size h = 10-4 and starting guess 2: RCL MATRIX B STO I EEX 4 CHS STO 0 2 A Intermediate values of |dz| are displayed: (( running )) 0.148589460 (( running )) 0.002695411 (( running )) 0.000000017 (( running )) 0.000000000 (( running )) 1.854105968 Should that annoy you just remove the PSE-command in line 058. Programs A: Halley's Method Code: 001 { 42 21 11 } f LBL A B: Find a root of : \(x^x = \pi\) Code: 076 { 42 21 12 } f LBL B C: Find all roots of: \(( 2 + 3i ) x^3 - (1 + 2i ) x^2 - ( 3 + 4i ) x - ( 6 + 8i ) = 0\) Code: 081 { 42 21 13 } f LBL C D: Attempt to find a complex root of: \(x^3 - 6x - 2 = 0\) Code: 105 { 42 21 14 } f LBL D E: Solve Leonardo di Pisa's equation: \(x^3 + 2 x^2 + 10 x - 20 = 0\) Code: 113 { 42 21 15 } f LBL E |
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02-26-2022, 03:48 PM
(This post was last modified: 02-26-2022 04:42 PM by Albert Chan.)
Post: #2
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RE: (15C) Halley's Method
(02-26-2022 11:09 AM)Thomas Klemm Wrote: We start with Halley's Irrational Formula: This also avoid cancellation if Re(f'(x)) < 0, since Re(√z) ≥ 0 Comment: two Cf expressions are not the same. First form denominator + is really ± (2 roots of quadratic) Second form pick the smaller correction, exactly what we wanted. |
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06-11-2022, 04:12 PM
Post: #3
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RE: (15C) Halley's Method
Halley's Irrational Formula may cause sqaure root of negative number problem.
(01-07-2020 06:13 PM)Albert Chan Wrote: Example, for N=30, PV=6500, PMT=-1000, FV=50000, we have I = 8.96% or 11.10% Halley's rational formula for rate search work, without issue. lua> n,pv,pmt,fv = 30,6500,-1000,50000 lua> i1, i2 = edge_i(n,pv,pmt,fv) lua> i1, i2 -0.02 0.15384615384615385 lua> g1 = loan_rate2(n,pv,pmt,fv,i1) lua> g2 = loan_rate2(n,pv,pmt,fv,i2) lua> for i = 1,6 do print(i, g1(), (g2())) end 1 0.05032222218969118 0.11874137324380304 2 0.08034524496312957 0.11136968662548538 3 0.0889289402959179 0.11100337818114 4 0.0896051698287111 0.11100328640549177 5 0.08960585626123155 0.11100328640549177 6 0.08960585626123234 0.11100328640549177 Halley's irrational formula failed, even on first try, at i = -0.02 Halley's modified slope = (f' + sign(f')*sqrt((f')^2 - 2*f*f'') / 2 lua> f0 = 1356.1628502335457 -- i = -0.02 lua> f1 = -26468.743095455087 lua> f2 = 280416.32885371713 lua> f1*f1 - 2*f0*f2 -59986054.527367234 Perhaps it is because of negative guess rate ? No ! Even with guess i = 0.07, we still hit square root of negative number problem. lua> f0 = 53.131798377782616 -- i = 0.07 lua> f1 = -4261.51788308051 lua> f2 = 171458.18285005045 lua> f1*f1 - 2*f0*f2 -59228.53500474244 |
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06-14-2022, 01:20 AM
Post: #4
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RE: (15C) Halley's Method
About Albert Chan's problem and corresponding equation
6500*R^30+50000=(R^30-1)/(R-1)*1000, with R=1+interest_rate/100, is it possible to know for sure / to find that there exactly two "analytical" solutions, but without making a graph or trying guesses? |
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06-14-2022, 02:59 AM
Post: #5
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RE: (15C) Halley's Method
Hi, Gil
We just count sign changes, see Descartes rules of signs N+1 Cash flows: [PV, PMT, ... , PMT, PMT+FV] = [6500, -1000, ..., -1000, 49000] 2 sign changes, thus 0 or 2 positive roots (for R = 1+i) Based on rate edges, (PMT/FV , PMT/-PV) = (-1/50, 2/13) 2 Rates (if exist at all): -1/50 < i < 2/13 If we can show we have 1 root, we must have 2. |
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06-14-2022, 07:33 AM
Post: #6
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RE: (15C) Halley's Method
Of course.
Thanks for reminding me. Regards, Gil |
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06-14-2022, 06:22 PM
Post: #7
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RE: (15C) Halley's Method
(06-14-2022 01:20 AM)Gil Wrote: 6500*R^30+50000=(R^30-1)/(R-1)*1000, Above setup were solving NFV = 0, for R NFV = 6500*R^30 + 50000 - (R^30-1)/(R-1)*1000 For comparison, I was solving for f = NPMT/n = 0 f = NFV * (R-1)/(R^30-1) = (56500 / (R^30-1) + 6500) * (R-1) - 1000 Solving for f=0 for R is more stable, and, likely converge faster. From the edges, solve f=0 with Newton's method, we have 1-sided convergence. In other words, starting from 2 edges, we can get both roots (if existed). Newton's method for NFV=0 starting from edges, for this example, we get only 1 root. Interestingly, Halley's Irrational formula for NFV=0 work for small edge, R = 1+i = 0.98 0.98 1.0810815846 1.08936323285 1.08960584869 1.08960585626 For R < 1.12175, argument inside square root are positive. Thus, it will not work on the other edge, with R = 1+i = 1+2/13 ≈ 1.15385 We have only very small guess window to get the other root, R ≈ 1.11100 R(where NFV'>0) to R(where (NFV')^2 - 2*NFV*(NFV'') ≥ 0) = (1.10110, 1.12175) I would stay away using Halley's Irrational formula. To avoid issues, it required very close guess, more trouble than it is worth. |
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06-18-2022, 03:37 PM
Post: #8
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RE: (15C) Halley's Method
(06-14-2022 02:59 AM)Albert Chan Wrote: 2 sign changes, thus 0 or 2 positive roots (for R = 1+i) I was thinking of a fast way to locate extremum, check f sign, to decide number of roots. Let decay factor, g = n*x / ((1+x)^n - 1) f = (pv+fv)/n*g + pv*x + pmt f' = (pv+fv)/n*g' + pv f' = 0 → g' = -n*pv/(pv+fv) g' is too complex to be invertible back for x Instead, we approximate g with simple exponential decay function. Matching g value and slope at x=0, we have g ≈ exp((1-n)/2*x) exp is invertible with ln, we have: Extremum: xm ≈ m * ln(-m*n*pv / (pv+fv)) , where m = 2/(1-n) Reusing previous example, n=30, pv=6500, pmt=-1000, fv=50000 f = 56500*x/((1+x)^30-1) + 6500*x - 1000 xm ≈ -2/29 * ln(2/29 * 30 * 6500/56500) ≈ 0.09899 f(x = 0.09899) ≈ -6.46 // true extremum, f(x = 0.1002) ≈ -6.52 f(x = 0) = (pv+fv)/n + pmt = 883.33 We have locked in 1 roots ⇒ we have 2 roots. |
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